tag:blogger.com,1999:blog-47185770883437792462024-02-19T15:02:11.467+13:00The AtavismDavid Winterhttp://www.blogger.com/profile/09704684760112027351noreply@blogger.comBlogger35125tag:blogger.com,1999:blog-4718577088343779246.post-58037017543465083772010-06-08T14:07:00.003+12:002010-06-08T17:31:40.268+12:00If some of us have Neanderthal genes, are Neanderthals us?<img style="float: left; width: 200px; margin: 10px;" src="http://upload.wikimedia.org/wikipedia/commons/d/d9/Neanderthal_child.jpg" />I got a little bit starry eyed <a href="http://theatavism.blogspot.com/2010/05/living-up-to-our-name.html">writing about the Neanderthal genome the other day</a>. I chose to retrace the arc of scientific progress that links the initial description of Neanderthal man as something different than modern humans to the point reached last month, where we are able to tag some of those differences to a single gene. Most of the news stories about the Neanderthal genome focused not on the genes that made us different from them, but a small percentage of the genome that reinforced the continuity been them and us. Genetic evidence that Neanderthals interbred with the ancestors of some modern humans. The revelation of these ancient assignations has caused some quite sensible people to say some quite silly things about what species are and what Neanderthals were. So, perhaps I can compliment my slightly hazy earlier piece with a more hardheaded take on why Neanderthals remain a species unto themselves.
<p>
Let's start with the evidence that Neanderthals interbred with the ancestors of modern humans. Modern humans (<i>Homo sapiens</i>) arose in Africa about two hundred thousand years ago, all modern human populations outside of Africa descend from a relatively small number of migrants who left that continent between eighty and fifty thousand years ago. When those migrants first left Africa and entered the Middle East they would have met other humans. The ancestors of the Neanderthal had moved out of Africa and established themselves in Europe and Central Asia thousands of years before. Until now we haven't known which of the four 'F's (fighting, fleeing, feeding or reproduction) followed that first contact, the Neanderthal genome has given us a clue.
</p><p>
When you compare individual DNA bases that are variable within modern human genomes to the corresponding sequences in the Neanderthal genome you find that non-African sequences match the Neanderthal sequence slightly (but significantly) more often than African sequences do. It's possible that this pattern is an artifact of our <a href="http://theatavism.blogspot.com/2010/02/nucleotide-diversity-what-two-new.html">poor sampling of African genomic diversity</a> (that observant nerd Christie does a good job of explaining how <a href="http://scienceblogs.com/observations/2010/05/anceint_sex_scandals_did_we_ge.php">here</a>) but for the sake of argument let's take it for granted that his pattern is the result of ancient interbreeding. The authors of the paper describing the Neanderthal genome estimate people with no recent African ancestry inherited between one and four percent of their genome from Neanderthals. That number is the same for <a href="http://en.wikipedia.org/wiki/Papuan_peoples">Papuan </a>and East Asian populations as it is for Europeans despite Neanderthals having lived alongside Europeans for thousands of years, suggesting any interbreeding that contributed to modern human genomes was limited to that first period of contact.
</p><p>
This is where the problems start. Having heard the news that Neanderthals and some of our ancestors might have once swapped genes some people remember that nice easy test of species-status from high-school biology. Something like "if two animals can interbreed then they're part the same species." So, are we Neanderthals; or are Neanderthals us? No. In fact, the Neanderthal genome serves to highlight some the mistakes we commonly make when start trying to define species.
</p><p>
Biologists have spent a lot of time arguing about just what a species is and how can delimit species from the creatures that we study, too often we've forgotten that those are two different arguments. DeLene from Wild Muse has a <a href="http://sciencetrio.wordpress.com/2009/10/05/genes-categories-and-species-by-jody-hey/">thoughtful overview of some of the factors that contribute to the "species problem"</a> in her review of Jody Hey's book on the same topic. You should read her piece because the species problem really is a fascinating philosophical question, but I think most of the fights that erupt around competing definitions of species come from a failure to understand that defining species and organising critters into species are two different tasks. We've been studying speciation, the process by which new species arise, for a while now and we've developed a pretty good idea of how it works. Two populations stop interbreeding with each other, during that period of "reproductive isolation" genetic changes in one population can't effect the other so natural selection and random changes (called genetic drift) change each population independently. Species are populations which are on independent evolutionary trajectories. </p><p>Reproductive isolation drives the independence that is at the heart of what species are, but it's not the <i>sine qua non</i> of a species. <a href="http://www.ucl.ac.uk/taxome/jim/">James Mallet from University College London</a> has made a special study of hybridisation, and he reckons 10% of animal species and a whopping 25% of plants interbreed with other species from time to time. As molecular tools have been applied to non-model organisms it's become increasingly clear that the "species barrier" is more porous than we'd thought, and species can maintain their independence even in the face of the occasional injection of genes from other species.(If you're interested in the wider question, <a href="http://theatavism.blogspot.com/2009/06/some-answers-on-speciation.html">I've written a bit on the species problem here</a>. The short version is we should see competing "species concepts" as operational tools that might be used to help delimit species, but not as definitions).
</p><p>
Now, think about the results from Neanderthal genome. Most sequences in that genome are separated from their human counterpart by a split that happened over five hundred thousand years ago. There is pretty good evidence that Neanderthals and the ancestors of non-Africans interbred when they met each other in the Middle East about four hundred and fifty thousand years after that initial split. That gene flow had the potential to homogenise the two populations into one, but it didn't. Each lineage maintained its identity. For the twenty or so thousand years that Neanderthals continued to exist they retained identifiable morphological traits. There are fossils in Europe that some argue show a mixture of characters, but any interbreeding in that continent left no mark on modern European genomes, which have no more Neanderthal DNA than Papuan and Chinese genomes do. At the same time, the authors didn't detect any flow of modern human genes into Neanderthal genomes (so it's not a case of of modern humans swamping Neanderthal populations and erasing any trace of genetic admixture in the process). The available evidence seems to point o Neanderthals and modern humans as separately evolving populations, and a little bit of gene flow between them wasn't enough to upset that pattern. </p><p> </p><p>
</p><p>
I should stress, by saying <i>H. neanderthalensis </i>and <i>H. sapiens</i> are different species we aren't saying very much about how different Neanderthals were from us. Species are not defined by a degree of difference, or an essence that was missing in Neanderthals but is present in us, they're just another human population that was moving in a different direction (and eventually extinction). If some of us do have Neanderthal genes, then it only goes to show how fuzzy the line between our species and the rest of the biological world is.
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<p>
<span class="Z3988" title="ctx_ver=Z39.88-2004&rft_val_fmt=info%3Aofi%2Ffmt%3Akev%3Amtx%3Ajournal&rft.jtitle=Science+%28New+York%2C+N.Y.%29&rft_id=info%3Apmid%2F20448178&rfr_id=info%3Asid%2Fresearchblogging.org&rft.atitle=A+draft+sequence+of+the+Neandertal+genome.&rft.issn=0036-8075&rft.date=2010&rft.volume=328&rft.issue=5979&rft.spage=710&rft.epage=22&rft.artnum=&rft.au=Green+RE&rft.au=Krause+J&rft.au=Briggs+AW&rft.au=Maricic+T&rft.au=Stenzel+U&rft.au=Kircher+M&rft.au=Patterson+N&rft.au=Li+H&rft.au=Zhai+W&rft.au=Fritz+MH&rft.au=Hansen+NF&rft.au=Durand+EY&rft.au=Malaspinas+AS&rft.au=Jensen+JD&rft.au=Marques-Bonet+T&rft.au=Alkan+C&rft.au=Pr%C3%BCfer+K&rft.au=Meyer+M&rft.au=Burbano+HA&rft.au=Good+JM&rft.au=Schultz+R&rft.au=Aximu-Petri+A&rft.au=Butthof+A&rft.au=H%C3%B6ber+B&rft.au=H%C3%B6ffner+B&rft.au=Siegemund+M&rft.au=Weihmann+A&rft.au=Nusbaum+C&rft.au=Lander+ES&rft.au=Russ+C&rft.au=Novod+N&rft.au=Affourtit+J&rft.au=Egholm+M&rft.au=Verna+C&rft.au=Rudan+P&rft.au=Brajkovic+D&rft.au=Kucan+Z&rft.au=Gusic+I&rft.au=Doronichev+VB&rft.au=Golovanova+LV&rft.au=Lalueza-Fox+C&rft.au=de+la+Rasilla+M&rft.au=Fortea+J&rft.au=Rosas+A&rft.au=Schmitz+RW&rft.au=Johnson+PL&rft.au=Eichler+EE&rft.au=Falush+D&rft.au=Birney+E&rft.au=Mullikin+JC&rft.au=Slatkin+M&rft.au=Nielsen+R&rft.au=Kelso+J&rft.au=Lachmann+M&rft.au=Reich+D&rft.au=P%C3%A4%C3%A4bo+S&rfe_dat=bpr3.included=1;bpr3.tags=Biology%2CEvolutionary+Biology%2C+Genetics%2C+Creative+Commons%2C+Taxonomy">Green RE, and many, many others (2010). A draft sequence of the Neandertal genome. <span style="font-style: italic;">Science (New York, N.Y.), 328</span> (5979), 710-22 PMID: <a rev="review" href="http://www.ncbi.nlm.nih.gov/pubmed/20448178">20448178</a></span>
</p><p>
James Mallet's bit on the frequency of hybridisation is taken form here:
<span class="Z3988" title="ctx_ver=Z39.88-2004&rft_val_fmt=info%3Aofi%2Ffmt%3Akev%3Amtx%3Ajournal&rft.jtitle=Trends+in+Ecology+%26+Evolution&rft_id=info%3Adoi%2F10.1016%2Fj.tree.2005.02.010&rfr_id=info%3Asid%2Fresearchblogging.org&rft.atitle=Hybridization+as+an+invasion+of+the+genome&rft.issn=01695347&rft.date=2005&rft.volume=20&rft.issue=5&rft.spage=229&rft.epage=237&rft.artnum=http%3A%2F%2Flinkinghub.elsevier.com%2Fretrieve%2Fpii%2FS016953470500039X&rft.au=Mallet%2C+J.&rfe_dat=bpr3.included=0;bpr3.tags=Biology">Mallet, J. (2005). Hybridization as an invasion of the genome <span style="font-style: italic;">Trends in Ecology & Evolution, 20</span> (5), 229-237 DOI: <a rev="review" href="http://dx.doi.org/10.1016/j.tree.2005.02.010">10.1016/j.tree.2005.02.010</a></span>
</p><p>
The ideas about species and species delimitation presented above are pretty similar to Kevin de Quieroz's take:</p><p>
<span class="Z3988" title="ctx_ver=Z39.88-2004&rft_val_fmt=info%3Aofi%2Ffmt%3Akev%3Amtx%3Ajournal&rft.jtitle=Systematic+Biology&rft_id=info%3Adoi%2F10.1080%2F10635150701701083&rfr_id=info%3Asid%2Fresearchblogging.org&rft.atitle=Species+Concepts+and+Species+Delimitation&rft.issn=1063-5157&rft.date=2007&rft.volume=56&rft.issue=6&rft.spage=879&rft.epage=886&rft.artnum=http%3A%2F%2Fsysbio.oxfordjournals.org%2Fcgi%2Fdoi%2F10.1080%2F10635150701701083&rft.au=De+Queiroz%2C+K.&rfe_dat=bpr3.included=0;bpr3.tags=Biology">De Queiroz, K. (2007). Species Concepts and Species Delimitation <span style="font-style: italic;">Systematic Biology, 56</span> (6), 879-886 DOI: <a rev="review" href="http://dx.doi.org/10.1080/10635150701701083">10.1080/10635150701701083</a></span>
</p>David Winterhttp://www.blogger.com/profile/09704684760112027351noreply@blogger.com5tag:blogger.com,1999:blog-4718577088343779246.post-84225929390061289502010-06-06T08:29:00.004+12:002010-06-06T11:07:35.869+12:00Sunday Spinelesness - One for the arachnophobes?<div xmlns="http://www.w3.org/1999/xhtml"><p>It occurs to me that some readers might be put off by my affection for spiders. I'd be interested to see which creature, the wasp or the spider, you find yourself cheering for at the end of this post. Let's introuduce them. First, the large black hunting wasp <i>Priocnemis monachus</i> emerging from its burrow in one of the steps on our garden path (I messed up the focus, but nature has a way of refusing to re-pose):
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<p></p><div align="center"><a title="pomp1 by igor_nz, on Flickr" href="http://www.flickr.com/photos/igor_nz/4667898115/"><img height="375" width="500" alt="pomp1" src="http://farm5.static.flickr.com/4022/4667898115_dc5f439227.jpg" /></a></div>
<p>
And the creature the black hunting wasp has been hunting, one of the native tunnelwebs <i>Porrhothele antipodiana</i>:
</p><p>
</p><div align="center"><a title="spider1 by igor_nz, on Flickr" href="http://www.flickr.com/photos/igor_nz/4668522786/"><img height="375" width="500" alt="spider1" src="http://farm5.static.flickr.com/4023/4668522786_c9b1ed774c.jpg" /></a>
</div>
<p>
<i>Po. antipodiana </i>is pretty cool spider, it's one of very few that are capable of eating snails. Snails usually avoid the attentions of ground dwelling spiders by being too slimy to get a hold off and being able to retract into their shell. <i>Po. antipodiana </i>get's around those defenses by hooking its fangs into the snail's body and holding on while the snail struggles, produces tonnes of mucus and finally succumbs to the spider. A couple of months ago I gave a talk to a local school who wanted someone to help their study of invertebrate lifestyles and one of the kids told me that he'd seen a tunnelweb eating a snail. The budding naturalist didn't seem at all proud when I told him that he'd observed a behaviour that was only recognised by scientist 30 years ago. I guess 30 years seems an impossibly long time when your 10!</p></div>
<p></p><p>
If this particular spider looks a bit bedraggled it's because it has already been anesthetised by the wasp. <i>Pr. monachus</i> is a member of the family <a href="http://en.wikipedia.org/wiki/Spider_wasp">Pompilidae </a>which, like the <a href="http://theatavism.blogspot.com/2010/05/sunday-spinelessness-wasp-that-did-for.html">ichneumonidae that featured here last week</a>, use the living bodies of other arthropods as incubators to grow their young. While most of the ichneumonidae use caterpillars to grow their larvae the pompilids specialise in spiders (which has earned them the name spider wasps). There are ten described species of spider wasp in New Zealand, each targeting a range of spider species. <i>Pr. monachus</i> the largest of our spider wasps, and by choosing <i>Po. antipodiana </i>to provision her nest this one has taken on of New Zealand's largest spiders:</p><div xmlns="http://www.w3.org/1999/xhtml"><p></p>
<p></p><p></p><div align="center"><a title="Pomp3 by igor_nz, on Flickr" href="http://www.flickr.com/photos/igor_nz/4668522836/"><img height="375" width="500" alt="Pomp3" src="http://farm5.static.flickr.com/4036/4668522836_66b7305627.jpg" /></a></div><div align="center"><a title="Pomp3 by igor_nz, on Flickr" href="http://www.flickr.com/photos/igor_nz/4668522836/"></a>
<p></p><p>
</p><div align="left"><i>Pr. monachus</i> follows the typical pompilid nesting behavior, which means they go hunting before they set up their nest. As I watched these two the wasp would drag the spider a few centimetres then drop it and scurry back up the step and into its nest for a few seconds before returning to the spider, checking it was still incapacitated (and giving it another sting if it showed a fight) and repositioning it again. I don't know how much of that behavior was down to the wasp setting up its nest and how much was the wasp struggling with having bitten off more than it could drag up the sheer surface of the step it built its nest in.</div>
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<a href="http://www.flickr.com/photos/igor_nz/4667898319/" title="Pomp5 by igor_nz, on Flickr"><img src="http://farm5.static.flickr.com/4054/4667898319_8f592a24b3.jpg" width="500" height="375" alt="Pomp5" /></a>
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</p><div style="text-align: left;">The wasp was definitely seemed to be having a hard time hefting the spider up the step. I spent about half an hour watching her grab and the spiders legs, its spinnerets or its even its head while clinging to the sheer face of the concrete step. In the end, it started raining and I decided I should probably do something else with the rest of my weekend so I left her to her work. I came back about an hour later and both spider and wasp were gone. I don't know if the wasp gave up; or if it achieved its Herculean task and the spider's body is, even now, nourishing the next generation of these impressive wasps.</div><p></p></div></div>
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</p><div style="text-align: center;"><a href="http://www.flickr.com/photos/igor_nz/4667898261/" title="Pomp4 by igor_nz, on Flickr"><img src="http://farm5.static.flickr.com/4046/4667898261_0c3981dcba.jpg" width="375" height="500" alt="Pomp4" /></a></div><div style="text-align: center;">
</div><p></p>David Winterhttp://www.blogger.com/profile/09704684760112027351noreply@blogger.com1tag:blogger.com,1999:blog-4718577088343779246.post-59599286880015330582010-05-23T08:22:00.001+12:002010-05-23T08:22:00.332+12:00Sunday Spinelessness - Attack of the Killer Sponge!<p>
<span style="float: left; padding: 5px;"><a href="http://www.researchblogging.org/"><img alt="ResearchBlogging.org" src="http://www.researchblogging.org/public/citation_icons/rb2_large_gray.png" style="border: 0pt none;" /></a></span>
<span style="font-style: italic;">Chondrocladia turbiformis, </span>a ruthless carnivore hauled from bottom of the sea off new New Zealand by NIWA scientists, has been <a href="http://www.stuff.co.nz/environment/3712019/Kiwi-sea-sponge-makes-worlds-top-10">named among the top ten new species described last year</a>. This abyssal predator isn't a <a href="http://en.wikipedia.org/wiki/Kraken">kraken</a>, <a href="http://en.wikipedia.org/wiki/New_Nessie">a plesiosaur that time forgot</a> or even an <a href="http://io9.com/5470224/here-comes-sharktopus">improbable (but awesome) hybrid</a>. It's a sponge.
