Bad evolution

There have been no science fiction movies that I know of that accurately describe evolution. None. And there have been very few novels that deal with it at all well. I suspect it’s because it makes for very bad drama: it’s so darned slow, and worst of all, the individual is relatively unimportant and all the action takes place incrementally over a lineage of a group, which removes personal immediacy from the script. Lineages just don’t make for coherent, interesting personalities.

io9 takes a moment to list the worst offenders in the SF/evolution genre. There are a couple of obvious choices: all of Star Trek, in all of its incarnations, has been a ghastly abomination in its depiction of anything to do with biology (I think you could say the same about its version of physics). Any episode with any biological theme ought to be unwatchable to anyone with any knowledge of the basics of the field; if you turn it off whenever it talks about alien races or whenever it mentions radiation from a contrived subatomic particle, though, you’d never see a single show. Gene Roddenberry must have been some kind of idiot savant, where the “idiot” half covered all of the sciences.

I’m very pleased to see that Greg Bear’s Darwin’s Radio gets mentioned for its bad biology. That one has annoyed me for years: Bear does a very good job of throwing around the jargon of molecular genetics and gives the impression of being sciencey and modern, but it’s terrible, a completely nonsensical vision of hopeful monsters directed by viruses and junk DNA. It’s also the SF book most often cited to me as an example of good biology-based science fiction, when it’s nothing of the kind.

TimeTree

People are always asking me for the source of those nice t-shirts that illustrate how long we’ve diverged from a given species. I think the name must be hard to remember: they’re at evogeneao.com. Now there’s a little software widget that will be just as neat-o.

Look up TimeTree, and remember to show it to the kids. This is a page with a simple premise: type in the name of two taxa (it will accept common names, but may give you a list of scientific names to narrow the search), and then it looks them up in the public gene databases and gives you a best estimate of how long ago their last common ancestor lived.

Grasshoppers and I, for instance, shared a many-times-great grandpa 981 million years ago. My zebrafish and I are practically cousins, with our last shared ancestor living a mere 454 million years ago. Hey, tree, we’ve been apart for 1407 million years, how’s it going? Sparrow! Long time no see! 325 million years, huh?

You get the idea. It’s great for getting the big perspective. The kids will pester you all the time for dates. Especially since…it’s got an iPhone app! Get on the App Store on your smart phone or iPad and search for TimeTree — it’s totally free (except for the cost of owning such a gadget, of course).

Oh, and once you’re done entertaining the children and yourself, it’s actually a serious tool. Tap on the results and it’ll take you to all the scientific details: breakdown of mitochondrial vs. nuclear date estimates, source papers, all that sort of thing.

For details on how it works, there’s also a published paper:

Hedges SB, Dudley J, Kumar S (2006) TimeTree: a public knowledge-base of divergence times among organisms. Bioinformatics 22(23):2971-2972.

Look, a cat! 92 million years.

Curl up and die already, HuffPo

Jebus, but I despise that fluffy, superficial, Newagey site run by the flibbertigibbet Ariana. I will not be linking to it, but if you must, you can just search for this recent article: “Darwin May Have Been WRONG, New Study Argues”. I don’t recommend it. It sucks. Read the title, and you’ve already got the false sensationalism of the whole story down cold.

It’s actually an old and familiar story that doesn’t upset any applecarts at all. There is a well-known concept in evolutionary theory of an adaptive radiation: a lineage acquires a new trait (birds evolve flight, for instance), or an extinction removes all competition and creates an opportunity for expansion (the dinosaurs are wiped out and mammals expand rapidly into vacant niches), and presto, new species and diversity abounds. For a really obvious example of this phenomenon, look to Darwin’s finches: one or a few species are storm-blown to an isolated chain of islands, and they gradually speciate to take on many roles.

See? No shock, no strike against evolution, or even against Darwin’s version of evolution. To claim otherwise is simply stupid.

Now the paper in question seeks to quantify the expansion of taxonomic diversity with the appearance of large-scale ecological opportunities, and concludes that competition and refinement by natural selection has not been the major driver of diversification, but that reason we have thousands of species of mammals and even more species of birds is more a consequence of chance and opportunity than strong competition. It’s a reasonable result, but not cause for a revolution; lots of us have been advocating for the importance of chance in evolution for many years, and it’s unsurprising that non-selective mechanisms of evolution will generate new diversity from a single species in an open, competition free field.

Bugger the awful Huffpo. One of the scientists, Sarda Sahney, has a nice blog with a sensible discussion of the paper. Read that instead.

