The Bizarre Bird That’s Breaking the Tree of Life



Extraits de l'article:

(...) Birds are the most diverse vertebrates on land, and they have always been central to ideas about the natural world. In 1837, a taxonomist in London told Charles Darwin that the finches he had shot and carelessly lumped together in the Galápagos Islands were, in fact, many different species. 

(...) The rise of genome sequencing, at the turn of the twenty-first century, seemed to bring Darwin’s dream within reach. 

(...) Hoatzins, which live along oxbow lakes in tropical South America, have blood-red eyes, blue cheeks, and crests of spiky auburn feathers. Their chicks have primitive claws on their tiny wings and respond to danger by plunging into water and then clawing their way back to their nests—a trait that inspired some ornithologists to link them to dinosaurs. Other taxonomists argued that the hoatzin is closely related to pheasants, cuckoos, pigeons, and a group of African birds called turacos. Alejandro Grajal, the director of Seattle’s Woodland Park Zoo, said that the bird looks like a “punk-rock chicken,” and smells like manure because it digests leaves through bacterial fermentation, similar to a cow.

DNA research has not solved the mysteries of the hoatzin; it has deepened them. One 2014 analysis suggested that the bird’s closest living relatives are cranes and shorebirds such as gulls and plovers. Another, in 2020, concluded that this clumsy flier is a sister species to a group that includes tiny, hovering hummingbirds and high-speed swifts. “Frankly, there is no one in the world who knows what hoatzins are,” Cracraft, who is now a member of B10K, said. The hoatzin may be more than a missing piece of the evolutionary puzzle. It may be a sphinx with a riddle that many biologists are reluctant to consider: What if the pattern of evolution is not actually a tree?

Fossils that resemble hoatzins have been found in Europe and Africa, but today the birds can be found only in the river basins of the Amazon and Orinoco of South America. 

(...) Hoatzins—“in some respects the most aberrant of birds,” according to one Victorian ornithologist—were a problem from the beginning. Early European naturalists described them as pheasants, and the first major tree for birds, published in 1888 by Max Fürbringer, placed them on the fowl branch. But, by the early nineteen-hundreds, some scientists were comparing hoatzins and cuckoos on the basis of traits such as jaws and feathers, and others were noting similarities between hoatzins and turacos, pigeons, barn owls, and rails. Even the hoatzin’s parasites defied classification: they hosted feather lice found on no other birds.

One crucial problem in phylogeny was convergent evolution. Sometimes natural selection nudges two organisms toward the same trait. Birds and bats independently evolved the ability to fly. Swifts and swallows each evolved into aerodynamic insectivores with nearly identical silhouettes, but traits such as their vocal organs and foot bones reveal that they are only distantly related. Because taxonomists often disagreed about things such as how to distinguish common ancestry from convergent evolution, the literature grew thick with conflicting trees, to the point that some twentieth-century biologists seemed ready to give up. “The construction of phylogenetic trees has opened the door to a wave of uninhibited speculation,” one wrote in 1959. “Science ends where comparative morphology, comparative physiology, comparative ethology have failed us.”

Phylogeny made a comeback in the seventies and eighties, after the German entomologist Willi Hennig developed more rigorous criteria for identifying common ancestry and drawing evolutionary trees. These innovations laid a foundation for a new wave of research that did not rely solely on physical specimens but, rather, on the emerging science of DNA. “Organisms are related to one another by the degree to which they share genetic information,” two ornithologists wrote in the early nineties, adding that genetics could reveal “a different view of the process of evolution and its effects.” The typical bird genome is a string of more than a billion base pairs that mutate randomly over time. Scientists can compare the same parts of the genome across multiple species to estimate their evolutionary closeness. Typically, species that share mutations have a more recent common ancestor, and species that do not are more distantly related.

Early sequencing was expensive and tedious, but, by the beginning of the twenty-first century, a signal was emerging from the noise. The journal Nature published an article about the promise of a single unified tree of life. But its author also identified a complication: each genome contains many different genes, and each one could generate a different evolutionary tree.