</p><p>It may come as some surprise that a sponge can be a carnivore, or even that sponges are animals. Sedentary as they are, sponges tick all the boxes for inclusion in the kingdom Anamalia. They eat other organisms to make energy and build their body (differentiating them form plants and algae), they have cells enclosed by membranes (not cell walls like plants and fungi) and they are truly multi-cellular, with specialised cell-types (which sets them apart from protists). On the other hand, sponges are pretty unusual animals. Sponges have no nervous system, no gut, not circulatory system and their cells don't form tissues. The relative simplicity of sponges helps us to understand the evolutionary history of animals, by plotting some of the characteristics of modern animals onto a phylogeny we can see what order those characters evolved in:</p><p>
</p><div style="text-align: center;"><img src="http://img.photobucket.com/albums/v387/science_boy/sponge_tree.png?t=1274409601" />
</div><p></p><div style="text-align: left;"><small style="color: rgb(153, 153, 153);">How the sponges relate to other animals. The protostomes and deuterostomes differ from each other in in fate of the blastopore, the first opening to form during embryonic development. In protostomes it becomes the mouth, in</small><small style="color: rgb(153, 153, 153);">deuterostomes it becomes the anus.</small>
</div><p>So, sponges are useful in trying to understand the evolution of animals. But we shouldn't view modern species as steps along a path toward more complex animals. Sponges are amazing creatures in their own right, for a start they're the only animals that don't have a mouth. Most sponges feed by drawing water into the their body through pores and absorbing bacteria and small algae from that water with specialized cells on the inner surface of their bodies. The cells of the inner surface have two sets of projections to help them with this task. The tail-like <a href="http://en.wikipedia.org/wiki/Flagellum">flagella</a> which beat together to get water flowing over the absorbing cells and the hair-like micro-villi which increase the cells surface area and make them more efficient absorbers (<a href="http://en.wikipedia.org/wiki/Intestinal_villus">the guts of more complex animals play the same trick on a larger scale</a>). Most sponges further increase the efficiency of this process by taking the form, and the function, of a chimney. The tubular forms are help together by a mesh of <a href="http://www.microscopy-uk.org.uk/mag/indexmag.html?http://www.microscopy-uk.org.uk/mag/artaug98/spiccy.html">small calcium carbonate structures called spicules</a>.
</p><p><span>Filter feeding works well in relatively nutrient-rich shallow waters, but scientists have pulled odd looking sponges up from the bottom of the ocean. Some of those sponges still had the characteristic sponge filter feeding system, but others had lost it all together. Quite how these strange sponges were getting by in the dark and unproductive abyss without even the normal sponge feeding system remained a mystery until 1995 when French researchers found a relative of the deep sea sponges in a relatively shallow submarine cave<span style="font-style: italic;">. Abestopluma hypoa </span>gave scientists their first chance to observe these sponges, and what they saw was amazing: it was a carnivore. In life </span><span><span style="font-style: italic;">A. hypoa</span> projects a set of filaments into the water. Those filaments are covered in tiny spicules which act like Velcro (that's the author's own simile) grabbing passing crustaceans and holding them in place. </span><span>It takes a while for the sponge to get its meal, cells make contact with prey within an hour but the actual ingestion follows a period of cell growth and movement which completely covers the animal after a day. It takes another couple of days to completely digest the crustacean. </span></p><p><span>Since that first discovery scientists have discovered many more carnivorous sponges, with a surprisingly large number coming from sea mounts off New Zealand and in the Southern Ocean. The topic of today's post (I knew I'd get to it eventually...), </span><span style="font-style: italic;">Chondrocladia turbiformis, </span><span>is one of the newest killer sponges, and it looks a bit like a mushroom:</span></p><p><span>
</span></p>
<div style="text-align: center;"><img src="http://img.photobucket.com/albums/v387/science_boy/sponge.jpg?t=1274409881" />
<div style="text-align: left;">
<p>The <span style="font-style: italic;">Chondrocladia </span><span>are a bit of a special case among the carinovore-sponges because they have retained the rudiments of their filter feeding system. They don't appear to use it to supplement their diet, rather it's been re-purposed to inflate a balloon like structure the sponge uses to help capture prey. (For a stunning example of this structure in a live sponge see the photo that <a href="http://opinionator.blogs.nytimes.com/2009/12/08/a-wild-celebration/">illustrates Olivia Judson's article here.)</a>. But the thing that really distinguishes <span style="font-style: italic;">C</span>. </span><span style="font-style: italic;">turbiformis</span> from the already amazing carnivorous sponges are its spicules:</p><p><span>
</span></p><div style="text-align: center;"><span><img src="http://img.photobucket.com/albums/v387/science_boy/sponge1.jpg?t=1274411504" /></span>
</div><p><span></span></p><span><p>Beautiful as they are, those symmetrical curved claws in D and E are run of the mill for <span style="font-style: italic;">Chondrocladia. </span>The spinning top spicules in G and H are something quite different. It was only through the description of <span><span style="font-style: italic;">C</span>. </span><span style="font-style: italic;">turbiformis </span><span>and a related species <span style="font-style: italic;">C. tasminae </span>that it became apparent these spicules, with have been named trochirhabds, are present in some modern </span><span><span style="font-style: italic;">Chondrocladia </span><span>species. It's not extactly clear what these cool little spiclues are doing in modern <span style="font-style: italic;">Chondrocladia</span> but they give us a clue to the history of carnivorous sponges. Spicules just like the </span></span><span><span>trochirhabds described from </span></span><span><span><span><span style="font-style: italic;">C</span>. </span><span style="font-style: italic;">turbiformis </span><span>have been found in marine sediments from the Jurassic period. It appears the carnivorous sponges that it took us until 1995 to learn about have been living in the oceans for at least 150 million years.
</span></span></span></p></span><p></p></div></div>The rest of the this years top ten - including bombardier worms, amphibious sea slugs and giant web building spiders - can be found <a href="http://www.species.asu.edu/Top10">here</a>.
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<span class="Z3988" title="ctx_ver=Z39.88-2004&rft_val_fmt=info%3Aofi%2Ffmt%3Akev%3Amtx%3Ajournal&rft.jtitle=Nature&rft_id=info%3Adoi%2F10.1038%2F377296a0&rfr_id=info%3Asid%2Fresearchblogging.org&rft.atitle=A+methanotrophic+carnivorous+sponge&rft.issn=0028-0836&rft.date=1995&rft.volume=377&rft.issue=6547&rft.spage=296&rft.epage=296&rft.artnum=http%3A%2F%2Fwww.nature.com%2Fdoifinder%2F10.1038%2F377296a0&rft.au=Vacelet%2C+J.&rft.au=Boury-Esnault%2C+N.&rft.au=Fiala-Medioni%2C+A.&rft.au=Fisher%2C+C.&rfe_dat=bpr3.included=1;bpr3.tags=Biology%2CCreative+Commons%2C+Zoology%2C+Taxonomy">Vacelet, J., Boury-Esnault, N., Fiala-Medioni, A., & Fisher, C. (1995). A methanotrophic carnivorous sponge <span style="font-style: italic;">Nature, 377</span> (6547), 296-296 DOI: <a rev="review" href="http://dx.doi.org/10.1038/377296a0">10.1038/377296a0</a></span>
<span class="Z3988" title="ctx_ver=Z39.88-2004&rft_val_fmt=info%3Aofi%2Ffmt%3Akev%3Amtx%3Ajournal&rft.jtitle=Zootaxa&rft_id=info%3A%2F&rfr_id=info%3Asid%2Fresearchblogging.org&rft.atitle=Two+new+species+of+Chondrocladia+%28Demospongiae%3A+Cladorhizidae%29+with+a+new+spicule+type+from+the+deep+south+Pacific%2C+and+a+discussion+of+the+genus+Meliiderma&rft.issn=&rft.date=2009&rft.volume=&rft.issue=2073&rft.spage=57&rft.epage=68&rft.artnum=http%3A%2F%2Fwww.mapress.com%2Fzootaxa%2F2009%2Ff%2Fzt02073p068.pdf&rft.au=Jean+Vacelet%2C&rft.au=Michelle+Kelly&rft.au=Monika+Schlacher-Hoenlinger&rfe_dat=bpr3.included=1;bpr3.tags=Biology%2CCommons">Jean Vacelet,, Michelle Kelly, & Monika Schlacher-Hoenlinger (2009). Two new species of Chondrocladia (Demospongiae: Cladorhizidae) with a new spicule type from the deep south Pacific, and a discussion of the genus Meliiderma <span style="font-style: italic;">Zootaxa</span> (2073), 57-68</span>David Winterhttp://www.blogger.com/profile/09704684760112027351noreply@blogger.com14tag:blogger.com,1999:blog-4718577088343779246.post-15492664512602474472010-05-16T16:22:00.006+12:002010-05-16T20:51:22.047+12:00Sunday Spinelessness - You don't know the trouble you're in<p>A scene from the garden. On the left, the New Zealand Praying Mantis <i>Orthodera novaezealandiae</i>. On the right, a hover-fly that doesn't know how much trouble it's in.
</p><p>
</p><div style="text-align: center;"><a href="http://www.flickr.com/photos/igor_nz/4610901716/" title="Trouble by igor_nz, on Flickr"><img src="http://farm2.static.flickr.com/1419/4610901716_9f46e61105.jpg" width="500" height="375" alt="Trouble" /></a></div><p></p><p>
(for those interested in the final result: the hover-fly flew off; the mantis lunged, but missed)</p>David Winterhttp://www.blogger.com/profile/09704684760112027351noreply@blogger.com2tag:blogger.com,1999:blog-4718577088343779246.post-24180300312493235192010-05-05T16:17:00.009+12:002010-05-18T09:45:20.654+12:00Memorialising my own folly<p>I'm usually a pretty cautious kind of a guy. I might be physically incapable of proofreading but I at least think these posts through and make sure I'm not committing any grave errors of science before I hit the publish button. Usually.
</p>
<p>
A couple of weeks ago <a href="http://theatavism.blogspot.com/2010/04/garth-george-wrong-wrong-275-million.html">I made fun of Garth George</a> because he underestimated New Zealand's carbon emissions by some staggering amount. It turns I overestimated the degree of Garth George's underestimate. Or to put it another way, I screwed up that maths. Garth George is still spectacularly wrong, out by a factor of 375 000, but I had said he was out by about eight times more than that. In putting the graphics together I'd written down the inverse of George's error (about 2.75 <span style="font-weight: bold;">millionths</span>, or 2.75 x 10<sup>-6</sup>) to help me calculate the sizes for each triangle and when it came time to write up the post I mistook my notes, reading 2.75 x 10<sup>6</sup> or 2.75 million.</p>
<p>That's not an excuse, it should have been obvious to me, as someone who passed 3rd from maths, that 3.7 x10<sup>8</sup> couldn't be millions of times bigger than 1 x10<sup>3</sup> and in writing the post I should have caught it. It's all very embarrassing, but if you are going to make fun of people you have to be prepared to be treated in the same way. So, in that spirit, here's the magnitude of my error plotted for all to see:
</p>
<p>
</p><div style="text-align: center;"><img src="http://img.photobucket.com/albums/v387/science_boy/magnitudeofmyerror.png" width="350" />
</div>
<p>And the worst bit, Garth George is still among the wrongest people in history but not quite on the same level as the Young Earth Creationists (and will no doubt be overtaken by Bill Gates at some stage, <a href="http://www.wired.com/politics/law/news/1997/01/1484">if he really said that thing they say he said</a>):</p>
<p>
</p><div style="text-align: center;"><img src="http://img.photobucket.com/albums/v387/science_boy/err_EMBARASSING.png?t=1273035978" />
</div>
<p>Any physical science types reading this post might want to make a joke at the expense of biologists now, can I suggest this one:</p>
<blockquote>A group of biologists and a group of mathematicians meet each other at a train station on their way to a conference on ecological modeling. The biologists each line up to buy a ticket, while a single mathematician collects a few coins from each his colleagues and buys a single ticket. Both groups board the train and before the biologists can ask what the mathematicians are up to one of them yells out that the conductor is on his way. The mathematicians leave on mass, cramming into one bathroom. The conductor arrives and clips the ticket of each biologist before knocking on the bathroom door and asking “tickets please”. The mathematicians slide their single ticket under the door, it gets clipped and the mathematicians get their train journey at a fraction of the cost the biologists paid.
<p>
The two groups run into each other again on the way home from the conference. This time the biologists are on to the game, so after exchanging a knowing wink with the mathematicians they send a representative off to get one ticket. But they are amazed to see the mathematicians don’t even bother with the single ticket that bought for the first journey. The biologists want to know what’s going on by the mathematicians stay tight lipped until their spy announces “conductor on his way”. The biologist scramble just as they’d seen the mathematicians do on the last trip, squeezing into a bathroom. In contrast, all but one of the mathematicians strolls down to the other bathroom in the train while the other approaches the biologists’ room, knocks on the door and asks “tickets please”.