It’s more than genes, it’s networks and systems

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Most of you don’t understand evolution. I mean this in the most charitable way; there’s a common conceptual model of how evolution occurs that I find everywhere, and that I particularly find common among bright young students who are just getting enthusiastic about biology. Let me give you the Standard Story, the one that I get all the time from supporters of biology.

Evolution proceeds by mutation and selection. A novel mutation occurs in a gene that gives the individual inheriting it an advantage, and that person passes it on to their children who also gets the advantage and do better than their peers, and leave more offspring. Given time, the advantageous mutation spreads through the population so the entire species has it.

One example is the human brain. An ape man millions of years ago acquired a mutation that made his or her brain slightly larger, and since those individuals were slightly smarter than other ape men, it spread through the population. Then later, other mutations occured and were selected for and so human brains gradually got larger and larger.

You either know what’s wrong here or you’re feeling a little uneasy—I gave you enough hints that you know I’m going to complain about that story, but if your knowledge is at the Evolutionary Biology 101 level, you may not be sure what it is.

Just to make you even more queasy, the misunderstanding here is one that creationists have, too. If you’ve ever encountered the cryptic phrase “RM+NS” (“random mutation + natural selection”) used as a pejorative on a creationist site, you’ve found someone with this affliction. They’ve got it completely wrong.

Here’s the problem, and also a brief introduction to Evolutionary Biology 201.

First, it’s not exactly wrong — it’s more like taking one good explanation of certain kinds of evolution and making it a sweeping claim that that is how all evolution works. By reducing it to this one scheme, though, it makes evolution far too plodding and linear, and reduces it all to a sort of personal narrative. It isn’t any of those things. What’s left out in the 101 story, and in creationist tales, is that: evolution is about populations, so many changes go on in parallel; selectable traits are usually the product of networks of genes, so there are rarely single alleles that can be categorized as the effector of change; and genes and gene networks are plastic or responsive to the environment. All of these complications make the actual story more complicated and interesting, and also, perhaps to your surprise, make evolutionary change faster and more powerful.

Think populations

Mutations are the root of biological variation, of course, but we often have a naive view of their consequences. Most mutations are neutral. Even advantageous mutations are subject to laws of chance in their propagation, and a positive selection coefficient does not mean there will be an inexorable march to fixation, where every individual has the allele. This is also true of deleterious mutations: chance often dominates, and unless it is a strongly negative allele, like an embryonic lethal mutation, there’s also a chance it can spread through the population.

Stop thinking of mutations as unitary events that either get swiftly culled, because they’re deleterious, or get swiftly hauled into prominence by the uplifting crane of natural selection. Mutations are usually negligible changes that get tossed into the stewpot of the gene pool, where they simmer mostly unnoticed and invisible to selection. Look at human faces, for instance: they’re all different, and unless you’re looking at the extremes of beauty or ugliness, the variations simply don’t make much difference. Yet all those different faces really are the result of subtly different combinations of mutant forms of genes.

“Combinations” is the magic word. A single mutation rarely has a significant effect on a feature, but the combination of multiple mutations may have a detectable or even novel effect that can be seen by natural selection. And that’s what’s going on all the time: the population is a huge reservoir of genetic variation, and what we do when we reproduce is sort and mix and generate new combinations that are then tested in the environment.

Compare it to a game of poker. A two of hearts in itself seems to be a pathetic little card, but if it’s part of a flush or a straight or three of a kind, it can produce a winning hand. In the game, it’s not the card itself that has power, it’s its utility in a pattern or combination of other cards. A large population like ours is a great shuffler that is producing millions of new hands every day.

We know that this recombination is essential to the rapid acquisition of new phenotypes. Here are some results from a classic experiment by Waddington. Waddington noted that fruit flies expressed the odd trait of developing four wings (the bithorax phenotype) instead of two if they were exposed to ether early in development. This is not a mutation! This is called a phenocopy, where an environmental factor induces an effect similar to a genetic mutation.

What Waddington did next was to select for individuals that expressed the bithorax phenotype most robustly, or that were better at resisting the ether, and found that he could get a progressive strengthening of the response.

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The progress of selection for or against a bithorax-like response to ether treatment in two wild-type populations. Experiments 1 and 2 initially showed about 25 and 48% of the bithorax (He) phenotype.

This occurred over 10s of generations — far, far too fast for this to be a consequence of the generation of new mutations. What Waddington was doing was selecting for more potent combinations of alleles already extant in the gene pool.