In 2001, a paper in the Proceedings of the Royal Society identified a pair of bird siblings as unlikely as Arnold Schwarzenegger and Danny DeVito: the flamingo’s closest relative was a little diving bird called a grebe. “That was probably the single most astounding result that anybody’s ever gotten,” Peter Houde, an avian biologist from New Mexico State University, told me. Ornithologists had always reasoned that grebes were closely related to short-legged loons, whereas tall wading birds such as flamingos, storks, and herons probably had a long-legged common ancestor.

That was the first domino to fall. In 2008, Science published a new avian tree based on DNA. Research led by Shannon Hackett, Rebecca Kimball, and Sushma Reddy, scientists affiliated with the Field Museum and the University of Florida, examined nineteen parts of the genomes of a hundred and sixty-nine avian species. The “root” of their tree resembled trees based on physical specimens: large, flightless birds such as ostriches, emus, and kiwis—known collectively as ratites—were first to diverge from all the others, followed by land fowl and waterfowl. The remaining ninety-five per cent of living birds, from parrots to penguins and pigeons, are known as “modern birds” and descended from a common ancestor, probably around the time that an asteroid hit the earth, sixty-six million years ago, and the dinosaurs went extinct. The youngest order—passerines, which include all songbirds—branched out into a staggering six thousand species in the span of tens of millions of years. The genetic tree for modern birds was decked with relationships that few, if any, taxonomists had guessed from anatomy; key groups such as parrots, owls, woodpeckers, vultures, and cranes shifted places.

Scientists had long assumed, for example, that daytime hunters such as hawks, eagles, and falcons all descended from a single bird of prey. But, in the genetic tree, hawks and eagles shared a branch with vultures, yet falcons turned out to be closer relatives of passerines and parrots. This meant that the peregrine falcon is more closely related to colorful macaws and tiny sparrows than to any hawk or eagle. The traditional explanation for flightlessness in ratites—that a common ancestor diverged into ostriches, emus, rheas, cassowaries, and kiwis after the southern continents split apart—also collapsed. DNA showed that the ratites also included flying birds called tinamous, suggesting that the group evolved flightlessness at least three separate times. “That study revolutionized our understanding of how the major groups of living birds are related to each other,” Daniel J. Field, an avian paleontologist at the University of Cambridge, said. Bird-watching guides had to reorganize their contents to reflect the new relationships.

What the study could not settle was the early evolution of modern birds. It was easy to tell when pheasants and ostriches turned off the highway of avian evolution, but modern birds did not follow a simple off-ramp. They seemed to zoom off in different directions, as though each kind of bird took a different exit from a busy roundabout. From their common ancestor—perhaps a little ground bird that pecked seeds and insects out of the ash that the asteroid left behind—modern birds split quickly into more than half a dozen branches. But the fastest computers of the time weren’t fast enough to disentangle them. All but one of these branches diversified into about ten thousand bird species. The last belonged to the hoatzin alone. The strange bird likely made the journey to the present day all by itself. “The enigmatic Opisthocomus (hoatzin) still cannot be confidently placed,” Hackett’s team wrote.

The first human genome sequences required hundreds of scientists and billions of dollars, but the costs fell quickly as the technology improved. In 2010, Tom Gilbert, an evolutionary biologist at the University of Copenhagen who previously studied mammoth and ancient human DNA, turned his attention to the pigeon genome. “I’m really interested in how regular city pigeons have spread around the world and done so well,” he told me. When he read the Hackett group’s study, he became curious about how the pigeon genome might fit into the larger picture of avian evolution. He wondered, “What if you had the perfect data set—all of the genome and not just parts of it?”

