Hi, real world, again!

The Mammal has emerged from a thesis-induced supermassive black hole and a Christmas-induced food coma, only to find that in the month or so that she spent barely functional and buried in chapters covered in the supervisor’s dreaded Red Pen, things actually happened in the world outside. This, naturally, manifested in thousands of items feeling thoroughly neglected in RSS readers and email inboxes. (Jesus. How many times have I vowed never to neglect my RSS feed again? Oh well, it’s not like unemployment is such a busy occupation that I can’t deal with a measly two and a half thousand articles 😛 )

… earlier tonight, the paragraph here said I wasn’t doing a proper post yet, “just pointing out” a couple of the cooler things I’ve missed. Then somehow this thing morphed into a 1000+ word post that goes way beyond “pointing things out”. It’s almost like I’ve been itching to write something that isn’t my thesis. >_>

So the first cool thing I wanted to “point out” is the genome paper of the centipede Strigamia maritima, which is a rather nondescript little beast hiding under rocks on the coasts of Northwest Europe. This is the first sequenced genome of a myriapod – the last great class of arthropods to remain untouched by the genome sequencing craze after many genomes from insects, crustaceans and chelicerates (spiders, mites and co.).  The genome sequence itself has been available for years (yay!), but its “official” paper (Chipman et al., 2014) is just recently out.

Part of the appeal of Strigamia – and myriapods in general – is that they are considered evolutionarily conservative for an arthropod. In some respects, the genome analysis confirms this. Compared to its inferred common ancestor with us, Strigamia has lost fewer genes than insects, for example. Quite a lot of its genes are also linked together similarly to their equivalents in distantly related animals, indicating relatively little rearrangement in the last 600 million years or so. But this otherwise conservative genome also has at least one really unique feature.

Specifically, this centipede – which is blind – has not only lost every bit of DNA coding for known light-sensing proteins, but also all known genes specific to the circadian clock. In other animals, genes like clock and period mutually regulate one another in a way that makes the abundance of each gene product oscillate in a regular manner (this is about the simplest graphical representation I could find…). The clock runs on a roughly daily cycle all by itself, but it’s also connected to external light via the aforementioned light-sensing proteins, so we can constantly adjust our internal rhythms according to real day-night cycles.

There are many blind animals, and many that live underground or otherwise find day and night kind of irrelevant, but even these are often found to have a functioning circadian clock or keep some photoreceptor genes around. However, based on the genome data, our favourite centipede may be the first to have completely lost both. The authors of the genome paper hypothesise that this may be related to the length of evolutionary time the animals have spent without light. Things like mole rats are relatively recent “inventions”. However, the geophilomorph order of centipedes, to which Strigamia belongs, is quite old (its most likely sister group is known from the Carboniferous, so they’re probably at least that ancient). Living geophilomorphs are all blind, so chances are they’ve been that way for the last 300+ million years.

Nonetheless, the authors also note that geophilomorphs are still known to avoid light – the question now is how the hell they do it… And, of course, whether Strigamia has a clock is not known – only that it doesn’t have the clock we’re used to. We also have no idea at this point how old the gene losses actually are, since all the authors know is that one other centipede from a different group has perfectly good clock genes and opsins.

In comparison with fruit flies and other insects, the Strigamia genome also reveals some of the ways in which evolutionary cats can be skinned in multiple ways. There is an immune-related gene family we share with arthropods and other animals, called Dscam. The product of this gene is involved in pathogen recognition among other things, and in flies, Dscam genes are divided into roughly 100 chunks or exons, most of which are are found in clusters of variant copies. When the gene is transcribed, only one of these copies is used from each such cluster, so in practical terms the handful of fruit fly Dscam genes can encode tens of thousands of different proteins, enough to adapt to a lot of different pathogens.

A similar arrangement is seen in the closely related crustaceans, although with fewer potential alternative products. In other groups – the paper uses vertebrates, echinoderms, nematodes and molluscs for comparison – the Dscam family is pretty boring with at most one or two members and none of these duplicated exons and alternative splicing business. However, it looks like insects+crustaceans are not the only arthropods to come up with a lot of DSCAM proteins. Strigamia might also make lots of different ones (“only” hundreds in this case), but it achieved this by having dozens of copies of the whole gene instead of performing crazy editing feats on a small number of genes. Convergent evolution FTW!

Before I paraphrase the entire paper in my squeeful enthusiasm (no, seriously, I’ve not even mentioned the Hox genes, and the convergent evolution of chemoreceptors, and I think it’s best if I shut up now), let’s get to something else that I can’t not “point out” at length: a shiny new vetulicolian, and they say it’s related to sea squirts!