This was confirmed in a cool way with a simple experiment: the results in the graph above were obtained from wild-caught populations. Using highly inbred laboratory strains that have greatly reduced genetic variation abolishes the outcome.

Jonathan Bard sees this as a powerful potential factor in evolution.

Waddington’s results have excited considerable controversy over the years, for example as to whether they reflect threshold effects or hidden variation. In my view, these arguments are irrelevant to the key point: within a population of organisms, there is enough intrinsic variability that, given strong selection pressures, minor but existing variants in a trait that are not normally noticeable can rapidly become the majority phenotype without new mutations. The implications for evolution are obvious: normally silent mutations in a population can lead to adaptation if selection pressures are high enough. This view provides a sensible explanation of the relatively rapid origins of the different beak morphologies of Darwin’s various finches and of species flocks.

Think networks

One question you might have at this point is that the model above suggests that mutations are constantly being thrown into the population’s gene pool and are steadily accumulating — it means that there must be a remarkable amount of genetic variation between individuals (and there is! It’s been measured), yet we generally don’t see most people as weird and obvious mutants. That variation is largely invisible, or represents mere minor variations that we don’t regard as at all remarkable. How can that be?

One important reason is that most traits are not the product of single genes, but of combinations of genes working together in complex ways. The unit producing the phenotype is most often a network of genes and gene products, such at this lovely example of the network supporting expression and regulation of the epidermal growth factor (EGF) pathway.

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The EGF pathway (from www.sabiosciences.com/pathwaycentral.php)

That is awesomely complex, and yes, if you’re a creationist you’re probably wrongly thinking there is no way that can evolve. The curious thing is, though, that the more elaborate the network, the more pieces tangled into the pathway, the smaller the effect of any individual component (in general, of course). What we find over and over again is that many mutations to any one component may have a completely indetectable effect on the output. The system is buffered to produce a reliable yield.

This is the way networks often work. Consider the internet, for example: a complex network with many components and many different routes to get a single from Point A to Point B. What happens if you take out a single node, or even a set of nodes? The system routes automatically around any damage, without any intelligent agency required to consciously reroute messages.

But further, consider the nature of most mutations in a biological network. Simple knockouts of a whole component are possible, but often what will happen are smaller effects. These gene products are typically enzymes; what happens is a shift in kinetics that will more subtly modify expression. The challenge is to measure and compute these effects.

Graph analysis is showing how networks can be partitioned and analysed, while work on the kinetics of networks has shown first that it is possible to simplify the mathematics of the differential equation models and, second, that the detailed output of a network is relatively insensitive to changes in most of the reaction parameters. What this latter work means is that most gene mutations will have relatively minor effects on the networks in which their proteins are involved, and some will have none, perhaps because they are part of secondary pathways and so redundant under normal circumstances. Indirect evidence for this comes from the surprising observation that many gene knockouts in mice result in an apparently normal phenotype. Within an evolutionary context, it would thus be expected that, across a population of organisms, most
mutations in a network would effectively be silent, in that they would give no selective advantage under normal conditions. It is one of the tasks of systems biologists to understand how and where mutations can lead to sufficient variation in networks properties for selection to have something on which to act.

Combine this with population effects. The population can accumulate many of these sneaky variants that have no significant effect on most individuals, but under conditions of strong selection, combinations of these variants, that together can have detectable effects, can be exposed to selection.

Think flexible genes

Another factor in this process (one that Bard does not touch on) is that the individual genes themselves are not invariant units. Mutations can affect how genes contribute to the network, but in addition, the same allele can have different consequences in different genetic backgrounds — it is affected by the other genes in the network — and also has different consquences in different external environments.

Everything is fluid. Biology isn’t about fixed and rigidly invariant processes — it’s about squishy, dynamic, and interactive stuff making do.

Now do you see what’s wrong with the simplistic caricature of evolution at the top of this article? It’s superficial; it ignores the richness of real biology; it limits and constrains the potential of evolution unrealistically. The concept of evolution as a change in allele frequencies over time is one small part of the whole of evolutionary processes. You’ve got to include network theory and gene and environmental interactions to really understand the phenomena. And the cool thing is that all of these perspectives make evolution an even more powerful force.

Bard J (2010) A systems biology view of evolutionary genetics. Bioessays 32: 559-563.

No metazoan is an island

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I’m one of those dreadful animal-centric zoologically inclined biologists. Plants? What are those? Fungi? They’re related to metazoans somehow. Lichens? Not even on the radar. The first step in fixing a problem, though, is recognizing that you have one. So I confess to you, O Readers, that my name is PZ, and I am a metazoaphile. But I can get better.