With the neurobiologist Erich Jarvis and the evolutionary geneticist Guojie Zhang, Gilbert assembled a team to pick up where researchers like Hackett had left off. The team, which grew to more than a hundred and twenty researchers, used nine supercomputer processing centers to sequence and analyze the genomes of forty-eight birds. (They got the hoatzin DNA sample from Houde, in New Mexico.) The tree they developed—featured on the cover of Science, along with an image of the hoatzin, in 2014—confirmed many of the Hackett group’s findings, challenged others, revealed new relationships, and used fossils to estimate the dates of divergences. Within fifteen million years of the extinction of dinosaurs, all the major lineages of modern birds emerged. The hoatzin’s long branch connected to the ancestor of cranes and shorebirds. “It kind of is a marshy waterbird,” Jarvis reasoned. But he and the other researchers couldn’t get strong statistical support for the hoatzin branch. He compared the bird’s origins with some of the most difficult questions he has faced in neurobiology. “Studying consciousness or language is the equivalent of figuring out where the hoatzin belongs,” he said.

The next year, the rival journal Nature published yet another tree. The Yale ornithologist Richard Prum argued that forty-eight species were too few, so his team compared a hundred and ninety-eight, sequencing a much smaller portion of their DNA. In this tree, several branches changed places around the time that the dinosaurs went extinct, suggesting new relationships for doves and pigeons; hummingbirds, swifts, and their relatives; and, of course, the hoatzin. Instead of yielding an authoritative tree of life, DNA had entrenched disagreement in the part of the tree most crucial to understanding the diversity of living birds. “There may be no amount of sleuthing or data or analysis that is going to resolve the placement of some of these lineages of birds,” Hackett told me. The conflicting signals in the hoatzin genome may not be analytical errors but biological realities—and they may require a different paradigm than the tree.

The tree is so ingrained in evolutionary biology that scientists encourage “tree thinking.” By learning to think in terms of trees, students can avoid the common fallacy of reading evolution as a ladder in which simpler organisms become more complex, as in the famous image “The Ascent of Man,” which shows a knuckle-walking ape evolving into an upright human. For all its pedagogical value, however, the tree also embeds subtle assumptions about evolution. The tree tends to downplay the genetic variation within species, which can obscure the fact that common ancestors are actually diverse populations that can pass on different versions of a gene to different descendants. It tells a story of endless partition and diversification, with branches that diverge and never reticulate.

While preparing their paper, Gilbert and his team had fiddled with their data set to understand the differences between gene trees. When they told their tree-building software to focus only on regions of the genome that Prum’s team used, it produced a tree that looked like Prum’s. When they shifted focus to other regions, a very different tree emerged. When they divided their bird genomes into thousands of different parts and ran each through their software, they got thousands of different trees, and not one completely matched the “species tree” they had constructed from large portions of genomes. “Different parts of the genome have different stories,” Gilbert realized. Genes do not stay in the lanes of common ancestry but can move much more unpredictably, like zigzagging pieces on a Plinko board. Scientists call this kind of genetic scrambling “incomplete lineage sorting,” and it is especially common during rapid bursts of evolution, such as the one that gave rise to modern birds.

In 2016, Alexander Suh, a biologist on the forty-eight-genome team, superimposed all the different gene trees they had generated. The resulting image of the early evolution of modern birds, around the time the dinosaurs went extinct, was not a tidy series of diverging branches but a kind of web or fishnet, whose contours constantly crossed paths. In a paper, Suh urged his colleagues to consider other patterns of evolution—to argue “less about which species tree is ‘correct,’ and more about if there is such a thing” as a traditional tree of life for modern birds.

(,,,) Relatives often shacked up, braiding their separate lineages back together. Something similar happens in nature when one species mates with another, producing a hybrid. Although tree-thinking biologists used to think that hybridization was extremely rare, genetic studies have shown that it actually happens all the time. Human DNA indicates that early Homo sapiens interbred with Neanderthals and other extinct hominins. Conservative estimates suggest that at least ten per cent of birds hybridize; among South America’s largest group of birds, that number is thirty-eight per cent, according to one recent study.