</p>
(The moral of the story, biologists should think carefully before applying mathematical methods)
</blockquote>David Winterhttp://www.blogger.com/profile/09704684760112027351noreply@blogger.com0tag:blogger.com,1999:blog-4718577088343779246.post-50672311390328429782010-04-04T09:10:00.000+12:002010-04-04T09:10:00.168+12:00Sunday Spinelessness - A Nobel Prize Winning Insect<p>
I think invertebrates are important. The 95% of animal species that don’t have a backbone are not simply the base of the animal kingdom’s pyramid, <a href="http://www.pbs.org/wgbh/nova/transcripts/2203crea.html">they are the little creatures that run the world.</a> A third of the planet’s food production <a href="http://www.mediathatmattersfest.org/films/every_third_bite/">relies on honey bees</a>, <a href="http://sciblogs.co.nz/the-atavism/2009/12/06/sunday-spinelessness-collembola-2-0/">collembola</a> and <a href="http://sciblogs.co.nz/the-atavism/2010/03/14/sunday-spinelessness-extreme-close-up/">corpse-feeding insects</a> turn dead tissue into living tissue and <a href="http://sciblogs.co.nz/the-atavism/2010/02/20/sunday-spinelessness-animals-that-dont-move/">coral reefs</a> can turn the nutrient-poor tropical seas into submarine rainforests. There are even a couple of invertebrate animals that have won the Nobel Prize.</p><p>
</p><div style="text-align: center;"><a href="http://www.flickr.com/photos/igor_nz/4482425915/" title="TheFliesHaveEyes by igor_nz, on Flickr"><img src="http://farm5.static.flickr.com/4029/4482425915_7369ba99c9.jpg" width="500" height="296" alt="TheFliesHaveEyes" /></a></div><p></p><p><i>Drosophila melanogaster</i> has probably taught us more about genetics than any other animal on earth. In the wild <i>D. melanogaster</i> larvae develop on rotting fruit so, just like <a href="http://sciblogs.co.nz/the-atavism/2010/03/14/sunday-spinelessness-extreme-close-up/">the flesh-flies that were featured here a couple of weeks ago</a>, they are faced with the problem of having to complete their entire developmental program in the short period of time the fruit they are born in is a viable food source. Thanks to these environmental constraints, <i>D. melanogaster</i> has a very short life cycle. Under optimal conditions they can go from egg to adult in a week. This remarkable developmental haste means drosophilists can run genetic experiments that cover many generations in a few months, and they can run many replicates of these experiments because each of them takes up about this much space:</p><p>
</p><div style="text-align: center;"><a href="http://www.flickr.com/photos/igor_nz/4482426027/" title="tubes by igor_nz, on Flickr"><img src="http://farm5.static.flickr.com/4042/4482426027_cd8d5c2c02.jpg" width="375" height="500" alt="tubes" /></a></div><p></p><p><i>Drosophila </i>has been kept in laboratories since the the turn of the 20th Century but T.H. Morgan was the first person to put <i>Drosophila </i>at the forefront of genetic research. Morgan was an embryologist by training and, like a lot of embryologists then and now, he became interested in a school of evolutionary thought called <a href="http://en.wikipedia.org/wiki/Mutationism">mutationism</a>. As the name suggests, the mutationists argued that one-off mutations were the creative engine of evolution, relegating natural selection to weeding out maladaptive mutants. In order to test the creative power of mutation Morgan grew up generation after generation of Drosophila and bombarded them with anything he thought might mutate them; radium, salts, sugars, acids, bases and even centrifugal force. Two years of this mutational bombardment got Morgan nowhere, he could induce changes in his flies but none that would be stably passed on. In 1910 he found a single white eyed male.</p><p>There is a story, which I can't find repeated by reliable sources, that holds that Morgan took the first white eyed male home with him in jar and slept with the jar next to his bed that night. I don't know if that story is true but that one fly does have a treasured place in the history of genetics. By crossing it to normal eyed (what geneticists call "wild type") females he was able to show that the genetic factor that made the fly's eyes white was part of the sex determining chromosome. For the first time a gene had been shown to be reside on a chromosome. A few years later he showed that multiple genes are arranged in linear fashion along chromosomes by demonstrating <a href="http://en.wikipedia.org/wiki/Chromosomal_crossover">crossing over</a> between the <i>white eye</i> gene and another called <i>rudimentary. </i>At Otago second year geneticists repeat Morgan's experiments, so this picture, sorting flies under a binocular microscope, will be familiar to anyone whose been through the program. (it will probably also bring back memories of escaped flies and a whiff of the (dilute) ether used to knock the files out...)</p><p style="text-align: center;"><a href="http://www.flickr.com/photos/igor_nz/4482425985/" title="underthescope by igor_nz, on Flickr"><img src="http://farm3.static.flickr.com/2691/4482425985_b10dff272e.jpg" width="500" height="419" alt="underthescope" /></a>
</p><p>Morgan was awarded the Nobel Prize in 1933, in 1948 <i>Drosophila </i>research got another Nobel, this time to Hermam Muller for showing X-ray radiation could induce mutations. Geneticists have continued to use <i>Drosophila </i>as a model organism, perhaps most usefully in untangling the genetic interactions that underly the development process. In 1980 <a href="http://en.wikipedia.org/wiki/Christiane_N%C3%BCsslein-Volhard">Christiane Nüsslein-Volhard</a> and <a href="http://en.wikipedia.org/wiki/Eric_F._Wieschaus">Eric Wieschaus</a> presented the results of a mutational screen; that is, they mutated <i>Drosophila </i>stocks at random and recorded the developmental phenotypes that resulted. Nüsslein-Volhard and Wieschaus identified 15 genes involved with the very early stages of development. In quick time Drosophilists mapped that those genes to chromosomes and worked out how their products combined to pattern a developing embryo. Nüsslein-Volhard and Wieschaus' work laid the ground work for one of the most staggering findings of modern biology, almost all the genes that help shape the Drosophila embryo <a href="http://nobelprize.org/nobel_prizes/medicine/laureates/1995/illpres/more-l-simgenes.html">have counterparts in the human genome</a> that play similar roles in our development. An insect can be a useful model for human development and disease genetics. Nüsslein-Volhard and Wieschaus were awarded the Nobel Prize in 1995, the third Nobel for work on <i>Drosophila</i>. </p><p>A big thanks to <a href="http://thegeneticallyinsane.blogspot.com/">Sarah Morgan,</a> one of <a href="http://biochem.otago.ac.nz/deardenlab/">Otago's fly pushers</a><a href="http://biochem.otago.ac.nz/deardenlab/">,</a> for the photos that illustrate this post. Sarah's off to the US of A this week to show off her research at <a href="http://www.drosophila-conf.org/2010/">The Big <i>Drosophila</i> Meeting</a> in Washington DC so she will probably have some less historical <i>Drosophila </i>science to talk about in the next little while...</p><hr width="50%"><span class="Apple-style-span" style="font-family:arial;color:#595959;"><span class="Apple-style-span" style="line-height: 15px;">
</span></span>
<p>
Nüsslein-Volhard C, & Wieschaus E. (1980) <a href="http://www.ncbi.nlm.nih.gov/pubmed/6776413">Mutations affecting segment number and polarity in Drosophila</a>. <i>Nature</i>, 287(5785), 795-801. PMID: <a href="http://www.ncbi.nlm.nih.gov/pubmed/6776413">6776413</a>
</p><p>
Rubin GM, & Lewis EB. (2000) <a href="http://www.ncbi.nlm.nih.gov/pubmed/10731135">A brief history of Drosophila's contributions to genome research</a>. <i>Science</i>, 287(5461), 2216-8. PMID: <a href="http://www.ncbi.nlm.nih.gov/pubmed/10731135">10731135</a>
</p>David Winterhttp://www.blogger.com/profile/09704684760112027351noreply@blogger.com4tag:blogger.com,1999:blog-4718577088343779246.post-61170765205159370582010-03-28T11:40:00.003+13:002010-03-28T12:06:47.922+13:00Sunday Spinlessness - The Other Damsel<p>This week's Sunday Spinelessness is dedicated to those people who wash up at <a href="http://theatavism.blogspot.com/2009/11/sunday-spinelessness-damselflies.html">this post</a> after googling for "<i>Austrolestes colensonis</i>" only to be disappointed. At the time I wrote that post on our damselflies I didn't have a photo of the the New Zealand Blue Damselfly, let me correct that now. A full body shot:
</p>
<p style="text-align: center;"><a href="http://www.flickr.com/photos/igor_nz/4468368876/" title="damsel2 by igor_nz, on Flickr"><img src="http://farm5.static.flickr.com/4069/4468368876_3dd21e4b40.jpg" width="500" height="375" alt="damsel2" /></a></p><p style="text-align: left;">And a close up:</p>
<p style="text-align: center;"><a href="http://www.flickr.com/photos/igor_nz/4468371356/" title="damsel3 by igor_nz, on Flickr"><img src="http://farm3.static.flickr.com/2745/4468371356_9e5a069815.jpg" width="500" height="375" alt="damsel3" /></a></p><p style="text-align: left;">
</p>
<p> These photos were taken at <a href="http://www.forestandbird.org.nz/what-we-do/reserves/fensham-reserve">Fensham Reserve</a> in the Wairarapa. We walked through the bush there on a bright summer's afternoon and every time we passed a break in the canopy we found a little flight of <span class="Apple-style-span" style="font-style: italic; ">Austrolestes </span>basking in the sun. The reflective wings were beautiful, but, as you're about to see, not easily photographed:</p><p>
</p>
<p style="text-align: center;"><a href="http://www.flickr.com/photos/igor_nz/4467592101/" title="damsel1 by igor_nz, on Flickr"><img src="http://farm3.static.flickr.com/2720/4467592101_2b32b948e8.jpg" width="500" height="375" alt="damsel1" /></a></p>David Winterhttp://www.blogger.com/profile/09704684760112027351noreply@blogger.com2tag:blogger.com,1999:blog-4718577088343779246.post-60632173506764176162010-03-26T17:20:00.007+13:002010-07-28T20:16:02.191+12:00Does a forty thousand year old finger point to another human species?<span style="float: left; padding: 5px;"><a href="http://www.researchblogging.org/"><img alt="ResearchBlogging.org" src="http://www.researchblogging.org/public/citation_icons/rb2_large_gray.png" style="border:0;" /></a></span><div style="text-align: left;">DNA extracted from a 40 000 year old finger bone found in a cave in Siberia might be evidence for a previously unrecognized human species. Or it might not be. The bone, which comes from what New Zealanders call a "little finger", Americans call a"pinky" and paleo-anthropologists call the "distal manual phalanx of the fifth digit", was found in the <a href="http://archaeology.about.com/od/dathroughdeterms/qt/denisova_cave.htm">Denisova cave</a>, in a region of Siberia from which remains of members of both our own species (<i>Homo sapiens</i>) and <a href="http://humanorigins.si.edu/evidence/human-fossils/species/homo-neanderthalensis">Neanderthals</a> (<i>H. neanderthalensis</i>) have previously been found. The mitochondrial DNA (mtDNA) sequences generated from the finger bone are distinct from both modern human sequences and from previously published neanderthal sequences, but inferring species boundaries is a tricky business and the mtDNA sequences are not, in and of themselves, proof that the finger belonged to a member of a third human species.</div><p></p><p>
Here's the big figure from the paper, which was presented by <a href="http://www.eva.mpg.de/genetics/files/team_paabo.html">Johannes Krause and colleagues</a> in <i>Nature</i> yesterday. It's a phylogenetic tree which relates the little finger's mtDNA to <i>H. sapiens</i> and <i>H</i>.<i> neanderthalensis </i>sequences (click to see a high-resolution version):
</p><p>
</p><div style="text-align: center;"><a href="http://img.photobucket.com/albums/v387/science_boy/nature08976-f32.jpg"><img src="http://img.photobucket.com/albums/v387/science_boy/mt_tree.jpg" /></a></div><p></p><p>The Denisnova sequence is red, Neanderthal sequences are in blue and modern humans are grey. So, the Denisova mtDNA forms a distinct lineage that isn't represented in modern humans or in previously published Neanderthal sequences. By using the tree as the basis for molecular dating the researchers were able to estimate that Denisova lineage separated from other human mitochondrial lineages between 0.78 and 1.3 million years ago. The temporal context the molecular dating adds to the phylogenetic tree helps to us understand where this new mitochondrial lineage might fit into humanity's family tree.</p><p><a href="http://theatavism.blogspot.com/2010/02/nucleotide-diversity-what-two-new.html">I've said before that most of our species' history was played out in Africa</a>, and, in fact, the same is true when we step up a taxonomic level and look at our genus. All the human species that have been found outside of Africa descend from migrants that moved out of that continent at some stage. Here's a schematic representing some of the species in the wider human family tree and the timing of the migrations that moved them out of Africa.</p><p>
</p><div style="text-align: center;"><img src="http://img.photobucket.com/albums/v387/science_boy/OOA.png" /></div><p></p>
<p>How does the new evidence presented by Krausse <i>et al.</i> fit into that scheme? Perhaps the simplest interpretation is the the Denisova lineage represents a new species. The estimated age of the Denisova lineage makes it too young to have been carried out of Africa by the first wave of <i><a href="http://humanorigins.si.edu/evidence/human-fossils/species/homo-erectus">H. erectus</a></i> migrants to leave Africa and apparently too old to have been inherited from the migrants that went on to form the Neanderthal lineage. If the Denisova sequence is something new then we'll have to update our family tree, adding a new branch and a fourth migration out of Africa. </p>
<p></p>
<div style="text-align: center;"><img src="http://img.photobucket.com/albums/v387/science_boy/OOAaA.png" /></div><p>
<a href="http://johnhawks.net/weblog/reviews/neandertals/neandertal_dna/denisova-krause-2010.html">John Hawks thinks we should hold off on updating the family tree too qucikly</a>. The Desinova specimen might be a Neanderthal. At first glance the tree presented by Krausse <i>et al. </i>seems to dispel that possibility since previously identified Neanderthal sequences are more closely related to modern human sequences than the new linaeage, but that tree is based entirely on mtDNA. The mitochondrial genome is <a href="http://sciblogs.co.nz/the-atavism/2009/07/31/my-mutant-mitochondria-and-life-on-earth/">inherited as if it was a single gene</a>. We can often use trees estimated from a single gene ("gene trees") as a proxy for species-level relationships ("species trees") but, in fact, every gene in a population has its own history and there there are scenarios that can push a given gene tree away from underlying species tree. Perhaps the easiest way to visualise how you'd end up with mitochondrial lineages that diverged millions of years ago within a single species is to think about genetic lineages moving through a population while speciation happens. <a href="http://theatavism.blogspot.com/2009/06/some-answers-on-speciation.html">New species form when populations stop sharing genes with each other</a>, in the diagram below the big black triangle represents a barrier to gene flow. What happens if multiple different gene lineages are present in the ancestral population at the time that this gene flow stops? Usually, given enough time, each species will "sort" into specific gene lineages that descend from just one of the lineages in the ancestral population, but it's also possible for one (or both) species to maintain multiple lineages for some time. Such "incomplete lineage sorting" makes gene trees bad proxies for species trees and it's just possible that something like this has happened in Neanderthals:</p>
<p style="text-align: center;"><img src="http://img.photobucket.com/albums/v387/science_boy/tubetree_corrected.png?t=1280304853" /></p><p>Perhaps by moving to the very Easterm edge of the Neanderthals range we've sampled for the first time a lineage that existed in that species for the whole time it was in Europe. Maybe, and Hawks surely knows a lot more about paleobiology than I do, but I don't really buy it. It's certainly possible for a species to harbour deeply divergent mitochondrial lineages, but the time it takes for gene-lineages to sort within a species is relative to the effect population size of that species. Neanderthals probably had a relatively small effective population size (and mtDNA definitely does, since only females pass it on and then in only one copy) making the retention of multiple lineages over hundreds of thousands of years seem like a long shot. As Hawkes argues, strong geographic structure in Neanderthal populations might have aided the retention of divergent genetic lineages against those odds, maybe the Denisova mitochondrial lineage was extinct in Western Europe but common in Central Asia? It's possible, but I wouldn't bet on it.</p><p>Finally, the Denisova sample might be our first look at <i>H. erectus</i> DNA. <i>H. erectus</i> remains have been recovered from China so it seems possible they were in Siberia too. As I've said, the molecular dating of the Denisova lineage probably makes it too young to be a descendant of the first wave of migration form Afirca (though, of course, there is some uncertainty associated with that dating), but it might be evidence of genetic exchange between African and the <i>H. erectus </i>diaspora.<i> </i>As we've come to understand the origin of our species we've realised that the simple "Out of Africa" model is just that, a model, and <a href="http://blogs.discovermagazine.com/loom/2005/12/06/tree-or-trellis/">the true pattern is more complex</a>. <i>H. sapiens</i> really did have its start in Africa and it really did push out into the rest of the world in the last 50 000 years or so, but during that expansion populations have continued to exchange genes. There's no reason to believe that that <i>H. erectus</i> could not have done the same, perhaps the main thrust of the <i>H. erectus</i> expansion was 1.6-2 million years ago but genes continued to flow in and out of Africa for sometime after that. </p><p>So, there are three possibilities for the Denisova sample:
</p><ol>
<li> It could be a new species,
</li><li>It could be an ancient mitochondrial lineage retained in eastern Neanderthal populations but lost elsewhere
</li><li> It could be the first <i>H. erectus </i>sequence.