My path to opening up to wider horizons is to focus on what I find most interesting about animals, and that is that they are networks of cells driven by networks of genes that generate patterned responses of expression by cell signaling, or communication. See? I’m already a little weird. Show me a baby bunny, and I don’t just see a cute little furry pal with an adorable twitchy nose, I see an organized and coherent array of differentiated tissues that arose by a temporal sequence of cell-cell interactions, and I just wanna open him up and play with his widdle epithelial sheets and dismantle his pwetty ducts and struts and fibers and fluids, oochy coo. And ultimately, I want to take apart each cell and ask why it has its particular assortment of genes switched off and on, and how its state affects its neighbors and the whole of the organism.

Which means, lately, that I’ve acquired a growing interest in bacteria. If I were 30 years younger, I could probably be seduced into a career in microbiology.

There are a couple of reasons why an animal-centric biologist would be interested in bacteria. One is the principle of it; the mechanisms that animal cells use to build complex arrangements of tissues were all first pioneered in single-celled organisms. We have elaborated and added details to gene- and cell-level phenomena, but it’s a collection of significant quantitative differences, with nothing known that is essentially new in metazoan cells. All the cool stuff was worked out by evolution in the 3-4billion years before the Cambrian, a potential that simply blossomed in the past half-billion years into big conglomerations of cells. Understanding how the building blocks of multicellularity work individually ought to be a prerequisite to understanding how the assemblages work.

But there’s another reason, too, a difference in perspective. It is our conceit to regard ourselves as individuals of Homo sapiens, a body of cells clonally derived from a single human cell. It’s not true. It turns out that each one of us is actually a whole population of species, linked by our evolutionary history and lumbering through the world as a team. Genus Homo is also genera Escherichi and Bacteroidetes and Firmicutes and many others.

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Physiology

Let’s begin with the most widely known factor: we’re mostly bacterial in cell numbers, with about ten times as many bacterial cells as human cells. Most of these are nestled deep in our guts, where they are indispensible. In mammals, they help break down complex polysaccharides which we can then absorb through the wall of the digestive tract — these are compounds that would be simply lost without bacterial assistance. Even more dramatically, termite guts contain colonies of bacteria that produce enzymes to break down cellulose. Another insect, aphids, live in plant saps which have negligible protein components, and they rely on gut bacteria that can synthesize nine essential amino acids. One cool feature is that the bacteria can’t complete the synthesis of leucine; the last step is carried out by aphid enzymes. The synthetic pathway is split acros two different species!

Another weird twist is that gut bacteria can affect morphology (or vice versa; physiology influences which gut bacteria thrive). Mice with a genetic predisposition to obesity were found to have a different distribution of gut bacteria; fat mice are full of Firmicutes, while lean mice are loaded with Bacteroidetes. Something in the genetics of the obese mice seems to favor the proliferation of that one species. Cause and effect is not so easily separated, though, since doing a fecal transplant and inoculating the guts of germ free mice with the bacteria from obese mice vs. lean mice has a surprising effect: the mice given obese mouse fecal enemas subsequently increased their body fat by 60%. The bacteria promoted more fat storage in the host animal.

So what, you may be thinking, it’s mice. However, it turns out that obese humans tend to have reduced amounts of Bacteroidetes species in their guts than lean people, and weight loss is accompanied by an increase in Bacteroidetes. Fecal transplants are not recommended as a weight loss technique…at least not yet.

They have worked for some other problems. Crohn’s disease and ulcerative colitis are diseases that involve intestinal inflammation, and they’re also associated with imbalances in the species distribution of gut bacteria. Some promising treatments have involved collecting feces from healthy individuals, and using a nasogastric tube to inoculate the guts of Crohn’s patients with the stuff. Ick, I know, but it seems to have worked surprisingly well in a small number of patients.

Development

Bacteria are present in the gut from a very early age, and populate the digestive epithelia. There must be interactions going on, and it appears that the bacteria are actually regulating the growth of the gut lining.

Germ-free zebrafish lines have no gut bacteria, and they also have problems. The intestinal lining arrests its development and fails to fully differentiate; the lining also grows much more slowly. They also have difficulty absorbing some nutrients. Add bacteria, though, and growth and differentiation resume. This is a case where the developmental program and the bacterial influences are interdependent, and it makes sense — they’ve co-evolved.