Vetulicolians really deserve a proper discussion, but in lieu of a spare week to read up on their messiness, for now, it’s enough to say that these early Cambrian animals have baffled palaeontologists since day one. Reconstructions of various types look like… a balloon with a fin? Inflated grubs without faces? I don’t know. Drawings below (Stanton F. Fink, Wikipedia) show an assortment of the beasts, plus Yunnanozoon, which may or may not have something to do with them. Here are some photos of their fossils, in case you wondered.

Vetulicolians from Wiki

They’re certainly difficult creatures to make sense of. Since their discovery, they’ve been called both arthropods and chordates, and you can’t get much farther than that with bilaterian animals (they’re kind of like the Nectocaris of old, come to think of it…).

The latest one was dug up from the Emu Bay Shale of Australia, the same place that yielded our first good look at anomalocaridid eyes. Its newest treasure has been named Nesonektris aldridgei by its taxonomic parents (García-Bellido et al., 2014), and it looks something like this (Diego García-Bellido’s reconstruction from the paper):

Garcia-Bellido_etal2014-nesonektris_recon

In other words, pretty typical vetulicolian “life but not as we know it”, at first glance. Its main interest lies in the bit labelled “nc” in the specimens shown below (from the same figure):

García-Bellido_etal2014-nesonektris_notochords

This chunky structure in the animal’s… tail or whatever is a notochord, the authors contend. Now, only one kind of animal has a notochord: a chordate. (Suspicious annelid muscle bundles notwithstanding. Oh yeah, I also wanted to post on Lauri et al. 2014. Oops?) So if this thing in the middle of Nesonektris’s tail is a notochord, then at the very least it is more closely related to chordates than anything else.

Why do they think it is one? Well, there are several long paragraphs devoted to just that, so here goes a summary:

1. It’s probably not the gut. A gut would be the other obvious ID, but it doesn’t fit very well in this case. Structures interpreted as guts in other vetulicolians – which sometimes contain stuff that may be half-digested food – (a) start in the front half of the body, where the mouth is, (b) constrict and expand and coil and generally look much floppier than this, (c) don’t look segmented, (d) sometimes occur alongside these tail rod-like thingies, so probably aren’t the same structure.

2. It positively resembles modern half-decayed notochords. The notochords of living chordates are long stacks of (muscular or fluid-filled) discs, which fall apart into big blocks as the animal decomposes after death. Here’s what remains of the notochord of a lamprey after two months for comparison (from Sansom et al. (2013)):

Sansom_etal2013-adult_lamprey_notochord_d63

This one isn’t as regular as the blockiness in the fossils, I think, but that could just be the vetulicolians not being quite as rotten.

There is, of course, a but(t). To be precise, there are also long paragraphs discussing why the structure might not be a notochord after all. It’s much thicker than anything currently interpreted as such in reasonably clear Cambrian chordates, for one thing. Moreover, it ends right where the animal does, in a little notch that looks like a good old-fashioned arsehole. By the way, the paper notes, vetulicolian tails in general don’t go beyond their anuses by any reasonable interpretation of the anus, and a tail behind the anus is kind of a defining feature of chordates, though this study cites a book from the 1970s claiming that sea squirt larvae have a vestigial bit of proto-gut going all the way to the tip of the tail. (I suspect that claim could use the application of some modern cell labelling techniques, but I’ve not actually seen the book…)

… and there is a phylogenetic analysis, in which, if you interpret vetulicolians as deuterostomes (which impacts how you score their various features), they come out specifically as squirt relatives whether or not you count the notochord. I’m never sure how much stock to put in a phylogenetic analysis based on a few bits of anatomy gleaned from highly contentious fossils, but at least we can say that there are other things – like a hefty cuticle – beyond that notochord-or-not linking vetulicolians to a specific group of chordates.

Having reached the end, I don’t feel like this paper solved anything. Nice fossils either way 🙂

And with that, I’m off. Maybe next time I’ll write something that manages to be about the same thing throughout. I’ve been thinking that I should try to do more posts about broader topics rather than one or two papers (like the ones I wrote about ocean acidification or homology versus developmental genetics), but I’ve yet to see whether I’ll have the willpower to handle the necessary reading. I’m remarkably lazy for someone who wants to know everything 😀

(Aside: holy crap, did I ALSO miss a fucking Nature paper about calcisponges’ honest to god ParaHox genes? Oh my god, oh my GOD!!! *sigh* This is also a piece of incredibly exciting information I’ve known for years, and I miss it when it actually comes out in a journal bloody everyone reads. You can tell I’ve been off-planet!)

