Deeper Dive on the PhyloPic T-shirt

Just to review:

•  PhyloPic is a website featuring freely-reusable silhouettes of organisms. Anybody may submit images under a Creative Commons license.
• I am attempting to raise funds to host PhyloPic for the next two years by selling a PhyloPic T-shirt, depicting the past half-billion years of our evolutionary lineage with free silhouettes.

We've come a long way.

In this post I'll go into more detail about what, exactly, is on the shirt, starting with the final silhouette and going back in time. In each entry, the taxonomic name links to a page for the image, with artist and license information. Some terminology first: "concestor" means "most recent shared ancestor", and "stem-X" means "not X, but more closely related to X than to anything else alive".

The final silhouette is a modern human, Homo sapiens sapiens, specifically a Melanesian woman. Melanesians and other Oceanians represent one of the furthest migrations of humanity from our original geographical range.

Immediately behind her is another Homo sapiens sapiens, this one a Subsaharan African man. Subsaharan Africa is the wellspring of modern humanity. (This isn't meant to imply an ancestor–descendant relationship between the two figures; they're just coexisting members of the same subspecies.)

Half a Billion Years in the Making: The PhyloPic T-shirt

Yes, now you can wear PhyloPic.

The PhyloPic T-shirt

PhyloPic's silhouettes are free, but hosting the site costs money. With this shirt, I'm trying to raise enough to cover basic expenses. If 100 of you buy a shirt, you will cover PhyloPic's hosting for the next two years.

The design uses PhyloPic silhouettes to depict the evolutionary lineage of humanity, starting with the earliest bilaterian animals. All of the silhouettes are public domain, or available under a Creative Commons Attribution or Attibution-ShareAlike license (which means the design itself is under a Creative Commons Attibution-ShareAlike license). The works of ten artists are featured:

• Dmitry Bogdanov
• Steven Coombs
• Ghedoghedo
• T. Michael Keesey (myself)
• Gareth Monger
• William G. Scott (RNA enzyme on the back)
• Smokeybjb
• Brian Swartz
• Nobu Tamura
• Mateus Zica

The shirt is only available through March 15. As of this morning, 25 shirts have been purchased, meaning that we are exactly one quarter of the way to the goal. So help PhyloPic out, and get a great T-shirt! Or, if you can't*, at least help spread the word.

Do you have PhyloPic's back?

* Apologies, but shipping is only available in the U.S., Canada, and Army or Fleet Post Offices. But if this campaign does well, I'll certainly look into a more global option for future shirts. (Yes, plural. Why should Homo sapiens get all the fun? PhyloPic has good coverage of many other lineages.)

"Year of Macrauchenia": Third and Final "All Your Yesterdays" Entry

I made a last-minute entry for the All Your Yesterdays contest:

Year of Macrauchenia

Macrauchenia was the greatest and last of the litopterns, a clade of stem-euungulates. This bizarre Pleistocene South American herbivore is often described as having the body of a llama and the head of a tapir. However, the body is only superficially llama-like (but with gigantic elbows) and the head is not at all tapir-like. (If any part of it resembles tapirs, it's the feet.) In fact, the skull isn't like that of any living terrestrial mammal. It has extremely dorsal nares, like trunked animals and cetaceans, but it lacks any place for trunk muscles to attach.

But there is a possible analogue — another group of terrestrial herbivores with extremely dorsal nares — and they even had long necks, too! I refer, of course, to sauropod dinosaurs. Unfortunately, none are extant for comparison, but recent work has shown that, despite the dorsal placement of the nares in the skull, the external nostrils were still placed rostrally, close to the mouth, thanks to fleshy tubes. I've restored Macrauchenia similarly.

This mandala depicts the life of Macrauchenia across the seasons. At bottom, a lone Macrauchenia wanders the frozen highlands in relative comfort, having grown a shaggy winter coat. Its fleshy nostril tubes serve to warm the air before it enters the body. At right, spring is in effect — a bull courts a cow by inflating his nostril tubes, similar to a hooded seal. At top, a young calf frolics under his mother's watchful eye — his green color comes from the algae living in his fur (similar to the camouflage of those other South American indigenes, the sloths). This extra measure of color accuracy is necessary because, unlike today's ungulates, Macrauchenia must contend with predators that have excellent color vision: phorusrhacids. At left, a wary bull faces off against a Smilodon, an invading predator from the north. (It is restored after linsangs, the extant sister group to felids, instead of the felids themselves, since it is, properly, a stem-felid, not a true felid.) Macrauchenia will survive this great faunal interchange, but not for long — another invader from the north, a large primate, will be the end of it, and hence all litopterns.

Human Clades: A Look at a Complex Phylogeny

Most methods of phylogenetic analysis deal with simple trees. In these phylogenies, every taxonomic unit has a single direct ancestor (or "parent"). But we know that phylogeny is often more complex than this. Our own species is an excellent example—while we are all primarily descended from one population in Africa, different peoples around the globe have inherited smaller percentages of ancestry from preexisting populations.

A new study by Reich & al. looks in some detail at peoples who have inherited DNA from the Denisovans, a fossil group known from Siberia. Ancient DNA has been retrieved from these fossils, although unfortunately the fossils are otherwise too scant to tell us much about what Denisovans looked like (other than "humanlike").

Reich & al. posit a complex phylogeny wherein populations are often descended from multiple ancestral populations. Lets take a look at the clades posited in this study.

Operational Taxonomic Units

Reich & al. used the following nine populations, seven extant and two extinct, as operational taxonomic units.

Yoruba.—An ethnicity from West Africa (Nigeria, Benin, Ghana, etc.)
(Photo by Marc Trip.)