</li></ol>
We'll need more genes (Krausse <i>et al</i>. report they are working on sequencing genes from the nuclear genome) or more complete specimens to know for sure but I'll throw caution to the wind and say I think the first scenario to be the most likely and the second the least probable (remembering of course, that I'm not an anthropologist and these are pretty subjective estimates!). Perhaps I'm displaying some biases because I also think numbers one and three would be the cooler results. If either of those scenarios are true then we can add a third human species (alongside the Neanderthals and the 'Hobbit' <i>H. floresiensis) </i>that modern humans might have interacted with - it's just so fascinating to imagine our ancestors living alongside other human species and how differently the world might have turned out if those other species had survived the few thousand years that separate us.<p></p> <div>You should read <a href="http://blogs.discovermagazine.com/loom/2010/03/24/the-x-womans-fingerbone/">Carl Zimmer's post on the paper</a>, he's compiling expert opinions as they come to him. There's also some more qualified comments via <i>The Independent</i> who made up for their poor news article on the story by having <a href="http://www.independent.co.uk/opinion/commentators/chris-stringer-the-tip-of-the-iceberg-in-understanding-of-human-history-1926981.html">Chris Stringer from the Natural History Museum write a piece on it</a>.</div>
<hr width="50%">
<span class="Z3988" title="ctx_ver=Z39.88-2004&rft_val_fmt=info%3Aofi%2Ffmt%3Akev%3Amtx%3Ajournal&rft.jtitle=Nature&rft_id=info%3Adoi%2F10.1038%2Fnature08976&rfr_id=info%3Asid%2Fresearchblogging.org&rft.atitle=The+complete+mitochondrial+DNA+genome+of+an+unknown+hominin+from+southern+Siberia&rft.issn=0028-0836&rft.date=2010&rft.volume=&rft.issue=&rft.spage=&rft.epage=&rft.artnum=http%3A%2F%2Fwww.nature.com%2Fdoifinder%2F10.1038%2Fnature08976&rft.au=Krause%2C+J.&rft.au=Fu%2C+Q.&rft.au=Good%2C+J.&rft.au=Viola%2C+B.&rft.au=Shunkov%2C+M.&rft.au=Derevianko%2C+A.&rft.au=P%C3%A4%C3%A4bo%2C+S.&rfe_dat=bpr3.included=1;bpr3.tags=Anthropology%2CBiology%2CEvolutionary+Biology%2C+Genetics%2C+Creative+Commons%2C+Taxonomy%2C+Biological+Anthropology">Krause, J., Fu, Q., Good, J., Viola, B., Shunkov, M., Derevianko, A., & Pääbo, S. (2010). The complete mitochondrial DNA genome of an unknown hominin from southern Siberia <span style="font-style: italic;">Nature</span> DOI: <a rev="review" href="http://dx.doi.org/10.1038/nature08976">10.1038/nature08976</a></span>David Winterhttp://www.blogger.com/profile/09704684760112027351noreply@blogger.com22tag:blogger.com,1999:blog-4718577088343779246.post-58740873076717531122010-03-21T10:56:00.001+13:002010-03-26T10:39:23.921+13:00Sunday Spinlessness - Waste Not<p>Just a quick one today. A few weeks a go <a href="http://sciblogs.co.nz/the-atavism/2010/02/28/sunday-spinelessness-arachnophobia/">I used a picture of a male </a><i><a href="http://sciblogs.co.nz/the-atavism/2010/02/28/sunday-spinelessness-arachnophobia/">Cambridgea </a></i><a href="http://sciblogs.co.nz/the-atavism/2010/02/28/sunday-spinelessness-arachnophobia/">spider to spring off into a half-baked conversation on arachnophobia</a>. That male had probably wandered into the warmth of our house after paying a visit to a female who has a web attached to the downpipe by our kitchen window:</p>
<p>
</p><div style="text-align: center;"><a href="http://www.flickr.com/photos/igor_nz/4444183499/" title="camegg1 by igor_nz, on Flickr"><img src="http://farm5.static.flickr.com/4061/4444183499_e7b7c8c40e.jpg" width="500" height="375" alt="cambridgea web" /></a></div><p></p>
<p>During the day the web's owner hides in a retreat (in this case right behind the joint in the downpipe) but at night you can see a very impressive spider sitting under her web, waiting for some tasty morsel to get trapped. <i>Cambridgea</i> are really forests spiders, if you hunt around a decent piece of native forest and you are bound to find a similarly constructed, but much larger, web. In the forest expectant <i>Cambridgea </i>mothers obscure their egg cases with twigs and dried leaves. Apparently our kitchen wall did offer much camouflage when our <i>Cambridgea </i>mother </p>
<p>
</p><div style="text-align: center;"><a href="http://www.flickr.com/photos/igor_nz/4444955022/" title="cammegg2 by igor_nz, on Flickr"><img src="http://farm5.static.flickr.com/4065/4444955022_e2b1b76de7.jpg" width="500" height="375" alt="cammegg2" /></a></div><p></p>
<p>You really should click on that image and see the high-res version, it's pretty cool. In order to grow, spiders have to cast off their rigid exoskeleton. You can see here our <i>Cambridgea </i>mother has used her discarded exoskeleton to help obscure her egg case! </p><p>The exoskeleton also gives you a clue as to how the spider has achieved its moult - the cephalothorax (the part of an arachnid body that includes the head and the thorax) is popped off and the spider pulls itself, legs and all, out through that gap. The last step of the process is <a href="http://rxwildlife.org.uk/2009/08/24/rye-harbour-moths-83/">photographed here</a>.</p>David Winterhttp://www.blogger.com/profile/09704684760112027351noreply@blogger.com0tag:blogger.com,1999:blog-4718577088343779246.post-39623732978791140032010-03-18T12:45:00.006+13:002010-03-18T14:20:18.952+13:00Illustrating Carl Zimmer's Readers<p><a href="http://blogs.discovermagazine.com/loom/2010/03/15/the-science-reader-help-me-draw-a-profile/">Carl Zimmer has been wondering what to do next</a>. Obviously, he's going to keep writing his wonderful science stories and continue to maintain the <a href="http://blogs.discovermagazine.com/loom/category/science-tattoo-emporium/">Science Tattoo Emporium</a> but where to do that , and how to make money from it, is less clear. Carl's a scientific kind of guy, so he wanted get some data to inform his decision. <a href="http://blogs.discovermagazine.com/loom/2010/03/17/the-science-reader-a-crowd-sourced-profile/">The results of his reader's survey are out</a> and they're interesting. But, for all Carl's skill with words data wants to be pretty, so here are a couple of the the key conclusions of his reader's survey illustrated with the help of <a href="http://had.co.nz/ggplot2/">ggplot</a>.</p>
<p>
Where do readers of The Loom get their science news?</p><p>
</p><p>
</p><p>
</p><p>
</p><div style="text-align: center;"><img src="http://img.photobucket.com/albums/v387/science_boy/source.png" /></div><p></p>
<p>
How much would they pay for an e-book from a scince writer they liked?</p><p>
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</p><p>
</p><div style="text-align: center;"><img src="http://img.photobucket.com/albums/v387/science_boy/cost.png" /></div><p></p>David Winterhttp://www.blogger.com/profile/09704684760112027351noreply@blogger.com0tag:blogger.com,1999:blog-4718577088343779246.post-32528410651227958532010-03-17T17:17:00.005+13:002010-03-17T18:33:00.359+13:00Lawrence Krauss on a bad day<p>
Dunedin got to see Lawrence Krauss on a good day and a bad day this week, but that’s not to say one of his presentations was better than the other. Yesterday the award winning physicist and scientific communicator revealed to his audience that his outlook on life changes from day to day. On good days he can revel in the wonder of a universe that could come to know itself due to a series of accidents that started 10<sup>-31</sup> seconds after the big bang and allowed the creation of first matter then atoms, stars and planets and finally astronomers. On bad days he despairs at the lack of scientific thinking in journalism and politics and thinks these problems, and the anti-scientific forces that fuel them, will probably prevent us from doing anything meaningful about climate change.
</p><p>
Krauss' awe inspiring story of an atom's journey from the birth of the universe to its death will gain nothing from my retelling it. If you weren't able to see it then you'l be glad to know his talk was a précis of his excellent book <i><a href="http://www.physicscentral.org/explore/writers/krauss01.cfm">ATOM: An Odyssey from the Big Bang to Life on Earth...and Beyond</a></i>and covers similar ground to <a href="http://www.youtube.com/watch?v=7ImvlS8PLIo">this recored lecture</a>. Perhaps I'm a masochist and a pessimist, but I'm going to skip the awe inspiring story to focus on what Lawrence Krauss thinks about on a bad day. His talk on "Science, Non-Science and Nonsense" described the sources of scientific confusion in society and the tactics used by those groups that seek to take advantage of it.</p><p>Krauss argued that the goal of science education and science communication should be to make sure everyone develops a functioning bullshit filter. He didn't express his thesis quite as bluntly as that, but his core idea is that spreading a scientific mindset would allow us to short circuit needless debates (is global warming real?) and let us get on to the important ones (what are we going to do about it?). He used a neat example to illustrate how this sort of scientific common sense could stop nutty ideas before they get started. UFO enthusiasts <a href="http://www.alien-ufos.com/ufo-alien-discussions/22778-ufo-flight-characteristics-right-angle-turns.html">often cite the ability of the lights they observe to perform right angle turns at speed as evidence of their otherworldliness</a>. In fact, Krauss pointed out, common sense should tell us that these apparently amazing maneuvers are evidence that the lights in question are not being emitted by a massive object moving through the sky. The only way to turn at a right angle is to stop then change direction, for a UFO to do all its slowing down and stopping so quickly a human observer couldn't perceive it would generate G-forces with a strength about 2000 times greater than earth's gravity. And quite a mess.</p><p>If the evidence used by UFO junkies is so silly then why do continue prosper? Why aren't people already filtering this sort of nonsense? The standard of scientific reporting in the media certainly has a lot to answer for. Krauss cited the normal concerns, a fractionated media market means viewers can choose a source of news that <a href="http://en.wikipedia.org/wiki/Confirmation_bias">confirms their biases</a> and the innate need of journalists to<a href="http://www.fair.org/index.php?page=1978"> present balance</a> is misplaced in science stories when, in almost every case, one side is wrong and we usually know which side that is. He also mentioned something I hadn't thought about before. According to Krauss, part of the problem with science coverage in mainstream reporting is that journalists don't feel qualified to make scientific pronouncements. Writers and broadcasters are happy to make bold statements on politics, financial markets and sports but will shy away from even a scientifically uncontroversial statement like "evolution is a fact."</p><p>Scientific understanding might not be helped by meek journalists and the false equality of balance but most journalists aren't setting out to deliberately mislead the public on science. Unfortunately, there are forces at work that are doing just that. Krauss had a tonne of examples from the culture wars in his native USA to draw on but he also took the time reminded us of our home grown cranks, citing the New Zealand Climate "Science" Coalition and Ray Comfort (<a href="http://www.youtube.com/watch?v=Y4yBvvGi_2A">The Apologists Nightmare</a> [youtube video]) as evidence we aren't immune to anti-science in New Zealand. As you'd expect Krauss exposed just how vacuous the claims of intelligent design creationism and the objections of climate change denialists are, but he also attempted to deconstruct the PR strategies each group use. Both campaigns seek to take advantage of the public's sense of fairness and journalists' willingness to provide balance to any point of view. The Discovery Institute would have you believe their goal is simply to get their science a fair hearing in the classroom. But they don't have a science. For normal science, theories only make it into the school curriculum after they've been proposed, tested, retested and confirmed. The ID crowd don't want fair treatment, they want special treatment, to avoid that boring scientific process and start in the classroom!</p><p>Krauss could hardly have known this, but our own climate cranks play the same game. I hate to make an example of <a href="http://www.stuff.co.nz/dominion-post/national/3313739/Kiwi-aids-climate-change-research-overhaul">this article</a> because the author usually covers science well, nevertheless it highlights the point. In an effort to provide balance to a story on how the IPCC might be made better the author contacted <a href="http://climaterealists.com/index.php?tid=91">Vincent Gray</a> for comment, here's the paragraph</p>
<blockquote>
Wellington scientist and climate change sceptic Vincent Gray said the researchers were continually coming up with "new models" but they were still "fiddling the figures" and were unlikely to restore public confidence in their work until their projections were proven
</blockquote>
<p>That sounds pretty fair doesn't it? Climate scientists can run their model forward in time and if their projections match observations we'll take action. Actually, it's absurd. As Krauss emphasised in his talk, the evidence for climate change doesn't only come from models, we have tonnes of data that tell us the earth is warming and the seas are rising. Combine those data with the fact <a href="http://tamino.wordpress.com/2008/03/26/recent-climate-observations-compared-to-ipcc-projections/">recent temperature records are within the uncertainties of the IPCC's projections</a> and<a href="http://www.skepticalscience.com/climate-models.htm"> sea levels are near to the upper bound</a> of those projections and Gray's sound bite seem less fair. </p><p>Krauss had more problems than solutions in his hour long presentation. In fact, it's a testament to the passion he has for his science and skill he has as a scientific communicator that he managed make a talk made almost entirely of depressing facts seem invigorating. The only ray of hope Krauss offered us was that when people's backs are to the wall they abandon their their preconceptions and to turn to science. In 2003 George W. Bush said that he believed "both sides" of the "evolution debate" should be taught in schools. In 2005 Bush was faced with the prospect of Avian flu becoming able infect humans. Confronted with threat of a flu pandemic the Bush administration dispensed with its evolutionary agnosticism and planned for the possibility of genetic mutations allowing viruses to pass from human to human. That sort of infectivity requires conformational changes in surface proteins which create a new function, <a href="http://en.wikipedia.org/wiki/The_Edge_of_Evolution">exactly the sort of phenomenon the ID crowd think is so improbable as to be effectively impossible</a>.</p><p>Krauss will be presenting something very similar to his Dunedin talk <a href="http://www.auckland.ac.nz/uoa/home/events/template/event_item.jsp?cid=246813">in Auckland next week</a>. I'd encourage anyone who has the chance to get out and seem him, he's a very chrasmatic and interesting speaker. You might even ask the question I really wish I did now- how are we going to fix all these problems?</p>David Winterhttp://www.blogger.com/profile/09704684760112027351noreply@blogger.com0tag:blogger.com,1999:blog-4718577088343779246.post-91864670409908535572010-03-14T07:52:00.004+13:002010-03-16T11:56:54.362+13:00Sunday Spinelessness - Extreme Close-up<p>Almost all the photos I've used to illustrate these Sunday Spinelessness posts have been taken with my <a href="http://www.steves-digicams.com/camera-reviews/konica/minolta-dimage-z20/konica-minolta-dimage-z20-review.html">fixed lens digital camera</a>. I think it does a pretty nice job in macro mode but sometimes you just want to get a little closer to your subject. I photographed each of the landsnails I collected for my PhD research so that I could have a record of their pigmentation, which degrades once you preserve a specimen in ethanol. Obviously, the more detail I could get the better so I borrowed some very exciting toys from the department's photography office: </p><p>
</p><p></p><div style="text-align: center;">
</div><div style="text-align: center;"><a href="http://www.flickr.com/photos/igor_nz/4426746978/" title="macro by igor_nz, on Flickr"><span class="Apple-style-span" style="color: rgb(0, 0, 0); -webkit-text-decorations-in-effect: none; "></span></a><a href="http://www.flickr.com/photos/igor_nz/4426746978/" title="macro by igor_nz, on Flickr"><img src="http://farm3.static.flickr.com/2790/4426746978_c6d9b0b99f.jpg" width="500" height="333" alt="macro" /></a></div><p></p><p>
The camera is a DSLR with a 100mm f2.8 macro lens, an extension tube and a twin flash. The mammal crashing this invertebrate-celebrating series is me. </p><p>Of course, I couldn't have a toy like this to play with and limit myself entirely to photographing snails. In amongst those important snail photos I have jumping spiders, hornets, geckos and really anything else that chanced across the porch I was taking photos on. One of the more striking subjects is this red-eyed fly:
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</p><div style="text-align: center;"><a href="http://www.flickr.com/photos/igor_nz/4426747324/" title="ff2 by igor_nz, on Flickr"><img src="http://farm5.static.flickr.com/4069/4426747324_4cf597b6ac.jpg" width="500" height="375" alt="ff2" /></a></div><p>
</p><p>And the head-on shot...
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</p><div style="text-align: center;"><a href="http://www.flickr.com/photos/igor_nz/4426747172/" title="ff1 by igor_nz, on Flickr"><img src="http://farm5.static.flickr.com/4017/4426747172_0fb8847feb.jpg" width="500" height="375" alt="ff1" /></a></div><p></p><p>
It turns out the pretty red-eyed fly is <i>Oxysarcodexia taitensis, </i>one of the Sarcophagidae. That family name gives you a clue to how this fly makes its living, it translates as "flesh eating" (it stems from the same root words as sarcophagus, the Greeks believed limestone ate away at corpses sealed in it). Most of the flesh-flies feed on dead animals but a few have earned a place in vertebrate nightmares, horror movies and even <a href="http://membracid.wordpress.com/2010/01/21/maggot-therapy/">medical practice</a> by depositing their maggots in on open wounds. </p><p>
</p><p>Relying on dead animals for food is a chancy business. Corpses are usually patchily distributed and there a plenty of other scavangers out there to compete with. This problem is especially bad for the larval stages of insects, without wings to get them to the next corpse their entire future depends on the continued existence of the flesh they are born on. The sarcophogids have developed a neat trick for making the most of corpse when they find one - they give birth to live maggots. Technically, the flesh flies are ovo-larviparous, meaning the larva develops inside an egg which is retained in the female until the larva hatches. Flesh-fly maggots can start eating as soon as they are born, maximizing their chances of getting through their lifecycle before another scavenger eats the corpse they live in.</p><p>It's easy to get freaked out about a creature that spends it's life eating decaying flesh but we should remember that flesh-flies play an important role in ecosystems. Sarcophigids and other scavengers turn dead flesh into living flesh. <a href="http://www.edge.org/3rd_culture/hamilton/hamilton_index.html">WD Hamilton</a>, one of evolutionary biology's most insightful and original thinkers, recognised the important role of carrion feeding insects in his burial instructions:</p><p>
</p>
<blockquote>
"I will leave a sum in my last will for my body to be carried to Brazil and to these forests. It will be laid out in a manner secure against the possums and the vultures just as we make our chickens secure; and this great Coprophanaeus beetle will bury me. They will enter, will bury, will live on my flesh; and in the shape of their children and mine, I will escape death. No worm for me nor sordid fly, I will buzz in the dusk like a huge bumble bee. I will be many, buzz even as a swarm of motorbikes, be borne, body by flying body out into the Brazilian wilderness beneath the stars, lofted under those beautiful and un-fused elytra which we will all hold over our backs. So finally I too will shine like a violet ground beetle under a stone.".