It’s not just fish, either — these are conserved interactions across the vertebrates. Mice exhibit the same dependence on gut flora for development of the intestinal lining.

The very best example of a developmental dependence on bacteria, though, is in squid. The bobtail squid has a light-emitting organ that relies on colonization by a luminescent bacterium, Vibrio fischeri. The animal gleans the bacteria from the water with a special ciliated epithelium and secreted mucus that seems to be just the right flavor for Vibrio, and the bacteria migrate deep into the light-emitting organ. Once colonized, the squid dismantles the harvesting cilia and downregulates the secretion of mucus. If no bacteria of the right species are present, it maintains the cilia. If the bacteria in the organ die, resumes mucus production.

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Bacterial symbionts induce light-organ morphogenesis in squid. A Adult squid (E scolopes). SEM images of epithelial fields before B and after C regression of ciliated appendage. Scale bar, 50 mm. Ciliated appendages are marked by an orange dashed line.

Evolution

If something affects development and physiology, it affects evolution, so evolutionary importance is simply rather unavoidable. However, there’s also one somewhat surprising observation (to me, at least — microbiologists probably expect it): different species of related organisms can have different microbial populations, even when raised in identical conditions. Different Hydra species in the lab under controlled conditions have recognizably different populations of bacteria living on their epithelia, and Hydra of the same species collected in the wild have similar distributions of species. The properties of each Hydra species uniquely favor different distributions of bacteria, and the bacteria are also preferentially colonizing particular species of Hydra.

Hydra are wonderful experimental animals in that one can ablate stem cells for a particular tissue type, and still get an animal that develops and lives; do the same thing to a vertebrate, for instance knocking out the mesodermal lineage in the embryo, and you get an aborted blob. In Hydra, you get a tissue that survives and is colonized by bacteria…but the kinds of bacteria populating it is different from the populations in the intact animal. The animal and the bacteria are swapping molecular signals that specify favored relationships. Again, these are coevolved populations that recognize molecular properties of the host and symbiont.

This is all getting very complicated. I’m used to thinking in terms of networks of genes: there are regulatory interactions between genes in a single cell that establish cell-type specific patterns of gene activity; all express a common core of genes, but different cell types, such as a neuron vs. a cell of the digestive epithelia, will also have their own unique special-purpose genes switched on. I’m also comfortable thinking of networks of cells: cells are in constant negotiations with their neighbors, mainting a common pattern of expression within a tissue, and defining interacting edges with other tissues. Cells are continually sending out messages about their state into the system and responding to local and global signals. All this is part of the normal process of thinking developmentally.

Now, though, there’s another layer: we have to think in terms of networks of species that cooperate in the development and physiology of individual multi-cellular organisms. Purity is compromised. My precious animalia — they’re inconceivable without bringing bacteria into the picture.

Fraune S, Bosch TCG (2010) Why bacteria matter in animal development and evolution. Bioessays 32:571-580.

Evolution isn’t libertarian

Larry Arnhart wrote a strange article in which he tried to claim Darwin and evolution for libertarianism, or as they prefer to call it nowadays, “Classical liberalism”. I was invited to give a reply, along with a few other people, but I can give the gist of my reaction here: no one gets to claim a biological justification for their political philosophy. Evolution does not endorse libertarianism, socialism, communism, or capitalism, and even if it did nudge one way or the other, that does not mean that we shouldn’t oppose the brutal short-term expediency of natural processes.

Make love, not war

Who remembers Robert Ardrey? I must shamefully confess that I was a fan back in the 1970s, when the ‘killer ape’ hypothesis was in the air. This was the idea that one of the things that made humans different and drove the evolution of the human brain was aggression and competition, specifically that big brains evolved as a weapon in a multi-million year intra-specific arms race. Arms races are cool concepts that, when first introduced to natural selection, seem like powerful mechanisms to drive the evolution of elaborate features.

I outgrew Ardrey, have no fear. As I learned more biology, I came to mistrust those umbrella hypotheses that appeared to explain everything with one simple premise — biology is complicated, and rarely fits into those simple categories. I also began to get suspicious of poorly credentialed popularizers who too often seemed most adept at twisting research to fit whatever hobby horse they were riding at the time (see also Elaine Morgan).

But mostly, it didn’t fit what we see in the real world. Think about your interactions with other human beings: probably, unless you’re in the military, the most ferociously antagonistic conflicts you encounter involve commenting on Pharyngula. The internet has a reputation for being contentious, but get real: it’s slinging words back and forth, feelings might get hurt, but the consequences to your survival and mating prospects are very, very low. You could even argue that most of the jostling isn’t about destroying our enemies, but about increasing in-group solidarity.