Han.—The most populous Chinese ethnicity.
(Photo by Brian Yap.)

Mamanwa.—One of the "Lumad" ("indigenous") ethnicities of the southern Philippines.
(Photo by Richard Parker.)

Jehai.—One of the Orang Asli ("original people") groups of Malaysia.
Note: this photo is of a woman from a different Orang Asli tribe, the Batik.
(Photo by Wazari Wazir.)

Onge.—A group of Andaman Islanders, from the Bay of Bengal.
(Photo from The Andamanese, by George Weber.)

Australians.—The indigenous ("aboriginal") peoples of Australia.
(Photo by Rusty Stewart.)

Papuans.—The indigenous peoples of the New Guinean highlands.
(Photo owned by the Center for International Forestry Research.)

Neandertals.—An extinct group of robust near-human peoples from West Eurasia.
(Photo by myself, of a sculpture by John Gurche.)

Denisovans.—An extinct group of near-human peoples known from Siberia but thought to have had a wider range.
Note: The photo is of a sculpture of Homo heidelbergensis, thought to be the common ancestor of humans, Neandertals, and Denisovans. Denisovans may not have looked exactly like this.
(Photo by myself, of a sculpture by John Gurche.)

Phylogeny

Reich & al. postulated the simplest phylogeny that could possibly explain their data. (Note that the actuality is likely more complex than this, but it's a good starting point.) More recent groups are to the right, and the thickness of the lines indicates the percentage of DNA contributed from population to population.

My diagram, not theirs. Any inaccuracies are my own.
Free for reuse under Public Domain.

I've added a line for the Denisovans' mitochondrial (motherline) ancestor, even though it's not part of the paper's phylogeny. More on that as we start looking through the various clades.


For looking at the clades I'll use a different diagram that does not reflect percentage of ancestry, but simply shows direct descent as unweighted arcs connecting parent and child taxonomic units.

Phylogeny of human and near-human populations according to Reich & al. 2011.
Created using Names on Nodes.
Free for reuse under Public Domain.

What is a human?

Find the human! Pretty easy, right? RIGHT??

It is obvious what is "human" and what is not if we just look at living organisms. There's a clear gap between us and our closest living relatives, the chimpanzees. No danger of mistaking one for the other.

But this clarity vanishes as soon as we look at the fossil record. There's a gradient of forms between us and things that are not clearly closer to us or chimpanzees (Ardipithecus, Orrorin, Sahelanthropus). Which ones are "human" and which are not? Is Praeanthropus afarensis human? What about Homo habilis? Homo ergaster? Neandertals? Homo sapiens idaltu?

Find the human! Or is there more than one?
Or are they all human?

This issue crops up for all kinds of taxa. Much time has been spent arguing what is and is not e.g., avian, or mammalian. The issue is more common within vertebrates than many other taxa, since vertebrates have an especially good and well-studied fossil record. But it applies, in theory or practice, to every extant taxon.


I subscribe to the school of thought that names born from neontology (the study of extant organisms) are best restricted to the crown group (that is, to the living forms, their final common ancestor, and all descendants of that ancestor). Arguments for restricting common names to crown groups were first laid out by de Queiroz and Gauthier (1992). The primary reason for doing this is that it prevents unjustified inferences about stem groups (that is, the extinct taxa which are not part of the crown group, but are closer to it than to anything else extant). For example, we currently have no way of knowing whether the statement, "Within all mammalian species, mothers produce milk," is true if we include things like Docodon as mammals (or, as a few have done, even earlier things like Dimetrodon). However, if we restrict Mammalia to the last common ancestor of monotremes and therians (marsupials and placentals) and all descendants of that ancestor, then the statement unambiguously holds.


This system also gives us a very easy way to refer to any stem group: just add the prefix "stem-". Some examples:

• stem-avians: Pterodactylus, Iguanodon, Diplodocus, Eoraptor, Coelophysis, Tyrannosaurus, Oviraptor, Velociraptor, Archaeopteryx, Ichthyornis
• stem-mammals: Casea, Dimetrodon, Moschops, Cynognathus, Docodon
• stem-whales: Indohyus, Ambulocetus, Pakicetus, Basilosaurus, Dorudon
• stem-humans: Ardipithecus(?), Praeanthropus, Australopithecus, Homo habilis, Homo ergaster

stem-humans

This is a nice, neat system. However, for humans, it gets a little sloppy the closer we get to the crown group.

For a long time, there was a debate in paleoanthropology as to how our species originated. We are distributed across the globe, so it's not immediately obvious where we are from. As the hominin fossil record gradually came to light during the 20th century, it became clearer that the earliest roots of the human total group were in Africa, since that's where the oldest remains are found. Everything before two million years ago is African, and only after that time period do we start to see remains in Eurasia, all of them belonging to the genus Homo. Remains in Australia and America don't occur until very late, and only modern humans appear in those regions.

But this leaves open the question of our own species' origin. Homo had spread all over the Old World by the time modern humans appeared, so we could have come from anywhere in Africa or Eurasia. Two major hypotheses were formed. The Out of Africa Hypothesis suggested that the ancestors of humans originated in Africa and then spread out over the globe, displacing all other populations of Homo: the Neandertals in West Eurasia, Peking Man in Asia, Java Man in Malaya, etc. The Multiregional Hypothesis, on the other hand, suggested that modern human races evolved more or less in their current areas: Negroids were descended from Rhodesian Man, Caucasoids from Neandertal Man, and Mongoloids from Peking Man.