</blockquote>David Winterhttp://www.blogger.com/profile/09704684760112027351noreply@blogger.com3tag:blogger.com,1999:blog-4718577088343779246.post-54196943456991198592010-03-07T16:20:00.002+13:002010-03-07T20:24:22.934+13:00Sunday Spinelessness - Survivor<p>
Until today these Sunday Spinelessness posts have been severely unrepresentative. I've talked about molluscs and myriopods and shown you photos of anthozoans and arachinids but nowhere in these posts have I included a post about a beetle. Which is a shame because, to a first approximation, every species on earth is a beetle. Really. Most animals are arthropods, most arthropods are insects and most insects are beetles. In all, 350 000 species have been described so far, about a third of the total number of species from all groups. The star of today's piece is one of New Zealand's 4 500 described species.
</p><p>
</p><div style="text-align: center;"><a href="http://www.flickr.com/photos/igor_nz/4411871545/" title="longhorn0 by igor_nz, on Flickr"><img src="http://farm5.static.flickr.com/4023/4411871545_248a4a6f6a.jpg" width="500" height="348" alt="longhorn0" /></a></div><p>
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I found our star stuck in one of <a href="http://theatavism.blogspot.com/2010/01/sunday-spinelessness-dipteran-deathtrap.html">those deadly rhododendron shoots </a>. I guess if I was a cold-hearted documentarian, interested only in recording the happenings of the natural world, I would have left him there to struggle. But, really, I'm just a sucker for handsomely striped <a href="http://en.wikipedia.org/wiki/Elytron">elytron</a> so I helped disentangle him from the sticky shoot.
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</p><div style="text-align: center;"><a href="http://www.flickr.com/photos/igor_nz/4412639492/" title="longhorn1 by igor_nz, on Flickr"><img src="http://farm3.static.flickr.com/2769/4412639492_f4c2ae80be.jpg" width="500" height="375" alt="longhorn1" /></a></div><p></p><p>
Those impressive antennae place our specimen in the order Cerambycidae, the long horn beetles, which includes the famous <a href="http://www.landcareresearch.co.nz/research/biosystematics/invertebrates/invertid/bug_details.asp?Bu_Id=200">huhu beetle</a>. I can't identify it down to species but it's likely in the genus <span style="font-style:italic;">Coptomma</span> (for what it's worth, the taxonomic shorthand for 'some species in <span style="font-style:italic;">Coptomma'</span> is '<span style="font-style:italic;">Comptomma</span>. sp'). Our <i>Coptomma </i>didn't seem to have any long lasting effects from his run in with the rhododendron's sticky trap, he wandered off my life-raft leaf and set about cleaning himself up:
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</p><div style="text-align: center;"><a href="http://www.flickr.com/photos/igor_nz/4412635602/" title="longhorn2 by igor_nz, on Flickr"><img src="http://farm5.static.flickr.com/4003/4412635602_8b08900315.jpg" width="500" height="310" alt="longhorn2" /></a></div><p></p>David Winterhttp://www.blogger.com/profile/09704684760112027351noreply@blogger.com0tag:blogger.com,1999:blog-4718577088343779246.post-28066170996716250112010-02-26T10:19:00.005+13:002010-02-26T11:04:23.456+13:00You have to be in to win...<a href="http://researchblogging.org/static/index/page/awards"><img alt="Research Blogging Awards 2010 Finalist" src="http://researchblogging.org/public/static/img/rb_badge_finalist.png" style="border:0;" /></a>So, in a fit of egotism and optimism I nominated myself (and a bunch of other people) for the <a href="http://www.researchblogging.org/static/index/page/awards">Research Blogging Awards</a> - putting myself forward in the category of "Best Lay-Level Blog". The finalists were announced today and it seems I made the list. Apparently in the next stage researchblogging.org members vote for their favourite blogs in each catergory. I think it's safe to say I'll be out of the running once voting starts but I'm really quite chuffed and... damn it I'm just gonna say it... it's an honour just to be nominated among real writers lie Brian Switek of <a href="http://scienceblogs.com/laelaps/">Laelaps</a> and Ed Yong of <a href="http://scienceblogs.com/notrocketscience/">Not Exactly Rocket Science</a> and the bloggers behind <a href="http://layscience.net/">The Lay Scientist</a>, <a href="http://observationsofanerd.blogspot.com/">Observations of a Nerd</a>, <a href="http://maukamakai.wordpress.com/">Mauka to Makai</a> and <a href="http://scienceblog.cancerresearchuk.org/">Cancer Research UK's blog</a>.<div><div><div>
<p></p>
</div><div>Congratulations to all the finalists but in particular to <a href="http://sciblogs.co.nz/misc-ience/">Aimee Whitcroft</a> who does a lot of work behind the scenes at <a href="http://www.blogger.com/www.sciblogs.co.nz">sciblogs </a>and has been nominated in the chemistry physics and astronomy category.</div></div></div>David Winterhttp://www.blogger.com/profile/09704684760112027351noreply@blogger.com2tag:blogger.com,1999:blog-4718577088343779246.post-82747011522295126092010-02-20T22:08:00.004+13:002010-02-21T15:00:45.589+13:00Sunday Spinelessness - Animals that don't move<p>There aren't many universal laws in biology. <a href="http://www.corante.com/loom/archives/000796.html">Snails proved Dollo wrong</a>, retorviruses did for Crick's Central Dogma of Molecular Biology and every lesson on Mendel's Laws of Inheritance includes a section of the exceptions to those rules. Biology's disregard of human laws notwithstanding, you might think, at least as far as macro-organisms are concerned, you could safely generalise that animals move and plants stay still. But once you consider the ocean even that generalisation can't be supported; corals, bryozoans, sea squirts, anemones and sponges are all animals that spend their adult life in one spot.</p>
<p>
While I was in Masterton for christmas my girlfriend went to Vanuatu (no, you're right, that doesn't quite seem fair...) with a waterproof camera so I've stolen a few of her photos of coral to illustrate todays sunday spinelessness.</p><div style="text-align: center;">
</div><p></p><div style="text-align: center;">
</div><div style="text-align: center;"><a href="http://www.flickr.com/photos/igor_nz/4373472883/" title="P1000095 by igor_nz, on Flickr"><span class="Apple-style-span" style="color: rgb(0, 0, 0); -webkit-text-decorations-in-effect: none; "></span></a><a href="http://www.flickr.com/photos/igor_nz/4373472883/" title="P1000095 by igor_nz, on Flickr"><img src="http://farm5.static.flickr.com/4066/4373472883_517a56eb87.jpg" width="500" height="375" alt="P1000095" /></a></div><p></p><p></p><div style="text-align: center;">
</div><div style="text-align: center;"><a href="http://www.flickr.com/photos/igor_nz/4373473335/" title="coral2 by igor_nz, on Flickr"><span class="Apple-style-span" style="color: rgb(0, 0, 0); -webkit-text-decorations-in-effect: none; "></span></a><a href="http://www.flickr.com/photos/igor_nz/4373473335/" title="coral2 by igor_nz, on Flickr"><img src="http://farm5.static.flickr.com/4005/4373473335_009ee362de.jpg" width="500" height="375" alt="coral2" /></a></div><p></p><p>
</p><p>
It's easy to see why early naturalist thought corals were plants but what you are looking at in those photos is not a single organism, rather it's a colony of tiny genetically identical animals. Corals are members of the phylum <a href="http://www.org.tolweb.org/Cnidaria">Cnidaria</a> (the 'c' is silent) which includes corals, anemones and a diverse bunch of animals we call jellyfish. Such a diverse collection of animals are united under the name Cnidaria because they all employ the impressive <a href="http://en.wikipedia.org/wiki/Cnidocyte">nematocyst</a>, a barbed harpoon like cell, to catch and deliver toxin to their prey. Cnidarians have two distinct life stages - a swimming "medusa" (adult jellyfish being the classic example) and a sessile <a href="http://en.wikipedia.org/wiki/Polyp">polyp</a> (like the sea anemones familiar to rock pool fossickers the world over). Individual coral colonies (termed "heads") are made entirely of polyps which reproduce asexually <a href="http://oceanservice.noaa.gov/education/kits/corals/coral03_growth.html">depositing a calcium carbonate base as they grow</a> - the exact pattern in which polyps bud from their parents determines the shape a coral head takes.</p><p>
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Many tropical corals supplement their diets by forging a symbiotic relationship with swimming algae (arguably plants that move...) called zooxanthella, the algae get carbon dioxide from the coral's respiration while the coral gets energy from the algae. This relationship is of huge importance in the tropics because it allows corals to grow in those region's warm, nutrient poor waters. Without coral reefs, made from thousands of years of calcification from corals, tropical waters would be nowhere near as biodiverse as they are now and people whose love of animals only goes as far as that peculiar phylum Chordata should care about that:<p></p>
<div style="text-align: center;"><a href="http://www.flickr.com/photos/igor_nz/4374442418/" title="c5 by igor_nz, on Flickr"><img src="http://farm3.static.flickr.com/2758/4374442418_da1e4f3d8a.jpg" width="500" height="375" alt="c5" /></a></div><p></p><div style="text-align: center;">
</div><div style="text-align: center;"><a href="http://www.flickr.com/photos/igor_nz/4374441566/" title="c4 by igor_nz, on Flickr"><span class="Apple-style-span" style="color: rgb(0, 0, 0); -webkit-text-decorations-in-effect: none; "></span></a><a href="http://www.flickr.com/photos/igor_nz/4374441566/" title="c4 by igor_nz, on Flickr"><img src="http://farm3.static.flickr.com/2728/4374441566_de9eee4ce9.jpg" width="500" height="375" alt="c4" /></a>
<p>
As always, you can click on any of those photos to see higher-resolution versions.</p></div>David Winterhttp://www.blogger.com/profile/09704684760112027351noreply@blogger.com2tag:blogger.com,1999:blog-4718577088343779246.post-60261691897905526092010-02-14T08:58:00.001+13:002010-02-14T08:58:00.190+13:00Sunday Spinelessness - robber fly<div style="text-align: center;"><a href="http://www.flickr.com/photos/igor_nz/4350171431/" title="robber2 by igor_nz, on Flickr"><img src="http://farm5.static.flickr.com/4019/4350171431_ca6475afb7.jpg" width="500" height="375" alt="robber fly eating a blowfly" /></a></div><div style="text-align: left;">
</div>
<p>
I've<a href="http://theatavism.blogspot.com/2010/01/sunday-spinelessness-christmas-dinner.html"> said before</a> that the bugs in my parents' back yard seemed especially hungry over the Christmas break. Above you see more evidence to this fact. In the lower half of the photo is a <a href="http://www.geller-grimm.de/general.htm">robber fly</a> and above is its meal, a blowfly of some sort. I've never seen live robber flies in Dunedin (<a href="http://theatavism.blogspot.com/2010/01/sunday-spinelessness-dipteran-deathtrap.html">though there is a dead one here</a>) but the species captured above seems to be reasonably common in the Wairarapa. The first time I spotted one of them I struggled as to where to place it among the insects. The robber flies have long slender bodies and large rounded eyes which misled me into thinking that first sighting might be a small dragonfly. The real taxonomic position of the robber flies is spelt out in bright yellow in the next photo.
</p><p>
</p><div style="text-align: center;"><a href="http://www.flickr.com/photos/igor_nz/4350917806/" title="robber3 by igor_nz, on Flickr"><img src="http://farm5.static.flickr.com/4004/4350917806_70c5c21a5e.jpg" width="500" height="375" alt="robber fly - check out the halteres" /></a></div><p></p><p>
That bright yellow structur under the main wing is a <a href="http://en.wikipedia.org/wiki/Halteres">haltere</a>. Most insects have two sets of wings and we can tell quite a lot about where a given species fits in the insect scheme based on how it uses those two. Dragonflies and damselflies use both for flying, in beetles the forewings are "sclerotised" into a rigid case that protects the flight wings<span class="Apple-style-span" style="font-family: sans-serif, serif; font-size: 13px; line-height: 19px; "><span class="Apple-style-span" style="font-family: Georgia, serif; font-size: 16px; line-height: normal; "> and the "true flies" ( order Diptera) have turned thier hind-wings into halteres - greatly reduced wings which act as gyroscopes stabilising the flies' flight and allowing them to perform aerobatic tricks. The robber flies from the extremely widespread and speciose family dipteran family <a href="http://www.geller-grimm.de/asilidae.htm">Asilidae</a> which includes a staggering 7 000 described species, meaning there are rather more robber fly species in the world than there are mammalian ones.</span></span></p><p>The features that led me to mistake that first robber fly that I saw for a dragonfly are likely the result of convergent evolution - dragonflies and robber flies are both predators that specialize in taking other insects on the wing. The robber flies differ from odonates in having piercing mouth-parts which they use to inject first a neurotoxin then digestive enzymes into their prey. The blowfly in the photos in this post is paralysed and its tissues are in the process of being liquified and sucked through the robber flies mouth parts. But ever before the neurotoxin entered the blowfly's body it was done for, the robber fly's strong "raptorial" legs are covered in sharp spikes and end in claws that offer little hope for escape once a catch is made.</p><p>
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</p><div style="text-align: center;"><a href="http://www.flickr.com/photos/igor_nz/4350171545/" title="robber1 by igor_nz, on Flickr"><img src="http://farm5.static.flickr.com/4049/4350171545_e9a01de6e7.jpg" width="500" height="375" alt="robber1" /></a></div><p></p>David Winterhttp://www.blogger.com/profile/09704684760112027351noreply@blogger.com4tag:blogger.com,1999:blog-4718577088343779246.post-60007300893713502172010-02-12T12:48:00.005+13:002010-02-12T16:39:40.779+13:00Charles Darwin and the Origin of Spouses<p style="text-align: center;"><img src="http://img.photobucket.com/albums/v387/science_boy/emma_darwin.jpg" /> <img src="http://img.photobucket.com/albums/v387/science_boy/youn-chuck.jpg" /></p><p>
</p><p>Happy <a href="http://www.darwinday.org/">Darwin Day</a> everyone! Today would have been Charles Darwin's 201st birthday so around the world geeks are celebrating, <a href="http://www.butler.edu/clergyproject/rel_evolution_weekend_2009.htm">churches are standing up to creationism</a> and at least a few <a href="http://pinicola.ca/darwind2.htm">biologists are trying to eat their way through the tree of life</a>. With Darwin Day falling so close to Valentines Day I thought it might be fun to forget about Darwin's science just for a few minutes and look at his attitude to love and marriage.
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No one has ever accused Darwin about making a rush to judgement about any topic. Just as he spent years poring over the minutest detail of barnacle anatomy before he published <i>The Origin</i> he gave the topic of marriage careful consideration before singing on. In fact, preserved in his notebooks we have a record of the deliberations he undertook. Sometime in 1838 Darwin turned to a new page in his notes and drew a line down the middle, he added the headings "Marry" and "Not Marry" to either side of the line an proceeded to list the pros and cons of either decision. You can <a href="http://darwin-online.org.uk/content/frameset?viewtype=side&itemID=CUL-DAR210.8.2&pageseq=1">see the notebook here</a> but below (presented without comment) is a transcript :</p>
<p>
</p><div style="width: 300px; float: left;">
<h3>Marry</h3><div>
<ul><li>Children — (if it Please God)</li><li>Constant companion, (& friend in old age) who will feel interested in one</li><li>Object to be beloved & played with —better than a dog anyhow. </li><li>Home, & someone to take care of house</li><li>Charms of music & female chit-chat.</li><li>These things good for one's health.</li><li>Forced to visit & receive relations but terrible loss of time.</li></ul></div>
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<h3>Not Marry</h3>
<ul><li>No children, (no second life), no one to care for one in old age. </li><li>What is the use of working 'in' without sympathy from near & dear friends—who are near & dear friends to the old, except relatives</li><li>Freedom to go where one liked — choice of Society & little of it. </li><li>Conversation of clever men at clubs </li><li> Not forced to visit relatives, & to bend in every trifle.</li><li>To have the expense & anxiety of children</li><li>Perhaps quarelling </li><li>Loss of time. </li><li>Cannot read in the Evenings </li><li>Fatness & idleness </li><li>Anxiety & responsibility</li><li>Less money for books &c </li><li> If many children forced to gain one's bread. (But then it is very bad for ones health to work too much)</li><li>Perhaps my wife wont like London; then the sentence is banishment & degradation into indolent, idle fool </li></ul></div>
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On the "marry" side of the page Darwin makes his conclusion:<div>
</div><div><ul><li>My God, it is intolerable to think of spending ones whole life, like a neuter bee, working, working, & nothing after all.</li><li>No, no won't do. — Imagine living all one's day solitarily in smoky dirty London House. </li><li>Only picture to yourself a nice soft wife on a sofa with good fire, & books & music perhaps — Compare this vision with the dingy reality of Grt. Marlbro' St.</li></ul><div>Darwin made his list a year before his engagement to his cousin Emma Wedgwood and it seems from their letters to each other and their personal diaries that Charles' "nice soft wife"<a href="http://articles.latimes.com/2009/jan/29/opinion/oe-heiligman29"> more than made up for the money he didn't get to spend on books</a>. There is a <a href="http://creationthemovie.com/">movie</a> out at the moment which apparently makes much of the religious divide between the Darwins. Emma was certainly a devout Unitarian (apparently she made the children turn their heads during the Nicene Creed and their local Anglican church!) who worried that Charles' skepticism of religion would prevent them from being joined in Heaven. Religion was a sticking point for the Darwins but they reached a sort of detente on the topic epitomised by one <a href="http://www.darwinproject.ac.uk/entry-441">of Emma's letters to Charles during their engagement</a>:
<blockquote>
When I am with you I think all melancholy thoughts keep out of my head but since you are gone some sad ones have forced themselves in, of fear that our opinions on the most important subject should differ widely. My reason tells me that honest & conscientious doubts cannot be a sin, but I feel it would be a painful void between us. I thank you from my heart for your openness with me & I should dread the feeling that you were concealing your opinions from the fear of giving me pain.