It’s even more true outside the abstract world of the internet. Most of our interactions with other people are regulated by deep-down protocols that we’re socialized into — if someone cuts into a queue ahead of you, we don’t pull out a stone axe and take care of the problem, we either roll our eyes and acquiesce or we complain verbally and get other people to shame the interloper. It’s relatively harmless. We go to work, and maybe you share an office with annoying jerks (of course you do, we all do), but we don’t go on a rampage and fight the boss for dominance, so we can purge the tribe of the ones we detest, who borrow our stapler and don’t give it back — no, we grumble and accommodate and cope somehow, and maybe try to work our way into a better position with social networking.

It’s what we are. We are social animals. In the history of our species, I think the most important signature of our evolutionary history is the construction of cohesive social units, groups larger than the individual, that allow us to survive better together than alone. We aren’t warring animals, we’re cooperative animals.

War is a byproduct. We’ve evolved and enculturated mechanisms that allow groups of increasingly larger size to persevere — a paleolithic tribe of 30 people is one thing, a nation of hundreds of millions or billions is another — and war occurs when these groups bump into one another. War is not the central activity of the human species, though, but a fringe event, a side-effect of processes that reinforce group cohesion and secondarily create friction when diverse social units encounter one another and demand responses that aren’t so strongly reinforced within our groups.

Anyway, that long ramble is an introduction to an interesting article on the history of war in primates. It’s just not that common in our closest relatives, the chimpanzees, and recent accounts of coordinated gang attacks may be unusual responses to high environmental stresses. This is not a good time to be a chimpanzee.

There are known examples of death by lethal tools in the human archaeological record, and this isn’t an argument that everyone since the dawn of time has been living in peaceful coexistence, but the documentable evidence of war is very thin. People are lovers, not killers.

Archaeologist Jonathan Haas of the Field Museum in Chicago concurs: “There is a very tiny handful of incidences of conflict and possible warfare before 10,000 years ago. And those are very much the exception.” In an interview with me he attributed the emergence of warfare in prehistory to growing population density, diminished food sources and the separation of people into culturally distinct groups. “It is only after the cultural foundations have been laid for distinguishing ‘us’ from ‘them,'” Haas says, “that raiding, killing and burning appear as a complex response to the external stress of environmental problems.”

On the other hand, Haas adds, “groups that are at war in one era or generation may be at peace in the next.” War’s recent emergence, and its sporadic pattern, contradict the assertion of Wrangham and others that war springs from innate male tendencies, he argues. “If war is deeply rooted in our biology, then it’s going to be there all the time. And it’s just not,” he says. War is certainly not as innate as language, a trait possessed by all known human societies at all times.

That’s the good news: warfare is a pathological condition for our species, brought on by external stress. We are not biologically committed to fighting one another.

The bad news is that external stresses are growing, with increasing demands for oil and water and food, with looming climate change likely to disrupt environmental stability, and with overpopulation increasing the friction within and between groups. Brace yourselves.

I might suggest, though, that the greatest human successes have arisen from developing tools to strengthen social unity and encourage competition — killing your neighbors is a sign of failure.

Radial tree of life

I use a very pretty radial tree of life diagram fairly often — the last time was in my talk on Friday — and every time I do, people ask where I got it. Here it is: it’s from the David Hillis lab, with this description:

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This file can be printed as a wall poster. Printing at least 54″ wide is recommended.
(If you would prefer a simplified version with common names, please see below.)
Blueprint shops and other places with large format printers can print this file for you.
You are welcome to use it for non-commercial educational purposes.
Please cite the source as David M. Hillis, Derrick Zwickl, and Robin Gutell, University of Texas.
About this Tree: This tree is from an analysis of small subunit rRNA sequences sampled
from about 3,000 species from throughout the Tree of Life. The species were chosen based
on their availability, but we attempted to include most of the major groups, sampled
very roughly in proportion to the number of known species in each group (although many
groups remain over- or under-represented). The number of species
represented is approximately the square-root of the number of species thought to exist on Earth
(i.e., three thousand out of an estimated nine million species), or about 0.18% of the 1.7 million
species that have been formally described and named. This tree has been used
in many museum displays and other educational exhibits, and its use for educational purposes
is welcomed.

There’s also a simplified version:

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Both of those are available as scalable pdfs, so you can zoom in and out to get just the right view, which is very handy.