Hybridization may have been rampant in the aftermath of the asteroid strike, when modern-bird lineages first emerged. Interbreeding would have passed genes from one branch of the tree to another, adding another layer of complexity on top of incomplete lineage sorting. “Lineages that split and never talk to each other again—that’s not how biology works,” Stiller said. Still, she remains hopeful that one day we may build an authoritative diagram of the past. “Our models are still comparatively simple,” she told me. “We should be able to reconstruct evolutionary history if we have the right models and the right data.”

The outlines of animal evolution still look a lot like a tree in many places, which is why scientists continue to spend so much time developing and debating different branches. But, if tree thinking taught biologists that everything is connected, genes are suggesting that the connections can run even deeper than a tree can capture. To gain a more complete picture—and to answer questions like how such an unusual mix of traits came together in the hoatzin—scientists may need to think outside the tree. B10K grew out of the forty-eight-genome group and now includes computer scientists who specialize not in trees but in networks; they try to track the movement of genes between branches, and they often find that even supercomputers aren’t yet up to the job.

In B10K’s preliminary analyses, the hoatzin again winds up closely aligned with cranes and shorebirds, but the conclusion lacks a hundred per cent statistical support. “There’s still a lot of conflict in the data,” Stiller said. “Depending on how you analyze it, you will get different placements.” After B10K finishes its tree for three hundred and sixty-three birds, it’ll move on to the more than two thousand avian genuses, and eventually to every species of bird. These genomes will create a much more complete portrait—but, even then, they may not be able to solve the mystery of the hoatzin, or reconstruct every crook in the early evolution of modern birds.

“If the evolutionary history of the hoatzin conformed to processes we already understand well, then we’d probably have already figured out what it is most closely related to,” Houde wrote via e-mail. “The fact that we don’t know its nearest relative suggests that there were processes involved that we still do not understand.” He indicated that the hoatzin could have more than one set of closest relatives—which he called “an unsettling prospect in the context of existing classification and in the minds of many contemporary biologists.”

This strange-sounding state of affairs is not unique to the hoatzin; we see it in our own DNA. Human beings share their most recent common ancestor with chimpanzees and bonobos, but more than ten per cent of the human genome is actually more closely related to the gorilla genome. Another tiny fraction of the human genome also seems to be most closely shared with an even more distant relative: the orangutan. “This implies that there is no such thing as a unique evolutionary history of the human genome,” a team of molecular biologists wrote in 2007. “Rather, it resembles a patchwork of individual regions following their own genealogy.”

Darwin ended “On the Origin of Species” with a famous description of “an entangled bank, clothed with many plants of many kinds, with birds singing on the bushes, with various insects flitting about, and with worms crawling through the damp earth.” Molecular biologists hoped that genes would reveal the true and final shape of Darwin’s tree. Instead, they found a new kind of entangled bank, in which species are connected in unexpected ways. “There is grandeur in this view of life,” Darwin wrote of his scene. There is grandeur, too, in the view of life that is encoded in DNA. 




Polynesians steering by the stars met Native Americans long before Europeans arrived



Extraits de l'article:

By about 1200 C.E., Polynesians were masters of oceanic exploration, roaming 7000 kilometers across the Pacific Ocean in outrigger canoes. Guided by subtle changes of wind and waves, the paths of migrating birds, bursts of light from bioluminescent plankton, and the position of the stars, they reached and settled islands from New Zealand to Rapa Nui, or Easter Island, the closest Polynesian island to South America.

So it's natural to wonder: Did these world-class explorers make it the last 3800 kilometers to South America? A genomic study of more than 800 modern Polynesians and Native Americans suggests they did.

The work strengthens earlier evidence that somewhere—perhaps on the northern coast of South America—the two groups met and mixed well before the era of European colonialism. And it shakes up the most popular model of where Native American genes first took root in Polynesia, shifting the focus from Rapa Nui to islands farther west.