</blockquote></div></div>David Winterhttp://www.blogger.com/profile/09704684760112027351noreply@blogger.com2tag:blogger.com,1999:blog-4718577088343779246.post-7274604989825442032010-02-07T14:29:00.007+13:002010-02-08T18:35:17.927+13:00Sunday Spinelessness - now with 150% more links<p>
None of my photos today, instead I thought we should have a look at what some of web's other inveterate invertebrate bloggers have been up to.
</p><p>
</p><div style="text-align: center;"><span style="color: rgb(153, 153, 153);font-size:85%;" ><img src="http://www.giantmicrobes.com/us/files/images/productdetails/waterbear.jpg" />
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Giant Microbe's plush Tardigrade</p></span><p></p>
</div><p></p><ul><li>Ted MacRae at <a href="http://beetlesinthebush.wordpress.com/">Beetles in the Bush</a> hosted the <a href="http://beetlesinthebush.wordpress.com/2010/02/01/circus-of-the-spineless-47/">latest edition of the Circus of the Spineless </a>which includes posts on noisy ants, maggot therapy, the place of amphipods in pop culture and no fewer than two samurai related stories.</li><li>Weird Bug Lady (check out her<a href="http://www.etsy.com/shop/weirdbuglady"> Etsy shop</a>, it's amazing...) now sells a stuffed toy in the shape of a flatworm. Yes, <a href="http://weirdbuglady.blogspot.com/2010/02/theyre-stuffed.html">plush planarians</a>!</li><li>Sticking with the plush theme (as phrase I never thought I'd write...) the people behind the wonderful <a href="http://www.giantmicrobes.com/">Giant Microbes</a> have stretched their reach into Metazoa, the latest example a plush <a href="http://www.giantmicrobes.com/us/products/waterbear.html">water bear (Tardigrade)</a>! I note they are not yet available in the Australian/ New Zealand version of their store, but how can animal<a href="http://weirdimals.wordpress.com/2009/07/05/water-bears/"> this cool</a> fail to become a top seller?</li><li>There's yet more invertebrate craft at <a href="http://iloveinsects.wordpress.com/">I Love Insects</a> where <a href="http://iloveinsects.wordpress.com/2010/01/14/one-for-the-kid-in-all-of-us-origami-insects/">Erika finds oragami insects</a>
</li><li>Finally, Mike at <a href="http://arthropoda.wordpress.com/">Arthropoda</a> has more evidence of the coming insect revolution - <a href="http://arthropoda.wordpress.com/2010/02/04/bees-can-learn-to-discriminate-human-faces/">bees have learned how to recognise our faces</a>. I for one refuse to <a href="http://itre.cis.upenn.edu/%7Emyl/languagelog/archives/000399.html"> make the obvious joke</a>.</li></ul>
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</p><div style="text-align: center; color: rgb(153, 153, 153);"><span style="font-size:85%;"><img src="https://blogger.googleusercontent.com/img/b/R29vZ2xl/AVvXsEj4ru1NAALRHMPQaq1f1k9euOA9ivqHN-nNlPvxGslFLMWRJ5Mr4O9z0_ItHYvcrLpkEBFN3hXSuk7ogAmZDZHO8g0-DI8kp-ndXaYHak6hxEQMx86j3r3hjFzetqK0DNSH1J_tVgOgGTo/s400/100_7959.JPG" />
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<p>Weird Bug Lady's plush planarians</p>
</span></div>David Winterhttp://www.blogger.com/profile/09704684760112027351noreply@blogger.com5tag:blogger.com,1999:blog-4718577088343779246.post-77148341693762941002010-02-04T19:20:00.005+13:002010-02-04T19:47:13.634+13:00Did the Moa's ancestor fly to New Zealand?<div style="text-align: center; font-size: 70%; color: rgb(102, 102, 102);">
<img src="http://farm1.static.flickr.com/22/28705276_0cbd55266d_m.jpg" /><img src="http://img.photobucket.com/albums/v387/science_boy/126523121414620.jpg?t=1265238084%22" width="200" />
<p>
Unlikely cousins? <a rel="cc:attributionURL" href="http://www.flickr.com/photos/brunogirin/">Tinamou from brunorigin @ flickr</a> (<a rel="license" href="http://creativecommons.org/licenses/by-sa/2.0/">CC BY-SA 2.0</a>| Moa from <a href="http://www.plosbiology.org/article/info:doi%2F10.1371%2Fjournal.pbio.0030020">PLoS Biology</a></p>
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<a href="http://www.researchblogging.org/"><img alt="ResearchBlogging.org" src="http://www.researchblogging.org/public/citation_icons/rb2_small.png" style="border: 0pt none ;" /></a>
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New Zealanders often think of our unique biota as a sort of time capsule - a glimpse at lifeforms that have long since been extinguished in other parts of the world. New Zealand has been apart from the rest of the world for 85 million years. At that time the land that makes up our mini-continent split from the super-continent <a href="http://en.wikipedia.org/wiki/Gondwana">Gondwana</a>, opening up the <a href="http://www.teara.govt.nz/en/geology-overview/6">Tasman Sea</a> and moving northward . A land apart from the rest of the world. Until recently most scientists have thought that the subset of the Gondwanan flora and fauna that set sail on that proto-New Zealand was likewise on its own evolutionary trajectory -insulated from biological happenings in the rest of the world. The idea of the New Zealand biota as a group of refugees from an ancient ecosystem hanging onto "Moa's Ark"<a href="http://www.nzonscreen.com/title/moas-ark-1990/series"> has become part of the New Zealand psyche</a>.
<p></p>
In recent years Moa's Ark has sprung more than a few leaks. Icons of our Gondwanan heritage like <span style="font-style: italic;">Nothofagus</span> beech trees have been shown to be recent arrivals. Geologists have suggested the whole continent submerged 20 million years ago, drowning any refugees still on board, and now new research suggests even the most unlikely of immigrants - the giant, flightless moa - may have arrived in New Zealand well after we left Gondwana.
<p>
The group of birds to which the moa belonged, the ratites, have long fascinated evolutionary biologists. All the ratites are flightless (though, as we'll see they are related to the quail-like <a href="http://en.wikipedia.org/wiki/Tinamou">tinamous</a> which can fly passably well) and all the major landmasses that had their start in Gondwana had at least one ratite species before humans arrived on the scene. Africa has ostriches, South America the rhea, Australians have emus and cassowary, Madagascar had the Elepahant bird and New Zealand lost the moa but retains the kiwi. The far flung distribution of the ratites and their apparent lack of ability to disperse between continents has led to them being put forward as a classic example of an idea called <a href="http://www.blackwellpublishing.com/ridley/tutorials/Evolutionary_biogeography17.asp">vicariance biogeography</a> in which the evolutionary history of a group is driven by the geological history of the land on which they live.
</p><p>
For vicariance biogeographers the evolution of the ratites was driven by the movement of the continents. The ancestor of all modern ratites was a flightless bird living in Gondwana and as each new continent split and rifted away from the super continent it took with it a population of ratites which adapted to the ecological changes brought on by their continent's journey: cassowaries in the Wet Tropics of Australia, ostriches on the African Savannah, rhea on the Pampas. It's certainly a nice story, but science has a way of ruining nice stories. The role of vicariance of evolution in the ratites was put to the test once we became able to use molecular evidence to reconstruct the relationships between species. If the geologically driven sketch of ratite evolution I presented above is right then the pattern of branching we find among ratites from different continents should match the order in which we know the continents broke up, something like this:</p><p>
</p><p>
</p><div style="text-align: center;"><img src="http://img.photobucket.com/albums/v387/science_boy/hypothesis.png?t=1265179886" />
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In 2001 <a href="http://www.adelaide.edu.au/acad/people/acooper_profile.html">Alan Cooper</a> and colleagues sequenced the entire mitochondrial genome (some 12 000 bases of DNA) from representatives of each of the extant ratites and, remarkably, two species of moa. The long, careful process of retrieving DNA sequences from sub-fossil bones deserves a post of its own but for the sake of this article we only need to know what Cooper <span style="font-style: italic;">et al</span> found when they used that DNA to recover the the relationships between ratite species.
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</p><div style="text-align: center;"><img src="http://img.photobucket.com/albums/v387/science_boy/cooper01.png?t=1265179891" />
</div><p></p><p>
The species in bold text above don't fit the pattern that we'd expect from geology alone. If ratite relationships simply reflected the Gondwanan breakup we'd expect to see ostriches grouping with rheas (and apart from the other ratites). New Zealand's two ratite orders are even more surprising, the kiwi lineage is more closely related to the Australian ratites than it is to the moa species. When combined with a molecular clock analysis Cooper et al. concluded that modern kiwis are the descendants of ancient immigrants hailing from either Australia or islands in the <a href="http://en.wikipedia.org/wiki/Lord_Howe_Rise">Lord Howe Rise</a> (which have since submerged). In order to explain that trans-tasman dispersal the authors reached for the last resort of the desperate biogeographer and invoked a land bridge for which there is little geological evidence. In fact, as we'll see it now seems more likely that the ancestors of the kiwi and the moa flew to New Zealand.
</p><p>
Even with the mitochondrial phylogeny of the group published there was considerable room for uncertainty in how the ratites related to each other. The underlying shape of ratite tree makes it particularly difficult to accurately recover with phylogenetic methods. When we use DNA sequences to estimate a phylogenetic tree we need to find species that share mutations that have accrued during the evolution of the group we're looking at. The branches that relate the different ratite species are relatively short, so there was little time for mutations that set related groups apart from more distantly related ones to accrue. Even worse, the branches that reach to the modern species (the tips of the tree) are very long meaning there has been a lot of time to any mutations that did accrue in those critical short branches to be overwritten<a href="#note1">*</a>. There are three approaches to dealing with this problem - sequence more genes (since each unlinked gene acts as a separate witness to the evolution of the group), sequence more samples (especially if doing so breaks up a long branch) or use a better model for the way mutations accrue in the genes you are studying. People have tried all three methods to get a better look at ratite evolution. Last year<a href="http://www.fieldmuseum.org/research_collections/zoology/zoo_sites/early_bird/"> a group centred around the Field Museum in Chicago</a> published a mutli-gene phylogeny of all birds that contained a big surprise for ratite evolution- the most recent common ancestor of all ratites flew.
</p><p>
</p><div style="text-align: center;"><img src="http://img.photobucket.com/albums/v387/science_boy/ToL.png?t=1265179891" />
</div><p>As long as the ratites grouped together in a phylogeny it was reasonable to assume that they all inherited their flightlessness from the common ancestor of the group. The Field Museum study found that, in fact, the flying tinomous fit right in the middle of the flightless ratites. So, either the most recent common ancestor of the ratites and the tinamous flew and ratite lineages have subsequently lost that ability at least three times or that ancestor was grounded and the tinamous have rediscovered flight. In vertebrates the evolution of true flight has happened three times (in bats, pterosaurs and birds) while there are hundreds of examples of birds that have given up on flying. Moreover, a group of flying birds that are prone to flightlessness is hardly anything new - at least 30 species of rail (including our own weka and takahe) have taken to life on the ground. Given the ways the odds are stacked towards losing flight it seems probable the common ancestor that relates tinamous and ratites flew. The Field Museum study didn't include any moa species and didn't attempt any molecular dating so it's hard to see just how the ancestors of the kiwi and the moa made it to New Zealand
</p><p>
A new study (I knew I'd get to it eventually) published in <span style="font-style: italic;">Systematic Biology </span>throws some light on the New Zealand ratite story. <a href="http://www.anu.edu.au/BoZo/staffandstudents/staffprofiles/phillips.php">Matt Philips</a> and a team of researchers from the Alan Wilson Centre at Massey University took another look at the mitochondrial dataset used in Cooper <span style="font-style: italic;">et al's</span> 2001 study by adding more kiwi species and using models of DNA evolution that avoid some of the pitfalls of the ratite phylogeny's difficult shape. The new ratite tree and a molecular clock analysis based on that tree confirm the idea of multiple loses of flight in the ratites and add a new finding - the closest living relatives of our giant moa are the quail-like tinamous:</p><p>
</p><div style="text-align: center;"><img src="http://img.photobucket.com/albums/v387/science_boy/new.png?t=1265179891" />
</div><p></p><p>
</p><p>So what does the new understanding of ratite relationships mean for our ideas about the origins of New Zealand's ratites? The <a href="http://www.nature.com/scitable/topicpage/The-Molecular-Clock-and-Estimating-Species-Divergence-41971">molecular clock</a> doesn't quite tick with the regularity of a stopwatch, so there is a good deal more uncertainty in the timing of the events presented above than the precisely defined nodes suggest. Still, even with the uncertainty of molecular dating taken on board we can safely say that both the New Zealand ratite lineages departed from their closest relatives after the Tasman Sea opened up.
</p><p>The revelation that the tinamous are the moa's closest living relatives suggests that the moa had ancestors that could fly. So, it seems the first proto-moa to arrive in New Zealand flew, or more likely was blown, here from Antarctica. Antarctica? It still seems amazing to me but 30 million years ago Antartica was still attached to South America and, without the <a href="http://en.wikipedia.org/wiki/Antarctic_Circumpolar_Current">circumpolar current</a> to isolate from the world, was a relatively verdant continent. We know from fossils that Antarctica supported southern beech forests (still found in Chile, New Zealand and Australia) and marsupial mammals (strangely absent in New Zealand but still present in Australia and South America) so it's no great stretch to propose the representatives of another Gondwanan group lived there. Antarctica certainly seems like a more likely jumping off point for dispersing proto-moa than South America, but either way it certainly seems they made it here under their own power.</p><p>
The mode of dispersal for the kiwi's ancestor is a little less clear. As we've seen we can be quite sure that they arrived in New Zealand after the Tasman Sea opened up and there is really no good evidence that there was ever a land-bridge across that sea. We can probably rule out walking. If we disregard the problem of dispersal for a second the simplest way to explain the distribution of flightlessness on the Phillips <span style="font-style: italic;">et al</span> phylogeny is with a single loss of flight in an ancestor shared by kiwis and the Australian ratites. Under that scenario the kiwi would, presumably, have had to raft to New Zealand. Alternatively, given that we've seen the ratites seem to have an inbuilt propensity to becoming flightless we might imagine that the common ancestor shared by the kiwi and the Australian ratites could fly and each lineage has since lost that ability. In this case the kiwi could simply have flown from Australia to New Zealand (a journey that storms frequently inflict on Australian birds today). Without sufficiently old ratite fossils from either country it's hard to choose one scenario over the other.<a href="http://scienceblogs.com/laelaps/2010/01/surfs_up_how_rafting_lemurs_co.php">Long range dispersal by rafting is probably an important force in biogeography</a> but if I was forced to make a bet I'd put my money on ancient flying kiwis.</p><p>The radical rethink of ratite evolution that a decade of molecular phylogenetics has forced on us raises a lot of interesting questions. What it is it about the ratite body plan, development or behaviour that makes them so prone to flightlessness? Is that repeated loss of flight, and consequent lack of pressure to keep their weight down, enough to explain the trend towards gigantism? The authors of the most recent paper suggest both trends might be explained by ratites on each continent filling the ecological niches left by the extinction of the dinosaurs. The dates on their tree are certainly consistent with the idea that each ratite lineage independently took to the ground 65 million years ago but without more fossils and more precise dates for each split it's very hard to test the idea further. I'm sure the story of ratite evolution has more surprises for us to uncover.