These hypotheses competed with each other until the advent of genetic analysis. When scientists were finally able to study the mitochondrial genome, which is copied from mother to child, they found that all living humans shared a relatively recent matrilineal ancestor, much more recent than the splits between Rhodesian, Neandertal, and Peking fossils. Furthermore, the matrilineal family tree strongly points to an ancestor in Africa, where the most divergence is found. Study of the Y chromosome, which is copied from father to son, indicated an even more recent patrilineal ancestor, also African. The case seemed closed. Out of Africa had won.

The case seemed further bolstered when the Neandertal mitochondrial genome was recovered. It revealed a signature which clearly placed it outside the modern human group (Teschler-Nicola & al. 2006). Earlier this year, mitochondrial DNA was also retrieved from an indeterminate fossil from Denisova, Siberia, indicating that it represented a matrilineage even further out, preceding the human-Neandertal split (Krause & al. 2010).

This would give us a pretty nice, clean series of splits. And it would mean that Neandertals, Denisovans, etc. are stem-humans.

But there is more to ancestry than just the matrilineage and the patrilineage. Most of our ancestral lineages include members of both sexes (think of your mother's father and your father's mother). The matrilineage and patrilineage are the only ones that can be studied with clarity, since all other chromosomes undergo a shuffling process. But those other lineages exist nonetheless.

Only very recently has evidence come to light which challenges Out of Africa, at least in its strong form. Earlier this year, a study suggested that all humans except for Sub-Saharan Africans have inherited 1–4% of their DNA from Neandertal ancestors (Green & al. 2010). And just yesterday, a new analysis of Denisovan nuclear DNA showed that Melanesians have inherited 4–6% of their DNA from Denisovans. This nuclear DNA seems to originate from an ancestor close to the human-Neandertal split, but somewhat on the Neandertal side.

Long story short, the picture has gotten a lot more complicated. It's no longer, "Out of Africa, yes, Multiregional, no." Now it's, "Out of Africa, mostly; Multiregional, somewhat."

So what does this mean for the term "human"? Are Neandertals and Denisovans human? After all, they seem to be ancestral to some, but not all, modern human populations.

Well, they can only belong to the crown clade if they are the final common ancestor of all living humans, or descended from it. Neither of these criteria appear to hold. So, for now, I would still say that they are not human, only very close to human. (Note that this does not mean that people descended, in part, from Neandertals and/or Denisovans are somehow "less human" than those with pure African ancestry. The African ancestors are also not humans but stem-humans under this usage. This usage is discrete; you're either human or you aren't.)

Still, at this level of resolution, we start to see a problem with the crown clade usage. What is the final common ancestor? Many would assume it to be the last-occurring common ancestor, but this is problematic, and not just because that ancestor probably lived within recorded history (making, e.g., the Sumerians inhuman!). When I say "final" I'm really referring to something a bit more complex—the maximal members of a predecessor union. (More discussion here.) But determining what that is, exactly, requires better datasets than we have.

I still think it's a good convention, and if its application is a bit vague, so be it—our knowledge is a bit vague. For now I would say that humans are a clade of large, gracile hominins with high-vaulted crania that emerged roughly 150,000 years ago in Africa, and then spread out. They are descended from not one but at least three major populations of stem-human. One of these, the African population (idaltu, helmei, etc.), forms the majority of the ancestry, up to 100% in some populations. The others, Neandertals and Denisovans, only form a small part of the ancestry of some humans.

I feel this convention is useful because it prevent unjustified inferences. For example, we know that all living human populations have languages with highly complex grammar. We really don't know whether Neandertals and Denisovans had such languages, or whether the immediate African predecessors of humans did, for that matter. So it's good to be able to categorize them as stem-humans, because it reminds us that we don't have as much data available on them as we do for the crown group. We have to be more clever in figuring these things out.

And if we ever cloned a Neandertal? Well, ask me again once that happens.

References

• de Queiroz & Gauthier (1992). Phylogenetic taxonomy. Annual Review of Ecology and Systematics 23:449–480. [PDF]
• Green & al. (2010). A draft sequence of the Neandertal genome. Science 328:710–722. doi:10.1126/science.1188021
• Krause & al. (2010). The complete mitochondrial DNA genome of an unknown hominin from southern Siberia. Nature 464(7290):894–897. doi:10.1038/nature08976
• Reich & al. (2010). Genetic history of an archaic hominin group from Denisova Cave in Siberia. Nature 468:1053–1060 doi:10.1038/nature09710
• Teschler-Nicola & al. (2006). No evidence of Neandertal mtDNA contribution to early modern humans. Pages 491–503 in Early Modern Humans at the Moravian Gate. Springer Vienna.  doi:10.1007/978-3-211-49294-9_17

Viewing Phylogenies at Different Graph Resolution

Although I've been primarily reining in features on the next version of Names on Nodes, there was a new feature I couldn't resist adding. I think it's coming along pretty well.

A common problem with working with phylogenies is that many of them are gigantic, far too big to view all at once. As an example, consider Figure 1 from Beck et al. (2006). It models a hypothesis about placental mammal phylogeny, at an arbitrary resolution ("family-level"). Here's how the current version of Names on Nodes renders it:

When you look at it "zoomed out", it's almost impossible to know what's going on. When you look at it full size, you can see various local areas, but you lose a sense of what's going on with the larger image. Note that I've highlighted our own species' twig on the tree (Hominidae, the great ape clade) in yellow.

Earlier I used the term "resolution" to refer to the size of the graph's nodes. We can refer to a graph with very small nodes (e.g., each node representing an individual organism) as being "fine" and a graph with very large nodes (e.g., "class-level") as being "coarse". Thinking about the problem from this angle, I had the idea to create a control for coarsening or refining the viewed graph.