(...) Earlier hints of contact between the two regions included the sweet potato, which was domesticated in the Andes but grown and eaten all over Polynesia for hundreds of years before Europeans arrived. And a 2014 study of 27 modern people from Rapa Nui found they had Native American ancestry dating back to between 1300 C.E. and 1500 C.E.—at least 200 years before the first Europeans landed there in 1722 C.E. But a 2017 ancient DNA study, led by Fehren-Schmitz, found no sign of Native American ancestry in five people who lived on Rapa Nui before and after European contact.

Population geneticist Andrés Moreno-Estrada and anthropologist Karla Sandoval, both at Mexico's National Laboratory of Genomics for Biodiversity, traveled to Rapa Nui in 2014 and invited the community to participate in a study. They analyzed genome-wide data from 166 people from the island. Then they combined those data with genomic analyses of 188 Polynesian people from 16 other islands, whose genetic samples had been collected in the 1980s.

(...) Moreno-Estrada, Sandoval, and their team found that people on many islands had both Polynesian and European ancestry, reflecting their colonial histories. But they were also able to detect a small amount of Native American ancestry in people from the eastern Polynesian islands of Palliser, the Marquesas, Mangareva, and Rapa Nui. The Native American sequences were short and nearly identical—seemingly a legacy of one long-ago meeting with a Native American group, rather than sustained contact over generations, Moreno-Estrada says.

Comparing those sequences with genomes from people from 15 Indigenous groups from the Pacific coast of Latin America, researchers found most similarity to the Zenu, an Indigenous group from Colombia, the team reports today in Nature.

Analyses of the length of the Native American sequences show this ancestry appeared first on Fatu Hiva in the South Marquesas roughly 28 generations ago, which would date it to about 1150 C.E. That's about when the island was settled by Polynesians, raising the possibility the contact happened even earlier. The genetic legacy of that mixing was then carried by Polynesian voyagers as they settled other islands, including Rapa Nui.

Where exactly the first encounter took place, the team can't say. Modern Latin American fishermen lost at sea have been known to drift all the way to Polynesian islands. "It could have been one raft lost in the Pacific," Moreno-Estrada says.

But it's more likely that Polynesians traveled to the northern coast of South America, says Keolu Fox, a genome scientist at UC San Diego. Polynesian voyagers frequently traveled between islands and could have journeyed to South America and back, perhaps multiple times, Fox says. "In the process, these Polynesians bring back the sweet potato, and they also bring back a small fragment of Native American DNA" from relationships on the mainland. "The ocean is not a barrier" for Polynesians, he says.



Bothriolepis yeungae (Paleozoo)




 

Sarcopterygian Madageria fairfaxi model (Paleozoo)




Wikipedia: Les sarcoptérygiens (Sarcopterygii) forment un des deux taxons majeurs des vertébrés osseux comprenant quelques genres basaux (aujourd'hui éteints), les actinistiens (les cœlacanthes et leurs parents éteints) ainsi que les rhipidistiens (comprenant les dipneustes, les tétrapodes ainsi que les groupes apparentés aujourd'hui disparus). Ce groupe monophylétique comprend donc à la fois les poissons à nageoires charnues ou poissons à membres charnus et les tétrapodes, dont l'origine évolutive trouve ses prémices dans certains caractères dérivés communs des sarcoptérygiens.

 


Ammonite - Cephalopodia (Paleozoo)





 

Devonian Sea - Age of Fishes (Paleozoo)





 

Tiktaalik roseae - Late Devonian "Fishapod" ~ 375 mya (Paleozoo)





 

Pikaia gracilens - middle Cambrian basal chordate (Paleozoo)





 

Eurypterus remipes - portrait of a Silurian arthropod (Paleozoo)





 

Tetrapods Didn’t Conquer Land as Quickly as We Thought (Ben G Thomas)





 

Walking Dinosaur skeleton automata (Wes Brackman the RC enthusiast)





 

History Buffs: Rome








Tales of Human History Told by Neandertal and Denisovan DNA That Persist in Modern Humans (University of California Television)





 

La diversité du Québec autochtone !