References:

Chipman AD et al. (2014) The first myriapod genome sequence reveals conservative arthropod gene content and genome organisation in the centipede Strigamia maritima. PLoS Biology 12:e1002005

García-Bellido DC et al. (2014) A new vetulicolian from Australia and its bearing on the chordate affinities of an enigmatic Cambrian group. BMC Evolutionary Biology 14:214

Lauri A et al. (2014) Development of the annelid axochord: insights into notochord evolution. Science 345:1365-1368

Sansom RS et al. (2013) Atlas of vertebrate decay: a visual and taphonomic guide to fossil interpretation. Palaeontology 56:457-474

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Parasitic sex cells wtf yay?

I’m reading a review about asexual reproduction in colonial sea squirts (Brown and Swalla, 2012). This isn’t really the place I expected to stumble on something that made me giggle and whisper “holy fuck” at the same time, but I was totally wrong. Apparently, some squirt colonies can fuse and create a single “chimaera” colony. And then one member’s germ cells can take over the other’s gonads. Because these squirts keep some germ cells in their blood, so they can go wherever the hell they want in the whole colony. Like that poor sod’s testicles.

It seems everything remotely related to sex in the animal kingdom is at least a little bit kinky.

Also, sea squirts are weird, and this is Captain Obvious speaking.

(Must resist temptation to immediately dive into PubMed for articles on germline parasitism. I have a ton of reading to do that’s actually relevant to my work…)

(P.S.: I wonder if tagging this post “sex” will trigger a giant traffic spike. Consider this an experiment!)

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Reference:

Brown FD, Swalla BJ (2012) Evolution and development of budding by stem cells: ascidian coloniality as a case study. Developmental Biology 369:151-162

Virtual squirtlet

Sea squirts are not the most endearing creatures, but they are pretty interesting in their own way. Although their adults are basically cellulose-covered bags of jelly, their larvae and their genomes reveal their dirty secret: they are actually close (probably the closest) relatives of vertebrates. Squirts and their kin – collectively known as tunicates – also have some of the fastest-evolving, most crazily scrambled genomes among animals (e.g. Denoeud et al. 2010).

(Say hi to your long-lost cousins! A whole crowd of grown-up Ciona from Wikipedia)

To be fair, not all of them are as bland and ugly as Ciona species. Some of them are actually quite gorgeous with all the colourful extravagance you’d expect from a tropical marine invertebrate (below is one example from Wikipedia’s squirt entry).

But, anyway, I got a bit carried away there. In truth, I just wanted to squee about a new virtual squirt embryo (Nakamura et al., 2012). Because 3D reconstructions of animals down to single-cell resolution are pretty damn cool.

Unlike the adults, baby squirts actually look a proper chordate, with a plump little body and a long tail supported by a good old notochord. They float in their little eggs for a while, developing their tails and simple sensory systems, and then they swim around for a few days before settling and transforming into those unappealing jellybags for a life of filter-feeding and spawning. (Below: the tadpole larva of the colonial squirt Botryllus schlosseri by Richard Grosberg via this site)

Because squirts are so close to vertebrates, and some of them (like Ciona) are relatively easy to breed and grow up in the lab, they’re among the favourite model organisms of evo-devo researchers. That means some people are bound to put serious effort into community resources about them. The good folks at Keio University in Japan have been building this amazing resource for years, where they painstakingly document the development of Ciona intestinalis from fertilised egg all the way to jellybaghood using photographs, microscopic images and 3D reconstructions from optical sections made with a confocal microscope. The virtual embryo is the latest addition to this project. It represents a stage where the embryo is growing its tail, and it is packaged into an interactive PDF with all sorts of annotations on cell types and stuff (that my PDF viewer can’t handle :(). I’m not much into sea squirts, but an interactive embryo you can manipulate and examine cell by cell and use as a free reference to interpret your own experimental results? That’s seriously awesome.

(Almost as cool as the digital zebrafish embryo movies)

(Above: A, an example of the confocal images used to build the virtual squirt, with a few views inside the 3D model: B, rear view of the “skinned” virtual embryo, C, side view of same, and D, virtual cross-section of the tail. Tissues like muscle, notochord and nerve tube are colour-coded and labelled. From Nakamura et al. [2012])

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References:

Denoeud F et al. (2010) Plasticity of animal genome architecture unmasked by rapid evolution of a pelagic tunicate. Science 330:1381-1385

Nakamura MJ et al. (2012) Three-dimensional anatomy of the Ciona intestinalis tailbud embryo at single-cell resolution. Developmental Biology in press, available online 27/09/2012, doi: 10.1016/j.ydbio.2012.09.007