I implemented a simple graph-coarsening algorithm*, and then created an algorithm for picking the best name for the new, coarser graph's nodes. And here is the phylogeny at near-maximum coarseness:

This is placental phylogeny boiled down to its basics: rodents, laurasiatheres, and a bunch of other junk (including us). The node labelled "Placentalia*" contains the placental ancestor but not all descendants—it lacks an unnamed clade included most non-afrothere placentals. The unnamed greenish node includes all members of that unnamed clade except for rodents and laurasiatheres. (This happens to include Hominidae, which is why it has that greenish color.)

Let's refine it one step:

We're starting to get a better idea of the hypothesis. Finer:

Now we can see the basal split between afrotheres and other placentals, as well as developing complexity in Rodentia and Laurasiatheria. Finer:

Getting a little bit on the big side, now, but we can see more details. There are a lot of unnamed clades within Hystricoidea and Chiroptera—we can see that those clades are diverse, although we can't see details. Finer:

This has about 2/5 as many nodes as the base graph. It's a bit large, but still much easier to view than the base graph. Many important details are visible (e.g., the platyrrhine-catarrhine split), while others are just suggested (e.g., lots of diversity in Caviomorpha).

Obviously this works best if lots of clades have been named. I think it'll be a useful for boiling a phylogeny down to an appropriate level: coarser for quick overviews, finer for in-depth discussion.

* Basic summary of the coarsening algorithm:

1. Look through all nodes that have children, and find the ones whose children are all terminal (sinks).
2. Merge each of those nodes with their children to create a "supernode".
3. Merge all overlapping supernodes. (This is important for graphs where nodes may have multiple ancestors, although it doesn't come into play in this example.)
4. Remove the supernodes from the graph and repeat from step 1. Keep going until no nodes are left.
5. Add the supernodes to a new graph. A supernode is ancestral to another supernode if any of its subnodes are ancestral to any of the other supernode's subnodes.

Names on Nodes: MathML Definitions (Version 1.1)

After posting Version 1.0 earlier this week, I had a revelation: the cladogen functions are completely unnecessary, and everything would work a lot nicer if I just tossed them. I also realized that there really was no reason I couldn't include the various relations (precedence, immediate precedence, proper precedence, etc.), just in case anyone wanted to do some seriously non-standard definitions. After some significant revisions, I present Version 1.1.

Some examples of the updated notation, using humans (Homo sapiens), platypuses (Ornithorhynchus anatinus), and Dimetrodon grandis, a stem-mammal:

Union. Homo sapiens ∪ Ornithorhynchus anatinus = all humans and all platypuses (polyphyletic taxon, also monothetic)

Exclusive Predecessors. Homo sapiens ← Ornithorhynchus anatinus = humans and all of their ancestors, except for the ancestors shared with platypuses (lineage)

Synapomorphic Predecessors. "milk glands" @ Homo sapiens = humans and all human ancestors to possess milk glands synapomorphic with those in humans (lineage)

Node-Based Clade. Clade(Homo sapiens ∪ Ornithorhynchus anatinus) = Mammalia

Branch-Based Clade (simple). Clade(Homo sapiens ← Ornithorhynchus anatinus) = "Pan-Theria"

Branch-Based Clade (multiple external specifiers). Clade(Homo sapiens ← Ornithorhynchus anatinus ∪ Dimetrodon grandis) = "Pan-Theria"

Branch-Based Clade (multiple internal specifiers). Clade(Homo sapiens ∪ Ornithorhynchus anatinus ← Dimetrodon grandis) = (unnamed clade comprised mostly of Therapsida)

Null Branch-Based Definition (multiple internal specifiers). Clade(Homo sapiens ∪ Dimetrodon grandis ← Ornithorhynchus anatinus) = ∅

Apomorphy-Based Clade. Clade("milk glands" @ Homo sapiens) = "Apo-Mammalia"

Node-Modified Crown Clade. Crown(Homo sapiens ∪ Dimetrodon grandis, "extant as of or after 2010") = Mammalia

Branch-Modified Crown Clade. Crown(Homo sapiens ← Ornithorhynchus anatinus, "extant as of or after 2010") = Theria

Apomorphy-Modified Crown Clade. Crown("milk glands" @ Homo sapiens, "extant as of or after 2010") = Mammalia

Total Clade. Total(Mammalia, "extant as of or after 2010") = Synapsida (or "Pan-Mammalia")

Image showing a node-based clade (Mammalia) under a given phylogenetic hypothesis. Click to enlarge. More here.

"The Case for Human Evolution" - Illustrations

I have been working on an essay entitled The Case for Human Evolution for a while. I've just posted some illustrations I've been working on:

The Case for Human Evolution (Flickr Set)

Enjoy!

Human-Chimpanzee Systematics

I've been working on a couple of projects to do with stem-humans. Naturally, these efforts necessitate creating a working phylogeny. I thought I'd post what I more or less have so far. I haven't done any rigorous work here; I'm just trying to piece things together from various publications.

This is a phylogeny of all known species within Clade(Homo sapiens Linnaeus 1758 ← Troglodytes gorilla Savage vide Savage & Wyman 1847), including some unnamed, fragmentary species that can only be differentiated from other species by location and/or time. (Note: Sahelanthropus tchadensis Brunet & al. 2002 is excluded because it doesn't seem to be clear that it does fall within this clade.) I've included links for all citations with permanent identifiers, when available, or popups with fuller information, when not. The phylogeny is interspersed with a rank-based taxonomy. (Unfortunately, there are no published phylogeny-based names to apply here.) Outlined circles indicate that the species may be ancestral to what are shown as sister groups. Species names are listed with their original prenomina (genera), regardless of current placement. I've added a note when the listed species is the type of its prenominal genus or another genus.