 

Why The Dark Ages Were Actually A Time Of Great Achievement (Timeline)





 

A Modern Look at Dilophosaurus (BRIAN ENGH PALEOART)





 

Alfred the Great - Saviour of the Saxons Documentary (The People Profiles)





 

When Mammals Only Went Out At Night (PBS Eons)





 

How Dinosaurs Coupled Up (PBS Eons)





 

Palatine Hill Walking Tour in 4K (Prowalk Tours)





 

The Geography of the Ice Age (Atlas Pro)





 

The Absurd 2nd Century Space Opera You'll Never Read (Austin McConnell)





 

"Huron Carol" (Heather Dale)





 

Why Sour May Be The Oldest Taste (PBS Eons)





 

The history of the Iroquois confederacy (Thomas Sowell)





 

INCREDIBLE dinosaur leg fossil is discovered! (Dinosaurs: The Final Day with Attenborough - BBC)





 

When Apes Conquered Europe (PBS Eons)





 

Why French sounds so unlike other Romance languages (NativLang)





 

The Curious Case of the Cave Lion (PBS Eons)





 

Were We Wrong About The Last Common Ancestor? (Stefan Milo)





 

DINOSAURIA (Dead Sound)













Prehistoric Planet (Apple TV+)













 

Découverte d'une agglomération gauloise et romaine à Yviers (Charente) (Inrap)





 

Herculaneum: A Fate Worse Than Pompeii (Real History)





 

Acrocanthosaurus (X-Alex)



Wikipedia: Acrocanthosaurus is a genus of carcharodontosaurid dinosaur that existed in what is now North America during the Aptian and early Albian stages of the Early Cretaceous, from 113 to 110 million years ago. Like most dinosaur genera, Acrocanthosaurus contains only a single species, A. atokensis. Its fossil remains are found mainly in the U.S. states of Oklahoma, Texas, and Wyoming, although teeth attributed to Acrocanthosaurus have been found as far east as Maryland, suggesting a continent wide range.


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Ichthyornis (Rudolph Zallinger)




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Herrerasaurus (NTamura)




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Allosaurus (FredtheDinosaurman)




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Quetzalcoatlus northropi (0CoffeeBlack0)




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Dilophosaurus wetherilli (PaleoPastori)





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Mawsoniidae (amorousdino)




Wikipedia: Les Mawsoniidae constituent une famille éteinte de poissons à membres charnus de l'ordre des Coelacanthiformes. Ce taxon regroupe plusieurs genres qui ont vécu sur un très large intervalle de temps couvrant la quasi-totalité du Mésozoïque, du Trias inférieur jusqu'à la partie terminale du Crétacé supérieur, soit une durée d'environ 180 Ma (millions d'années) entre −252 et −70 Ma. Les Mawsoniidae ont vécu sur l'ensemble du globe : en Europe, en Afrique du Nord, en Amérique du Nord et du Sud, en Inde et en Chine.


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Stegosaurus (Sketchy-raptor)





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Les antiarches (artbyjrc)




Wikipedia: Les antiarches sont des poissons dotés de mâchoires (ce sont donc des gnathostomes) de la classe des placodermes. Ils se caractérisent, comme les autres placodermes (c'est-à-dire l'ordre des Arthrodires et celui des Ptyctodontes) par un corps recouvert d'une cuirasse. Ils possédaient de petits yeux rapprochés et même leurs nageoires étaient incluses dans un coffrage osseux, ce qui ne dut pas permettre à l'animal de nager très efficacement. Certains scientifiques proposèrent que les antiarches se déplaçaient en se propulsant sur le fond de l'océan avec leurs nageoires. Le groupe prospéra au Dévonien- en même temps que les Arthrodires carnassiers comme le Dunkleosteus- et les genres les plus célèbres sont Le Bothriolepis, de 30 centimètres et le Pterichthyodes de 13 centimètres, ainsi que le plus primitif Yunnanolepis.