</p><p>
</p><p><div id="note1">*</div><span style="font-style: italic;">Outrageously geeky aside: these sorts of phylogenetic trees can even fall into the terrifying Felsenstein Zone in which the confidence with which you estimate </span><span style="font-style: italic;">the </span><span>wrong </span><span style="font-style: italic;">tree</span><span style="font-style: italic;"> increases as you throw more data at it.</span>
</p>
<hr width="66%">
<p>
<span style="font-style: italic;">Links to the primary literature are provided below but you should also check out </span><a style="font-style: italic;" href="http://www.nzherald.co.nz/nz/news/article.cfm?c_id=1&objectid=10623539">Simon Collins excellent piece in the Herald</a><span style="font-style: italic;"> and Mike Dickison, who got his PhD studying giant flightless birds </span><a style="font-style: italic;" href="http://www.giantflightlessbirds.com/research/2007/12/did_ratites_fly_to_new_zealand.html">and wrote about the idea that ratites flew to New Zealand way back in 2007</a><span style="font-style: italic;">.</span>
</p>
<span class="Z3988" title="ctx_ver=Z39.88-2004&rft_val_fmt=info%3Aofi%2Ffmt%3Akev%3Amtx%3Ajournal&rft.jtitle=Nature&rft_id=info%3Apmid%2F11217857&rfr_id=info%3Asid%2Fresearchblogging.org&rft.atitle=Complete+mitochondrial+genome+sequences+of+two+extinct+moas+clarify+ratite+evolution.&rft.issn=0028-0836&rft.date=2001&rft.volume=409&rft.issue=6821&rft.spage=704&rft.epage=7&rft.artnum=&rft.au=Cooper+A&rft.au=Lalueza-Fox+C&rft.au=Anderson+S&rft.au=Rambaut+A&rft.au=Austin+J&rft.au=Ward+R&rfe_dat=bpr3.included=0;bpr3.tags=Biology%2CEvolutionary+Biology%2C+Genetics%2C+Creative+Commons%2C+Taxonomy">Cooper A, Lalueza-Fox C, Anderson S, Rambaut A, Austin J, & Ward R (2001). Complete mitochondrial genome sequences of two extinct moas clarify ratite evolution. <span style="font-style: italic;">Nature, 409</span> (6821), 704-7 PMID: <a rev="review" href="http://www.ncbi.nlm.nih.gov/pubmed/11217857">11217857</a></span>
<p></p>
<span class="Z3988" title="ctx_ver=Z39.88-2004&rft_val_fmt=info%3Aofi%2Ffmt%3Akev%3Amtx%3Ajournal&rft.jtitle=Proceedings+of+the+National+Academy+of+Sciences&rft_id=info%3Adoi%2F10.1073%2Fpnas.0803242105&rfr_id=info%3Asid%2Fresearchblogging.org&rft.atitle=Phylogenomic+evidence+for+multiple+losses+of+flight+in+ratite+birds&rft.issn=0027-8424&rft.date=2008&rft.volume=105&rft.issue=36&rft.spage=13462&rft.epage=13467&rft.artnum=http%3A%2F%2Fwww.pnas.org%2Fcgi%2Fdoi%2F10.1073%2Fpnas.0803242105&rft.au=Harshman%2C+J.&rft.au=Braun%2C+E.&rft.au=Braun%2C+M.&rft.au=Huddleston%2C+C.&rft.au=Bowie%2C+R.&rft.au=Chojnowski%2C+J.&rft.au=Hackett%2C+S.&rft.au=Han%2C+K.&rft.au=Kimball%2C+R.&rft.au=Marks%2C+B.&rft.au=Miglia%2C+K.&rft.au=Moore%2C+W.&rft.au=Reddy%2C+S.&rft.au=Sheldon%2C+F.&rft.au=Steadman%2C+D.&rft.au=Steppan%2C+S.&rft.au=Witt%2C+C.&rft.au=Yuri%2C+T.&rfe_dat=bpr3.included=0;bpr3.tags=Biology%2CEvolutionary+Biology%2C+Genetics%2C+Creative+Commons%2C+Taxonomy">Harshman, J., Braun, E., Braun, M., Huddleston, C., Bowie, R., Chojnowski, J., Hackett, S., Han, K., Kimball, R., Marks, B., Miglia, K., Moore, W., Reddy, S., Sheldon, F., Steadman, D., Steppan, S., Witt, C., & Yuri, T. (2008). Phylogenomic evidence for multiple losses of flight in ratite birds <span style="font-style: italic;">Proceedings of the National Academy of Sciences, 105</span> (36), 13462-13467 DOI: <a rev="review" href="http://dx.doi.org/10.1073/pnas.0803242105">10.1073/pnas.0803242105</a>
<p></p>
</span><span class="Z3988" title="ctx_ver=Z39.88-2004&rft_val_fmt=info%3Aofi%2Ffmt%3Akev%3Amtx%3Ajournal&rft.jtitle=Systematic+Biology&rft_id=info%3Adoi%2F10.1093%2Fsysbio%2Fsyp079&rfr_id=info%3Asid%2Fresearchblogging.org&rft.atitle=Tinamous+and+Moa+Flock+Together%3A+Mitochondrial+Genome+Sequence+Analysis+Reveals+Independent+Losses+of+Flight+among+Ratites&rft.issn=1063-5157&rft.date=2009&rft.volume=59&rft.issue=1&rft.spage=90&rft.epage=107&rft.artnum=http%3A%2F%2Fsysbio.oxfordjournals.org%2Fcgi%2Fdoi%2F10.1093%2Fsysbio%2Fsyp079&rft.au=Phillips%2C+M.&rft.au=Gibb%2C+G.&rft.au=Crimp%2C+E.&rft.au=Penny%2C+D.&rfe_dat=bpr3.included=1;bpr3.tags=Biology%2CEvolutionary+Biology%2C+Genetics%2C+%2CCreative+Commons">Phillips, M., Gibb, G., Crimp, E., & Penny, D. (2009). Tinamous and Moa Flock Together: Mitochondrial Genome Sequence Analysis Reveals Independent Losses of Flight among Ratites <span style="font-style: italic;">Systematic Biology, 59</span> (1), 90-107 DOI: <a rev="review" href="http://dx.doi.org/10.1093/sysbio/syp079">10.1093/sysbio/syp079</a></span>David Winterhttp://www.blogger.com/profile/09704684760112027351noreply@blogger.com11tag:blogger.com,1999:blog-4718577088343779246.post-18297179607312041492010-01-31T09:14:00.000+13:002010-01-31T09:14:00.299+13:00Sunday Spinelessness - Motherly Devotion<p>
I promised last week that I'd come up with something a bit more cheery than photos of dead flies for the next Sunday Spinelessness post and what could be more uplifting than portraits of motherly devotion? Of course, in this case the mother is a spider. The New Zealand lynx spider <span style="font-style: italic;">Oxyopes gracilipes</span>.
</p><p></p><div style="text-align: center;">
</div><div style="text-align: center;"><a href="http://www.flickr.com/photos/igor_nz/4289396934/" title="Gravid Lynx Spider by igor_nz, on Flickr"><span class="Apple-style-span" style="color: rgb(0, 0, 0); -webkit-text-decorations-in-effect: none; "></span></a><a href="http://www.flickr.com/photos/igor_nz/4289396934/" title="Gravid Lynx Spider by igor_nz, on Flickr"><img src="http://farm5.static.flickr.com/4004/4289396934_f34399e137.jpg" width="500" height="375" alt="Gravid Lynx Spider" /></a></div><p></p><p>
<a href="http://bugguide.net/node/view/1965">Lynx spiders</a> are a family (Oxopidae) of very active and fast running hunting spiders. The swollen abdomen of the female photographed above is evidence of her gravidity (I was tempted to dedicate this post to Harvest Bird <a href="http://www.harvestbird.com/blog/2009/12/29/gravidity/">who finds herself in the same condition</a> but I'm not quite sure how someone a little less arachnophilic than I would take that). A few days before I spotted the gravid female I'd taken some pretty poor photos of a male lynx spider on the same plant so we can probably assume he's the father.
</p><p></p>
<div style="text-align: center;"><a href="http://www.flickr.com/photos/igor_nz/4289396942/" title="LynxM by igor_nz, on Flickr"><img src="http://farm5.static.flickr.com/4013/4289396942_b7683f47b4.jpg" width="500" height="375" alt="LynxM" /></a></div><p></p>
And because that photo really is pretty awful here's another male lynx spider I found crawling around on our house
<p></p>
<div style="text-align: center;"><a href="http://www.flickr.com/photos/igor_nz/4289396930/" title="lyncM2 by igor_nz, on Flickr"><img src="http://farm5.static.flickr.com/4035/4289396930_87605d83b7.jpg" width="500" height="375" alt="lyncM2" /></a></div><p></p>
That's a bit more like it. In this one you can see a few of the defining morphological characteristics of the lynx spiders - spiny legs, a hexagonal arrangement of eyes very large and <a href="http://en.wikipedia.org/wiki/Pedipalp">palp</a>s in males. <span class="Apple-style-span" style="font-style: italic; ">O. gracilipes </span>also displays a few behavioral traits that are typical of lynx spiders, it's active during the day there is a great deal of maternal investment in offspring. Here's our female again, a little over a week after the first photo.<div>
<p></p><div style="text-align: center;">
</div><div style="text-align: center;"><a href="http://www.flickr.com/photos/igor_nz/4289396940/" title="lynxF2 by igor_nz, on Flickr"><img src="http://farm3.static.flickr.com/2685/4289396940_3dc2f9c96c.jpg" width="375" height="500" alt="lynxF2" /></a></div><p></p>
She's lost her former globose shape because she's laid her eggs. The silk she's spun around the leave is protective egg sag but lynx spiders take protection very seriously - they won't leave the fate of their eggs to a bit of silk and chance. I checked on the egg sac almost every day for two weeks and never found the lynx spider more than a few centimeters away. Little is known about the behaviour of our lynx spider but their American counterparts have been known to relocate egg sacs when they are threatened by predators or starve to death while standing guard. In the end I had to leave before the spiderlings hatched but in <i>Spiders of New Zealand and their Worldwide Kin </i>Ray and Lyn Forster tell us that the female wanders off shortly before that event.</div><p></p>
As ever you can click on the images to get to a higher resolution version.
<p></p>
<div style="text-align: center;"><a href="http://www.flickr.com/photos/igor_nz/4289871262/" title="lynxF3 by igor_nz, on Flickr"><img src="http://farm3.static.flickr.com/2701/4289871262_52cc01e959.jpg" width="500" height="311" alt="lynxF3" /></a></div>David Winterhttp://www.blogger.com/profile/09704684760112027351noreply@blogger.com2tag:blogger.com,1999:blog-4718577088343779246.post-52967819825876769022010-01-20T08:46:00.000+13:002010-01-20T08:46:00.318+13:00Doing Science in PublicA few quick links about scientists talking to the public or getting the public to help out with science:
<ul><li>Fabiana Kubke has heard something strange about Tui and wants your help to check it out. She's not telling us exactly what it is that she's testing just yet but to get involved all you have to do is <a href="http://popscinz.wordpress.com/the-nz-tui-project/">drop her a line with a few details when you see a Tui.</a> Fabiana described the project and the idea of <a href="http://en.wikipedia.org/wiki/Citizen_science">citizen science</a> to Noelle McCarthy on National Radio so I'll let her provide the details [<a href="http://static.radionz.net.nz/assets/audio_item/0009/2174481/sno-20091228-1112-Tui_science_project-m048.asx">streaming audio</a>]</li><li>A group of scientists from the Univeristy of Canterbury have been documenting their work on the Chatham Islands with a blog, <a href="http://rangatirablackrobin.blogspot.com/">Life on the Edge of the World</a>.</li><li>The people that brought you <a href="http://www.scq.ubc.ca/">Science Creative Quarterly</a> have a sneaky plan: to hijack kids' freakish ability to recall details about hundreds of Pokemon "species"and use it to teach them a few things about real animals. You can read about<a href="http://phylomon.org/"> the phylomon project here</a> - it's brand new and looking for input from graphic artists, photographers, science geeks, gaming geeks and really anyone that's interested.
</li><li>Finally, go over and welcome <a href="http://developinggeneticist.blogspot.com/">another Otago geneticists to the blogosphere</a>. Tamsin is a PhD student working on the genetics of embryonic development which means she has <a href="http://developinggeneticist.blogspot.com/search/label/Extraordinary%20Embryo%20of%20the%20Week">tonnes of stunning images</a> to blog about.
</li></ul>David Winterhttp://www.blogger.com/profile/09704684760112027351noreply@blogger.com0tag:blogger.com,1999:blog-4718577088343779246.post-74093533686698881622010-01-15T14:24:00.001+13:002010-01-15T16:00:07.816+13:00The why of the Y-Chromosome's amazing evolutionary rate<div style="text-align: center;"><img src="http://upload.wikimedia.org/wikipedia/commons/5/53/NHGRI_human_male_karyotype.png" />
</div>
<span style="padding: 5px; float: left;"><a href="http://www.researchblogging.org/"><img alt="ResearchBlogging.org" src="http://www.researchblogging.org/public/citation_icons/rb2_large_gray.png" style="border: 0pt none ;" /></a></span>
<p>
There is something faintly pathetic about the Y-chromosome when its lined up with its peers in a <a href="http://learn.genetics.utah.edu/content/begin/traits/karyotype/">karyotype</a>. Each of the 22 numbered chromosomes pair off with a near identical partner just their size while the Y has to shape up to the X which has more than twice as much DNA and 25 times as many functional genes.
</p><p>
</p><p>The puny Y-chromosome only looks worse when you realise that mammalian sex chromosomes weren't always so mismatched. 160 million years ago the X and Y were just another pair of chromosomes, albeit the pair that the carried the sex determining gene <span style="font-style: italic;">SRY</span>. Over time the chromosome that went on to become the Y stopped swapping genes with its partner, allowing it to maintain a suite of genes that are beneficial in male bodies but not in females. It's the lack of genetic recombination that sent the Y into its decline. Genes on any other chromosome can be swaped between pairs, meaning over many generations individual gene copies (called alleles) are exposed to natural selection independently of alleles either side of them. The same process doesn't apply to alleles on the Y-chromosome. Since the Y is always passed on as a single unit natural selection acts on the whole thing - a broken gene might make it into the next generation because it is attached to beneficial mutations. The efficiency of natural selection is further reduced in the Y-chromosome because it has a relatively small effective population size (less that one quarter of that for normal chromosomes since only males carry the Y and then in only one copy and even then a larger number of males than females don't contribute to the next generation) <a href="http://www.nature.com/scitable/topicpage/Genetic-Drift-and-Effective-Population-Size-772523">which makes genetic drift a strong force</a>.
</p><p>
What we've known about the Y-chromosome's past has has shaped out ideas about what it is now and what it will become. Until quite recently the Y was seen as more or less a derelict chromosome, a few broken remnants of the genes still found on the X and a couple of male-specific genes hanging on the the sex determining gene <span style="font-style: italic;">SRY</span>. People have even go so far as to extrapolate the Y's long slow decline to a future time at which the Y will simply disappear. The first clue that the Y-chromosome might be a little more resilient than that came in 2003. The publication of the complete sequence of the human Y-chromosome revealed more than fossils from the Y's more substantial ancestor. There are plenty of those so called "X-degenerate" segments but most of the active genes in the Y are in large repetitive runs of DNA called the "ampliconic regions". The genes in these regions are mainly made of DNA sequences unique to the Y chromosome and are expressed only in the testes - suggesting the Y has been making its own genes at the same time that its been losing the X-degenerate ones.
</p><p>Untill this week it has been hard to test the idea of a regenerating Y-chromosome in an evolutionary framework. Those large repeated runs of DNA are very hard to sequence (the standard metaphor is putting together a jigsaw puzzle made entirely of sky) so we haven't had another Y-chromosome sequence to compare ours with. Now, thanks to Jeniffer Hughes and colleagues, we do and the result it stunning. Not only has the Y-chromosome been making genes, it's been making them at an outrageous rate. Thirty percent of our Y-chromosome sequences have no counterpart in the chimpanzee. As the authors say that's the sort of divergence you'd expect to see between humans and chickens, which are separated by 310 million years of evolution not humans and chimps which only split 6 million years ago!
</p><p>It's evident that, far from being in the tail end of an inexorable decline, the Y-chromosome is evolving a good deal more quickly than the rest of the genome. So, the burning question is what is behind that evolutionary rate? There is probably no single answer to that question but it's safe to assume it results from some of the unique features of the Y-chromosome; a lack of genetic recombination, the presence of those large repetitive sections of DNA and the preponderance of male specific genes.