• • ?Orrorin tugenensis Senut & al. 2001 [typus]
  • ≅ Tribus Hominini Gray 1825
    • Ardipithecus kadabba Haile-Selassie 2001
    • ≅ Genus Pan Oken 1816
      • Pan sp. innom. McBrearty & Jablonski 2005
      • Pan paniscus Schwarz 1929
      • Simia troglodytes Blumenbach 1776 [typus Pan]
    • ≅ Subtribus Hominina Gray 1825
      • Australopithecus ramidus White & al. 1994 [typus Ardipithecus]
      • • Australopithecus anamensis Leakey & al. 1995 (?= praegens)
        • Homo praegens Ferguson 1989
        • • Australopithecus afarensis Johanson & al. 1978 [typus Praeanthropus]
          • Australopithecus bahrelghazali Brunet & al. 1995 (?= afarensis)
          • Australopithecus garhi Asfaw & al. 1999
          • Kenyanthropus platyops Leakey & al. 2001 [typus] (?= afarensis)
          • ≅ Genus Australopithecus Dart 1925
            • Australopithecus aethiopicus Olson 1985
            • Australopithecus africanus Dart 1925 [typus]
            • Zinjanthropus boisei Leakey 1959 [typus]
            • Australopithecus robustus Broom 1938 [typus Paranthropus]
          • ≅ Genus Homo Linnaeus 1758
            • Homo sp. innom. Kimbel & al. 1996
            • • Homo habilis Leakey & al. 1965
              • Homo rudolfensis Alexeev 1986
              • ≅ Subgenus Homo (Homo) Linnaeus 1758
                • Anthropopithecus erectus Dubois 1892 [typus]
                • Homo ergaster Groves & Mazák 1975
                • ?Homo floresiensis Brown & al. 2004
                • Homo georgicus Vekua & al. 2002
                • ≅ Superspecies Homo (sapiens) Linnaeus 1758
                  • Homo antecessor Bermúdez de Castro & al. 1997
                  • Homo cepranensis Mallegni & al. 2003 (?= antecessor)
                  • • Homo heidelbergensis Schoetensack 1908
                    • Homo neanderthalensis King 1864
                    • • Homo rhodesiensis Woodward 1921 (?= heidelbergensis)
                      • Homo sapiens Linnaeus 1758 [typus]

'Nother Toolshop Animatic: The Head Map

I created a sort of "mashup" of the previous two and added a temporary music track. (The ultimate version will have something different.) Click on the thumbnail (might take a moment to load):


Still clunky, but I'm just fleshing out the ideas at this point. Enjoy!

March of Man: The Toolshop

My somewhat ambitious web app, March of Man, has not been proving too successful. The idea behind the project is to illustrate human and chimpanzee evolution using hundreds of figures. The web app includes tools for submitting images and generating collages. But there are only a couple dozen images right now. At this rate, the project will be completed by the time I am an old man. Time for a new approach!

I'm going to leave the site up as is, but I am also going to be working on a CG animation. I've made a new area of the website called "The Toolshop" where I'll be posting progress. Here are the first two mockups, using vector animation (click on the image to see the animation):

Human/chimpanzee evolution depicted as streams of bubbling heads.

The ranges of various taxa over time.

Enjoy!

Extinct or Extant?

It's pretty easy to tell whether something's alive, right? You might have to jab it with a stick a couple of times to make sure (assuming it's an animal), but generally it's not too hard. So you'd think.

The International Union for Conservation of Nature is devoted to the preservation of life's diversity, so, naturally, it has a big stake in this question. When should we expend energy to try to save a critically endangered species, and when should we throw in the towel? Their Red List Guidelines say this about extinction:

Extinction is defined as population size reaching zero.

That made me laugh when I first read it. Really? You don't say! But I read on, and it became clear that there was much more to this seemingly simple definition:

Population size is the number of all individuals of the taxon (not only mature individuals). In some cases, extinction can be defined as population size reaching a number larger than zero. For example, if only females are modelled, it is prudent to define extinction as one female (instead of zero) remaining in the population. More generally, an extinction threshold greater than zero is justified if factors that were not incorporated into the analysis due to a lack of information (for example, Allee effects, sex structure, genetics, or social interactions) make the predictions of the analysis at low population sizes unreliable.

For Criterion E, extinction risk must be calculated for up to 3 different time periods:

• 10 years or 3 generations, whichever is longer (up to a maximum of 100 years)
• 20 years or 5 generations, whichever is longer (up to a maximum of 100 years)
• 100 years

For a taxon with a generation length of 34 years or longer, only one assessment for 100 years) is needed. For a taxon with a generation length of 20 to 33 years, two assessments (for 3 generations and 100 years) are needed. For a taxon with a generation length less than 20 years, all three assessments are needed.

This is just a small sample of what the IUCN has to say on the subject. So much for just poking things with sticks.

It would be nice if we could simply categorize species as extinct or extant, but it's not always easy. A species may be extant one day and extinct the next. And we may not realize this until years or even decades later. Or, we may think a species extinct only to have individuals turn up again, as may have happened with Campephilus principalis, the ivory-billed woodpecker, a few years ago (Hill et al. 2006).

This question is important not only for conservation efforts, but also for nomenclature. In fact, in some ways, the issues become even thornier for nomenclature. To see why this is so, let's look at the phylogenies of two mammalian taxa.