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Ancient genomes offer rare glimpse of Neanderthal family groups



Extraits de l'article:

More than 49,000 years ago, a family of Neanderthals set up camp in a cave high in Siberia's Altai Mountains, overlooking a river valley where bison, red deer, and wild horses roamed. In the cave's main gallery, a teenage girl lost a tooth, perhaps while gnawing on bison that her father or his kin had hunted in the sweeping grasslands.

Now, researchers have analyzed the genomes of this father and daughter and 12 of their relatives, many of whom sheltered in the same cave over less than 100 years. The new genomes almost double the number of Neanderthal genomes known and offer a glimpse of the Neanderthal population at the eastern end of their range, at a time when they were headed toward extinction.

The genomes also offer the first real clues to the social structure of a group of Neanderthals. In addition to identifying the first father-daughter pair, the genetic evidence suggests these males stayed in their family groups as adults, like men in many modern human societies, says geneticist Laurits Skov of the Max Planck Institute for Evolutionary Anthropology. He presented the work in a virtual talk at the ninth International Symposium on Biomolecular Archaeology earlier this month.

"It's really remarkable that they managed to get genomes from seven males at one site," says paleogeneticist Cosimo Posth at Tübingen University. "For this group in this cave, it is indeed suggestive that they lived in small groups of closely related males."

Over the past decade, geneticists have sequenced the genomes of 19 Neanderthals. But that DNA mostly came from females who were distantly related and lived at sites across Europe and Asia anywhere between 400,000 and 50,000 years ago.

Computational biologist Benjamin Peter and paleogeneticist Svante Pääbo at Max Planck led the new study with a team including Skov, a postdoc. They extracted Neanderthal DNA from teeth, bone fragments, and a jawbone dug up during ongoing excavations at Chagyrskaya and Okladnikov caves by archaeologists at the Russian Academy of Sciences in Novosibirsk. Optically stimulated luminescence dates of the sediments around the teeth and bones suggest the Neanderthals lived between 49,000 and 59,000 years ago. Both caves are close—50 to 130 kilometers—to the famous Denisova Cave, which was inhabited by both Neanderthals and their close cousins, the Denisovans, off and on between 270,000 to 50,000 years ago.

The researchers analyzed DNA from more than 700,000 sites across the genomes from seven males and five females from Chagyrskaya, and from a male and a female from Okladnikov. They found family ties: The nuclear DNA from one Chagyrskaya bone fragment linked the father to the tooth shed by his teenage daughter. Some individuals shared two types of maternally inherited mitochondrial DNA (mtDNA). Those genomes hadn't yet differentiated from each other, which happens in a few generations, so the individuals must have lived during the same century.

The DNA painted a bigger picture of Neanderthal society. Several Chagyrskaya males carried long chunks of identical nuclear DNA from the same recent ancestor. Their Y chromosomes were also similar and came from a modern human ancestor, like those of the only three other male Neanderthal genomes known. The nuclear DNA also showed they were more closely related to later Neanderthals in Spain than to earlier ones at neighboring Denisova, suggesting migration.

The similarities among the males suggest they belonged to a population of only hundreds of men who were fathering children—about the same number of breeding males as seen in endangered mountain gorillas today. "If you were to think of this Neanderthal population like [populations today], they would be an endangered population," Skov says.

In contrast to the Y chromosome and nuclear DNA, the mtDNA of both males and females was relatively diverse, implying that more female ancestors contributed to the population than males. That could be a founder effect, in which the initial group included fewer fertile males than females. Or it could reflect the nature of Neanderthal society, says paleogeneticist Qiaomei Fu of the Chinese Academy of Sciences, who heard the talk. Either "fewer men than women contributed to the next generation, or women moved more frequently between groups," she says.