</p><p>It's usually a good idea when trying to explain an evolutionary phenomenon to think of explanations that don't invoke natural selection as the main driver as a sort of <a href="http://en.wikipedia.org/wiki/Null_hypothesis">null hypothesis</a> against which to test other ideas. In this case the increased fixation of new genes on the Y-chromosome might simply reflect an increased rate of production of new genes. Those highly repetitive sections of the Y-chromosome are the perfect substrate for a process called ectopic gene conversion in which a Y-chromosome can recombine <span style="font-style: italic;">with itself</span> and as a result duplicate streches of DNA. We know from human studies that a process like this has made wide scale structural changes in the last 100 000 years and it might be enough to explain the Y's unusual gene production.</p><p>I think it's very likely that natural selection also plays a role in the number of of those new genes that become fixed in the human and especially the chimp lineage. Most of the active genes on the Y-chromosome are expressed in the testes and involved in sperm production. Chimpanzees are highly <del>polygynous</del> <a href="http://everything2.com/title/polygynandry">polygynandrous</a> [Thanks to <a href="http://www.harvestbird.com/blog/">Harvest Bird</a> for pulling me up on this,], in most cases a female will mate with each of several dominant males in a troop, and a result sperm competition is an important level of selection. Although humans aren't as polygamous as chimps (and likely haven't been in our recent history) it's clear that fertility selection is still an important force and we know for sure that mutations in the Y-chromosome can lead to infertility so, again, the fate of new genes on the Y-chromosome are likely to be driven by selection.</p><p>Both the adaptive and non-adaptive explanations above might will be influenced by the lack of recombination in the Y-chromosome. The reduction in the efficiency of natural selection described above will stop very slightly deleterious mutations from being driven to extinction which might mean new genes that would be selected against on any other chromosome become fixed on the Y. This phenomenon can be enhanced when it is coupled with selection producing a 'selective sweep'. If a new beneficial mutation, perhaps associated with sperm competition or fertitily selection, pops up in on a chromosome with a bunch of other mutations that whole thing will be selected for and driven to fixation which has the potential to make for large scale changes quickly.</p><p>It is likely that the amazing evolutionary rate of the Y-chromosome is a result of some combination of all these factors but it should be possible to disentangle at least some of their contributions. If sperm competition is a major driver of Y-chromosome evolution then it follows that animals that go in for purely monogamous relationships will have comparatively low rates. Evolution has furnished us a natural experiment to test this idea, all <a href="http://en.wikipedia.org/wiki/Gibbon">gibbon</a> species form pair bonds and are highly monogamous. We could test the sperm production hypothesis by sequencing the Y-chromosome of two gibbon species and calculating the rate of evolution of a Y-chromosome in a monogamous species. .Although I'm happy to present the test of this idea I'm not going to line up to do it, those repetitive sections of DNA make sequencing Y-chromosome so hard that it took 13 years to do the human one and 8 to finish the chimp one.</p><p>
</p>
<hr width="66%">
<span class="Z3988" title="ctx_ver=Z39.88-2004&rft_val_fmt=info%3Aofi%2Ffmt%3Akev%3Amtx%3Ajournal&rft.jtitle=Nature&rft_id=info%3Adoi%2F10.1038%2Fnature08700&rfr_id=info%3Asid%2Fresearchblogging.org&rft.atitle=Chimpanzee+and+human+Y+chromosomes+are+remarkably+divergent+in+structure+and+gene+content&rft.issn=0028-0836&rft.date=2010&rft.volume=&rft.issue=&rft.spage=&rft.epage=&rft.artnum=http%3A%2F%2Fwww.nature.com%2Fdoifinder%2F10.1038%2Fnature08700&rft.au=Hughes%2C+J.&rft.au=Skaletsky%2C+H.&rft.au=Pyntikova%2C+T.&rft.au=Graves%2C+T.&rft.au=van+Daalen%2C+S.&rft.au=Minx%2C+P.&rft.au=Fulton%2C+R.&rft.au=McGrath%2C+S.&rft.au=Locke%2C+D.&rft.au=Friedman%2C+C.&rft.au=Trask%2C+B.&rft.au=Mardis%2C+E.&rft.au=Warren%2C+W.&rft.au=Repping%2C+S.&rft.au=Rozen%2C+S.&rft.au=Wilson%2C+R.&rft.au=Page%2C+D.&rfe_dat=bpr3.included=1;bpr3.tags=Biology%2CEvolutionary+Biology%2C+Genetics%2C+Creative+Commons">Hughes, J., Skaletsky, H., Pyntikova, T., Graves, T., van Daalen, S., Minx, P., Fulton, R., McGrath, S., Locke, D., Friedman, C., Trask, B., Mardis, E., Warren, W., Repping, S., Rozen, S., Wilson, R., & Page, D. (2010). Chimpanzee and human Y chromosomes are remarkably divergent in structure and gene content <span style="font-style: italic;">Nature</span> DOI: <a rev="review" href="http://dx.doi.org/10.1038/nature08700">10.1038/nature08700</a></span>David Winterhttp://www.blogger.com/profile/09704684760112027351noreply@blogger.com5tag:blogger.com,1999:blog-4718577088343779246.post-6884775898463907272009-12-31T16:12:00.005+13:002010-01-10T17:38:36.074+13:00The Origin of Species and the origin of species<p>
2009 was the double celebration for evolutionary biologists, In February we markerd the 200th anniversary of Charles Darwin's birth and in November we celberated the 150th anniversary of That Book's publication. Somehow I've managed to go the whole year without dedicating a post to Darwin's ideas about speciation. Which is odd because I've spent quite a lot of thinking about, talking about and even writing about Darwin this year. So here, with about seven hours of 2009 left are a few of my thougts on Darwin and speciation.
</p> <p>
Darwin's book was called <i>The Origin of Species</i> but I'm sure that most of the tributes you've read to Darwin and his book this year will have focused on how he proved evolution had happened and provided natural selection as the mechanism required to explain modern organisms in that framework - the fact and the theory of evolution . Missing among the descriptions of the events that shaped Darwin's thinking and the thousands of strands of evidence he wove to form his thesis will have been an answer to the question the title of the books seems to ask - where do new species come from. In fact, there is a prevailing view in evolutionary biology that for all his triumphs Darwin didn't quite understand species and as a result <i>The Origin</i> failed to provide a theory of speciatoin. I don't think it's quite that simple.</p><p>
To know what someone thinks about speciation you need to know what they think about species.</p>
<blockquote>
Practically, when a naturalist can unite two forms together by
others having intermediate characters, he treats the one as a
variety of the other, ranking the most common, but sometimes
the one first described, as the species, and the other as the
variety. But cases of great difficulty, which I will not here
enumerate, sometimes occur in deciding whether or not to rank
one form as a variety of another, even when they are closely
connected by intermediate links; nor will the commonly-assumed
hybrid nature of the intermediate links always remove the difficulty.
<i>The Origin</i>, p47
</blockquote>Darwin was the sort of person who could develop a world shattering theory, produce a body of data to support it then spent eight years looking at barnacles. Historians of science have spent a lot of ink trying to provide an explanation for "Darwin's delay". It may have been driven in part by an off-hand comment by his correspondent <a href="http://en.wikipedia.org/wiki/Joseph_Dalton_Hooker">Hooker</a> that only someone who has worked on the systematics of a group could hope to understand the nature of species or might just be a phenomenon all too familiar to modern systematists - a small project that grew out of control. Whatever the cause Darwin's barnacle obsession (on visiting a friend's house his son asked where his friends father "did his barnacles") clearly shaped the way he thought about species. In numerous letters of the time, especially to Hooker, he remarks on the great deal of variation he finds within barnacles of a given species and the great trouble he finds in using that variation to define the limits of species. Partly as a result of his eight years spent dissecting barnacles Darwin came to see the variation within a species as the of the same sort as the variation that exists between species and, importantly, the difference between two varieties of a given species and two distinct species as one of degree not of kind. At the risk of boiling Darwin's ideas down to the sort of diagram you might find in a powerpoint slide here's a pictorial representation.
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<div style="text-align: center;"><img src="http://img.photobucket.com/albums/v387/science_boy/concept.png" width="400px" />
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Darwin's species concept makes the difference between species and "well marked" varieties an arbritary one. He even goes so far as to call varieties within a species "incipient species" and link the difference he noted in his barnacles, in organisms and under domestication and in organisms in the wild with the differences that seperate species and even higher orders
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Hence I look at individual differences, though of small interest to the systematist, as of high importance for us, as being the first step towards such slight varieties as are barely thought worth recording in works on natural history. And I look at varieties which are in any degree more distinct and permanent, as steps leading to more strongly marked and more permanent varieties; and at these latter, as leading to sub-species, and to species.
<i>The Origin</i>, p51
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It's the fact that Darwin saw no fundamental difference between varieties and species that has lead many, notably<a href="http://en.wikipedia.org/wiki/Ernst_W._Mayr"> Ernst Mayr</a>, to conclude that he didn't understand species and that <i>The Origin</i> was not a speciation book. I read it quite differently. To me it seems Darwin saw the term 'species' as something a systematist could apply to a group of organisms sometime after a process he called divergence (which we would now call speciation) has started to form discontinuities between them. </p><p>
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The big question then is what is the process that drives the discontinuities that make for species? The clearest answer to question comes in Chapter 4 of <i>The Origin</i>. Here is one example of Darwin's ideas about the principle of divergence.
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It has been experimentally proved, that if a plot of ground be sown with one species of grass, and a similar plot be sown with several distinct genera of grasses, a greater number of plants and a greater weight of dry herbage can be raised in the latter than in the former case. The same has been found to hold good when one variety and several mixed varieties of wheat have been sown on equal spaces of ground. Hence, if any one species of grass were to go on varying, and the varieties were continually selected which differed from each other in the same manner, though in a very slight degree, as do the distinct species and genera of grasses, a greater number of individual plants of this species, including its modified descendants, would succeed in living on the same piece of ground. And we know that each species and each variety of grass is annually sowing almost countless seeds; and is thus striving, as it may be said, to the utmost to increase in number. Consequently, in the course of many thousand generations, the most distinct varieties of any one species of grass would have the best chance of succeeding and of increasing in numbers, and thus of supplanting the less distinct varieties; and varieties, when rendered very distinct from each other, take the rank of species.
<i>The Origin</i>, p88</blockquote>
In typically prescient fashion Darwin took a proto-ecological view to the experimental evidence that plots sown with multiple plant species where more productive than monocultures. If the the mixed-species plot is doing better than the monoculture it must mean each species is taken advantage of different resources in that plot - what we'd now call distinct ecological niches. But then he took it yet further. What would happen if we let that monoculutre grow on for several generations. We know from his barnacles and from all the examples he listed in the previous chapters of <i>The Origin </i>that variants will arise. A very few of those variants will be able to make use of some of the resources that were previously going untapped. Over many generations natural selection would act - the most specialised forms would produce more seeds and produce more variants while forms intermediate between the ancestral species, not being masters of either niche, would be out competed and driven to extinction. Let this process continue long enough and you'd get first new varietes and finally, since they are just very distinct varietes, new species. Darwin provides his own diagram (the only one in the book) to describe this process and its phylogenetic implications but that is, in my supervisor's words, "a rattly looking thing" so here's one from me.
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</div><div style="text-align: center;"><img src="http://img.photobucket.com/albums/v387/science_boy/theory.png" />
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</p><div style="text-align: left;">After the rediscovery of the Mendelian genetics and the forging of the <a href="http://www.talkorigins.org/faqs/modern-synthesis.html">modern synthesis</a> we've come to see that some of Darwin's ideas about species and speciation are too simplistic. The verbal argument presented above in which new species are formed solely by natural selection doesn't hold up to modern mathematical scrutiny - recombination between unlinked genes will break down the distinction between forms more quickly than selection can makes the difference. Modern models of speciation which come strong natural selection with assortative mating do produce new species and a number of emperical studies seem to suggest this has happened in the wild. </div><p></p></div><p>
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I find it very hard to marry the received wisdom that Darwin failed to understand the nature of species and provided on theory of speciation with the arguments Darwin presented in <i>The Origin</i>. When his species concept is viewed (<a href="http://theatavism.blogspot.com/2009/06/some-answers-on-speciation.html">as I think all such concepts should be)</a> as a diagnostic tool rather than an essential definition then his is as good as any other. His theory of speciation as presented doesn't hold up to our modern knowledge of genetics but the underlying process, selection driving ecological specialisation, forms one half of our modern models of speciation that <a href="http://evolution.berkeley.edu/evosite/evo101/VC1eSympatric.shtml">don't involve geographical isolation </a>and those that involve <a href="http://www.pnas.org/content/early/2009/11/12/0911761106">secondary contact between incipient species</a>. <div>
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</div>David Winterhttp://www.blogger.com/profile/09704684760112027351noreply@blogger.com2tag:blogger.com,1999:blog-4718577088343779246.post-19333428666780205872009-11-22T11:55:00.001+13:002009-11-22T13:34:30.692+13:00Sunday Spinelessness - millipede<p>I have three talks to present next week so today's edition of Sunday Spinelessness will be short and sharp. In fact, here's an animal I can't say very much about at all, it's err... a millipede:
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</p><div style="text-align: center;"><a href="http://www.flickr.com/photos/igor_nz/4123063086/" title="millipede by igor_nz, on Flickr"><img src="http://farm3.static.flickr.com/2631/4123063086_06b8d059b5.jpg" border="0" alt="millipede" height="375" width="500" /></a>
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For an invertebrate evangelist being able to identify an animal only as far as 'millipede' is sort of like a being a cheerleader for the cute and cuddly and identifying a fury creature as "definitely being some sort of mammal" - faintly depressing. It's only thanks to the arrangement of feet that I can even get that far - centipedes have one pair legs per segment while this guy, and all millipedes have two. Interestingly*, despite the Latin roots of their names no millipede has as many as a thousand legs and, because they always have an odd number of leg bearing segments, no centipede has exactly a hundred.
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Be sure to click on the image to see it in higher resolution.
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<span style="font-style: italic;">*for certain values of interesting...</span></p>David Winterhttp://www.blogger.com/profile/09704684760112027351noreply@blogger.com0tag:blogger.com,1999:blog-4718577088343779246.post-47237089465343613632009-11-15T17:30:00.004+13:002009-11-15T20:05:41.398+13:00Sunday Spinelessness - damselflies<p>
It's been a bit of a wintry Sunday here in Dunedin so I'll dedicate today's round of Sunday Spinelessness to a group of insects we should see a lot more of as summer takes hold, the Damselflies (<a href="http://tolweb.org/Odonata">Odonata</a>:Zygoptera).
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</p><div style="text-align: center;"><a href="http://www.flickr.com/photos/igor_nz/4105029290/" title="Xzealandcia by igor_nz, on Flickr"><img src="http://farm3.static.flickr.com/2634/4105029290_445a49a1a7.jpg" width="500" height="375" alt="Xzealandcia" /></a></div><div style="text-align: left;">
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That's <i>Xanthocnemis zealandica </i>which is sometimes called the "common redcoat damselfly." It's certainly common enough, visit a pond or wetland in summer and you'll see hundreds of them skimming across the water to lay their eggs or perched on blades of grass or on trees (despite having an insect's full compliment of six legs those limbs are purely for perching - odonates can't walk). </div><div style="text-align: left;">
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</div><div style="text-align: left;">You can probably tell just by looking at <i>Xanthocnemis </i>that damselflies are related to dragonflies, in fact the damsels and the dragons are two infra-orders in the medievaly themed order Odonata . You can tell a damselfly from a dragonfly thanks to the way they hold their wings - damselflies fold them up over their body when they land while dragonflies hold them open (kiwi naturalist Shelia Natusch describes this posture in a slightly morbid way: "wings extended, as though already pinned down on a collector's board") .</div><div style="text-align: left;">
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</div><div style="text-align: left;">Damselflies are expert hunters - adults take small insects on the wing and their nymphs are pretty impressive aquatic predators - some will even take small fish. I don't know that any of the New Zealand species are quite as aggressive as all that but you can see photos of the nymphs thanks to <a href="http://www.landcareresearch.co.nz/research/biosystematics/invertebrates/freshwater_invertsCD/cd_images.asp">Landcare Research</a> and <a href="http://www.waitakere.govt.nz/Abtcit/ei/EcoWtr/macroinv/xanthocnemis.asp">Waitakere City Council's website</a> (which includes a 'profile' written in the first person).</div><div style="text-align: left;">
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</p></div><div style="text-align: left;"> There are six species of damselfly described in New Zealand - three more <i>Xanthocnemis </i>species (each of which are rare and restricted to a small area) , <i>Austrolestes colensonis</i> (which is blue and almost as comon as <i>X. zealandica</i>) and the self-introduced <span style="font-style:italic;">Ischnura aurora. </span><span>Despite the lack of a red coat the next picture is likely another <i>X.</i> <i>zealandica </i>(it certainly isn't <i>Austrolestes </i>or <i>Ischnura </i>and as far as I can tel the other <i>Xanthocnemis </i>species aren't known from Dunedin.)</span></div><div style="text-align: center;">
</div><div style="text-align: center;"><a href="http://www.flickr.com/photos/igor_nz/4105029286/" title="damse1_2, on Flickr"><span class="Apple-style-span" style="color: rgb(0, 0, 0); -webkit-text-decorations-in-effect: none; "></span></a><a href="http://www.flickr.com/photos/igor_nz/4105029286/" title="damse1_2, on Flickr"><img src="http://farm3.static.flickr.com/2590/4105029286_7b8406cb09.jpg" width="500" height="375" alt="Damselfly perched on grass" /></a></div><p></p><p>
</p>David Winterhttp://www.blogger.com/profile/09704684760112027351noreply@blogger.com1