Whales

Whales, or cetaceans, are related to even-toed ungulates, or artiodactyls. (In fact, they may even be artiodactyls, but that's a discussion that I'm going to try to avoid as much as possible right now.) The chart below shows a sampling of fossil and living species, giving a very rough and highly abridged picture of cetacean evolution:

Time goes from left to right. Arrows point from ancestor species to descendant species. Silhouettes are not to scale.

Cetacea is what we call a "crown group". A crown group is a special type of clade, a clade being an ancestor and all of its descendants. A crown group is the final common ancestor of certain extant organisms, and all descendants of that ancestor. Note that this doesn't mean that all members of a crown group are extant; for example, Aetiocetus, a proto-baleen whale known from fossils, is long extinct. But it is descended from the final common ancestor of living baleen whales (Mysticeti) and living toothed whales (Odontoceti), so it is still a member of the crown group Cetacea.

The cetacean "total group", informally termed "pan-Cetacea", includes everything sharing closer ancestry with cetaceans than with any other extant organisms. A number of extinct taxa, from Pakicetus to Dorudon, are members of the total group, but not of the crown group. Therefore, they are part of the cetacean "stem group", or, more succinctly, "stem-cetaceans". (Indohyus may also be a stem-cetacean, but there are differing hypotheses.) Note that the stem group includes the ancestors of the crown group, but not all members of the stem group are ancestors of the crown group. For example, Basilosaurus cetoides is a stem-cetacean, but it is a somewhat derived offshoot of the cetacean lineage, with a long, snake-like body different from that of modern cetaceans or their ancestors.

Somewhere around the time of the Cretaceous-Paleogene extinction (when non-avian dinosaurs, among many other taxa, became extinct reached a population size of zero), the cetacean line split off from other extant lineages (either from the hippopotamid lineage, the ruminant lineage, or both at once—the artiodactyl lineage). The earliest stem-cetaceans were hoofed, but they soon gave way to amphibious varieties, which looked vaguely like mammalian crocodiles with flippers. Over time, adaptations toward an aquatic lifestyle were accumulated in stem-cetacean populations: tail flukes, dorsal fins, birth in the water. Stem-cetaceans were replaced by cetaceans, which possessed all of these adaptations. Early cetaceans split into two major lineages: one leading to the filter-feeding mysticetes and the other to the echolocating, predatory odontocetes.

Many living species of cetacean are threatened. Perhaps the worst case is that of the Yangtze River dolphin or baiji, Lipotes vexillifer. This human-sized freshwater cetacean was once one of the few animals to be actually protected by superstition (many others, instead, are endangered by it—think of rhinoceros horns as an ingredient in impotence remedies). But, in modern times, this protection has come to mean less. The last uncontested sighting of a baiji was in 2004. The IUCN currently classifies the species as critically endangered, but it may be extinct already. If so, it would be the first aquatic mammal species to go extinct in the 3rd millennium—less than a decade in and we're already off to a bad start.

Not all zoologists use Cetacea in the crown group sense; some paleontologists expand it to include some or all of the stem group. But there is a danger in doing this. Cetacea is primarily a term from the neontological (as opposed to paleontological) literature, so it is most often associated with the suite of characters that the living organisms possess. But members of the stem group may or may not possess these. A recent, spectacular discovery of a fossilized, pregnant Maiacetus (which would go in the above chart somewhere around Rodhocetus) shows that Maiacetus probably gave birth on land. It is not known (to me, anyway) whether they had dorsal fins or tail flukes.

Since extending neontological terms beyond the crown group can result in unwarranted character inferences, some systematists prefer to limit such terms to crown groups when possible. The PhyloCode, a nomenclatural code currently in draft form, advocates this approach (see, for example Recommendation 10.1B). (The PhyloCode is also the source of the "pan-" convention for the names of total groups; see Art. 10.3.)

Moving too fast? Let's slow down....

Sloths

Although today's sloths, or Folivora ("leaf-eaters"), are tree-dwellers, many in the past were terrestrial; some were even amphibious (living sloths are good swimmers when they need to be). Modern sloths exist in two clades: Bradypus, the three-toed sloths, and Choloepus, the two-toed sloths. The closest living relatives to sloths are Vermilingua ("worm-tongues"), or "true" anteaters (not to be confused with other long-tongued mammals that feed on eusocial insects, such as aardvarks, numbats, and echidnas). Together, sloths and anteaters comprise a clade called Pilosa ("hairy ones"). All living pilosans are Neotropical, although some fossil taxa were Nearctic (as are some of their cousins, the armadillos, or Loricata).

Here is a phylogeny with a sampling of species to give an overview of sloth evolution (again, highly abridged, to say the least):

Time goes from left to right. Left-right lines connect ancestor species to descendant species. Silhouettes are not to scale.
Note that I've flipped the living sloths upside-down ... err, right-side-up ... err ... never mind.

The sloth lineage split from its stem-anteater kin during the Paleocene. The original sloths were terrestrial, but at least two clades became highly arboreal (Bradypus and Choloepus, mentioned before). One clade, including Thalassocnus, went in a different direction and became amphibious. Most lineages, however, remained terrestrial, one of them culminating in the enormous Megatherium americanum, a sloth the size of an elephant.

If you look at the above diagram, you might think, "But, look, there are more than just two extant groups." This is because the diagram is on such a vast scale that it's impossible to distinguish the extant from the recently extinct. Here's the same phylogeny to a logarithmic scale, which expands recent time:


Now we can actually see the Holocene, or "Recent", our current geological epoch (unless you accept the Anthropocene—more on that later). And you can see that some taxa, such as Mylodon and Megatherium, died out around the Pleistocene-Holocene transition. This transition was only 11 to 12 thousand years ago (an eyeblink in geological time, as can be seen by the fact that it's not even visible in the first chart).

Some Haitian sloth species persisted until much more recent times. Parocnus serus and Synocnus comes were still hanging around (ha ha—just kidding, they were more or less terrestrial) when European explorers first came to the Caribbean. They may have died out in the 16th century C.E.

Sloths present an interesting case because the clades that can be considered crown groups have changed over the course of human existence. Twelve thousand years ago, when humans were still settling the New World, a sloth crown group would have included Mylodon, and within that group a smaller crown group would have included Choloepus, Hapalops, Thalassocnus, Megatherium, Synocnus, and Parocnus. (Thalassocnus and Hapalops were extinct, but would still be part of that crown group.) After the Holocene-Pleistocene extinctions, Mylodon would no longer be part of the sloth crown group, and the Choloepus-but-not-Bradypus crown group would no longer contain Thalassocnus, Megatherium, or Hapalops. This continued, more or less, until the European/African settling of the Caribbean, at which time Synocnus and Parocnus died out.

Today, some species of Bradypus (B. pygmaeus and B. torquatus) are endangered. Time will tell if conservation efforts win out, or if the Bradypus crown group shrinks further.

Defining Crown Groups

I've been talking about crown groups changing over time, but we need nomenclature to be stable. (Why? Well, for one thing, so we can communicate effectively about conservation efforts.) One way to do this is to tie names to phylogeny-based definitions. This is how the PhyloCode works.

There are three major ways to define a crown group:

1. Node-Based Definition

This is the simplest way: just build up a list of extant specifiers, take their final common ancestor, and add all descendants. As an example, we could define Cetacea as the clade originating with the final common ancestor of Balaena mysticetus Linnaeus 1758 and Delphinus phocaena Linnaeus 1758 (=Phocoena phocaena Gray 1825). One advantage of this type of definition is that we don't need to worry about the meaning of "extant".

There is a peril with this approach, though: what if a new phylogenetic hypothesis shows some member to be outside the delimited clade? Fortunately the PhyloCode allows for expedient "unrestricted" emendations in such cases (i.e., minor, commonsense emendations that don't require committe approval; see Art. 15). But ideally the need for such emendations should be avoided. One way to avoid this need is with modified node-based definitions, which come in two major flavors.

2. Branch-Modified Node-Based Definition

In this approach, we create a node-based definition using all extant members of a given total group. For example, the cetacean total group could be defined as everything sharing closer ancestry with B. mysticetus than with Hippopotamus amphibius Linnaeus 1758 or Bos taurus Linnaeus 1758. Thus, Cetacea could be defined as the clade originating with the final common ancestor of all extant organisms that share a closer common ancestor with B. mysticetus than with H. amphibius or B. taurus.

There are two pitfalls to this approach. One is that you might fail to specify the closest extant outgroup. For example, if pigs (suids) turned out to be closer to whales than cattle or hippos are, then, under that definition, pigs would be cetaceans! Again, this can be fixed with an unrestricted emendation, but it would be nice not to have to do that.

The other pitfall is that the author(s) must define "extant", but more on that later.

3. Apomorphy-Modified Node-Based Definition

This style of definition uses a derived character, or "apomorphy", to delimit a clade, and then creates a node-based clade using the members of that apomorphy-based clade. This requires some apomorphy that evolved within the stem group. Cetacea, for example, could be defined as the clade originating with the final common ancestor of all extant organisms that possess tail flukes homologous (synapomorphic) with those of B. mysticetus.

There are two pitfalls with this approach. One is that the apomorphy may turn out not to have evolved within the stem group. It may have evolved earlier, thus expanding the content of the clade, or it may have evolved independently multiple times within the crown group, thus contracting the content of the clade. (It must be said, though, that in the case of cetacean tail flukes, both possibilities are extremely unlikely.)

The other pitfall is the same as that of branch-modified node-based definitions: what does "extant" mean? Extant when? And by what criteria? Let's look at this in more depth.

The Many Flavors of "Extant"

Although many of the PhyloCode's articles deal with crown groups and total groups, the code doesn't provide a single definition of "extant". Instead, the author of the definition must select a meaning. The author has considerable latitude here. If nothing is specified, there is a default fallback: extant at time of publication (Art. 9.5).

Recent (Holocene)

In just about every place that the PhyloCode uses the word "extant", it is followed with a parenthesis: "(or Recent)". In other words, a crown group may be considered as a clade originating with the final common ancestor of Holocene organisms.

I find this problematic for a couple of reasons. One is that the Holocene covers all of human history and more, so just being Holocene is no guarantee that we'll have good specimens. Some Holocene species went extinct thousands of years before Sumerians ever put wedge to clay tablet. Look at the sloth phylogeny—some of the species, such as Mylodon sp. and M. americanum, seem to have gone extinct right before the Holocene. But what if some small populations endured for a short while in refugia? That could drastically change the content of, e.g., a branch-modified node-based clade including Choloepus but not Bradypus.

The other problem is that "Recent" doesn't really get at the reason why crown groups are interesting. They're interesting because we have a wealth of available data about some of their members, data which can be used to extrapolate ancestral states. The same amount of data is not present for stem groups, which are generally known from fossils, if they are known at all.

Non-Fossil Specimens

Philip Cantino, one of the authors of the PhyloCode, once told me (pers. comm.) his opinion on what "extant" should mean: "I think that any species that was extant recently enough to be represented in museums in a non-fossilized form (e.g., study skins, herbarium specimens) should be treated as extant." Note one big advantage of this approach: it's much simpler to verify whether something is extant.

This approach also gets closer to the basic intent of crown groups. Extra data are available in non-fossil specimens. But it's still short of the data present in living forms; for example, behavior is not observable. Is it enough extra data to warrant recognizing the species as extant for nomenclatural purposes? It boils down to opinion. (And I note that behavior might not be a very important consideration for Phil's purposes, since he works on plants.)

This idea has direct relevance for sloths, because one extinct form is actually represented by non-fossil specimens! Mylodon skins, complete with armor nodules and fur, still exist, having been preserved in caves. Supposed that Folivora were defined as the clade originating with the final common ancestor of all extant organisms sharing closer ancestry with Bradypus tridactylus Linnaeus 1758 than with Myrmecophaga tridactyla Linnaeus 1758 (the giant anteater). The question of whether Mylodon is extant would determine whether an entire clade (Mylodontidae) belongs to Folivora. (Of course, nobody says that has to be the definition of Folivora, or even that Folivora has to be a crown group, but this is just an example.)

Anthropocene

Although the Holocene is already a ridiculously short geological epoch, Cruzen and Stoermer (2000) proposed naming a new, much shorter geological epoch for the Industrial Age. They named the "Anthropocene" in recognition of the global effects that Industrial-Age humans have had upon the environment, and set its starting date as 1784 C.E., with James Watts' invention of the steam engine. (This is also, not coincidentally, around the time that certain effects of pollution start to appear in ice core samples.)

This designation hasn't met widespread adoption, to my knowledge, nor has it been proposed as a criterion for determining whether a species is "extant" for the purposes of nomenclature. But it seems to me like a better candidate than the Holocene. At least Anthropocene species have all coexisted with scientists.

Living at a Given Time in History

A similar candidate to using the Anthropocene, was proposed in a bulletin board discussion by Mike Taylor. Under this proposal, anything living during or after 1758 C.E. would be considered extant, 1758 being the year that the 10th edition of Linnaeus' Systema Naturae was published. That publication is regarded as the beginning of biological nomenclature by the botanical and zoological codes.

Both of these approaches (Anthropocene and Systema Naturae) have similar problems to the use of "Recent", although to a lesser extent. It's difficult to establish whether some species went extinct before or after the selected boundary. For example, the sloths Synocnus and Parocnus probably went extinct a couple of centuries earlier than these dates, but it's possible that they persisted in remote areas. An even closer example is Hydrodamalis gigas, Steller's sea cow, which seems to have gone extinct by 1768 (post-Systema Naturae, pre-Anthropocene!).

Living Now

Right now. Wait, I mean NOW. Wait ... no ... okay ... NOW.

Well, there is no one "now". Every instant is its own "now". Obviously, I mean something closer to the PhyloCode's default definition: extant as of the publication date of the definition.

This is less problematic than using earlier dates in some ways. We have much better ways of tracking populations today than we did in the 1700s. But pushing the date closer to the present also presents problems. Consider Steller's sea cow and the Yangtze River dolphin. It's easy to say that the sea cow is extinct, but the fate of the dolphin is still as unclear as the muddy waters it swims (or swam?) in. Consider: what if, despite the phylogeny presented above, Lipotes was found to be an outgroup to [other] extant cetaceans? Would the cetacean crown group include it or not? (Thanks to Matt Martyniuk for thinking of that example.)

And all of the meanings mentioned so far share another problem: the discovery of a previously unknown species could change everything. There are many example of "Lazarus taxa" (so-called because, like the character of Lazarus in the Christian gospels, they appear to rise from the grave), living organisms that represent clades previously known only from fossils: the Laotian rock rat, Laonastes aenigmamus (Diatomyidae); the Indian Ocean coelacanth, Latimeria; the gladiators, Mantophasmatinae (Insecta: Mantophasmatodea); the monito del monte, Dromiciops gliroides (Marsupialia: Microbiotheria); the Wollemi pine, Wollemia nobilis (Araucariaceae: Wollemia); etc. Although the discovery of such a species is always a wonderful event, it's potentially disruptive to modified node-based definitions.

Living And Published Upon

This last problem can be easily remedied, though: just require that something must be extant and published upon at the time of the definition. This could go a long way toward stabilizing definitions. The only drawback is that it could be seen as a bit arrogant: "If science hasn't heard of it, then it doesn't exist!" But this is only for nomenclatural purposes (of course Wollemi pines make a sound when they fall, whether scientists hear it or not).

But this still doesn't solve the problem of whether Lipotes is extinct or extant.

Let Someone Else Worry About It

The IUCN has put tons of thought and effort into these sorts of questions. One possibility would be to simply leave the question up to their Red List and let them worry about particulars. If I want to know if species X was extant in 2004, I check their database and see if its designation was something other than "extinct" for that year. They may not always be able to pinpoint the exact time of death for every species, but they do as good a job as anyone, or better.

Of course, the IUCN doesn't cover all species, leaving out 1) species that have been extinct for a long time (e.g., Tyrannosaurus rex), and 2) species that haven't been published by scientists yet (e.g., Laonastes aenigmamus in lists prior to 2005). But I think in both of these cases we can consider such species to be "non-extant for the purposes of nomenclature". Long-extinct species are clearly not extant. Treating undiscovered species as non-extant has the same stabilizing benefit as requiring an extant species to be published upon. The only problem spot is the taxa that the IUCN doesn't focus on, e.g., bacteria and archaeans. But this still leaves plenty of taxa that it works just fine for.

I think I like this approach best, at least for the taxa I study (amniotes). Delegate the issue to the experts. Mylodon and Synocnus are extinct. Lipotes is critically endangered (at least as of last year). The nomenclatural problem is taken care of, and we can move on to more crucial problems, like preserving the crown groups that we have.