To Skov, the evidence suggests the latter. He says modeling studies show it's unlikely that a small group of migrants expanding from Europe into Siberia would include mostly females and few males. Instead, he thinks these Neanderthals lived in very small groups of 30 to 110 breeding adults, and that young females left their birth families to live with their mates' families. Most modern human cultures are also patrilocal, underscoring another way that Neanderthals and modern humans were similar.

Posth cautions that 14 genomes can't reveal the social lives of all Neanderthals. But he sees ominous signs in the males' low diversity. The end was fast approaching for our closest cousins: In just 5000 to 10,000 years, they would be gone.




Herrerasaurus ischigualastensis (PLASTOSPLEEN)




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Stegosaurus (FredtheDinosaurman)




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Smilodon (FredtheDinosaurman)




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Dimetrodon (Lokill9)




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Cryodrakon (cisiopurple)




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Conodont (Evoblast99)



Wikipedia: Conodonts (Greek kōnos, "cone", + odont, "tooth") are an extinct group of agnathan (jawless) vertebrates resembling eels, classified in the class Conodonta. For many years, they were known only from their tooth-like oral elements found in isolation and now called conodont elements. Knowledge about soft tissues remains limited. They existed in the world's oceans for over 300 million years, from the Cambrian to the beginning of the Jurassic. Conodont elements are widely used as index fossils, fossils used to define and identify geological periods. 


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Arcticodactylus (BrennanStokkermans)



A flock of Arcticodactylus soar through the waves of Triassic Greenland.


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Albertosaurus (Thek560)




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Heterosteus (Mario Lanzas)




Wikipedia: Heterosteus (also known as Heterostius) is an extinct genus of heterosteid placoderm of the Middle Devonian known from remains discovered in Europe and Greenland.

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Panderichthys (Mario Lanzas)




Wikipedia: Although it probably belongs to a sister group of the earliest tetrapods, Panderichthys exhibits a range of features transitional between tristichopterid lobe-fin fishes (e.g., Eusthenopteron) and early tetrapods.

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Shonisaurus (RudolfHima)




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Pteranodon (kepyle2055)




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Diplocaulus (kepyle2055)



Wikipedia: Diplocaulus (meaning "double caul") is an extinct genus of lepospondyl amphibians which lived from the Late Carboniferous to the Late Permian of North America and Africa. Diplocaulus is by far the largest and best-known of the lepospondyls, characterized by a distinctive boomerang-shaped skull. Remains attributed to Diplocaulus have been found from the Late Permian of Morocco and represent the youngest-known occurrence of a lepospondyl.


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Deinosuchus (RudolfHima)



Wikipedia: Deinosuchus is an extinct genus of alligatoroid crocodilian, related to modern alligators and caimans, that lived 82 to 73 million years ago during the late Cretaceous period. The first remains were discovered in North Carolina (United States) in the 1850s.

Although Deinosuchus was far larger than any modern crocodile or alligator, with the largest adults measuring 10.6 meters (35 ft) in total length, its overall appearance was fairly similar to its smaller relatives.

Deinosuchus fossils have been described from 10 U.S. states, including Texas, Montana, and many along the East Coast. Fossils have also been found in northern Mexico. It lived on both sides of the Western Interior Seaway, and was an opportunistic apex predator in the coastal regions of eastern North America. Deinosuchus reached its largest size in its western habitat, but the eastern populations were far more abundant. Opinion remains divided as to whether these two populations represent separate species. Deinosuchus was probably capable of killing and eating large dinosaurs. It may have also fed upon sea turtles, fish, and other aquatic and terrestrial prey.


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Compsognathus (BlueFluffyDinosaur)




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Avisaurus & Edmontosaurus (EWilloughby)




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La Brea (Midiaou)




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Ornitholestes (Midiaou)




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Skybalonyx (Midiaou)



Wikipedia: Skybalonyx is an extinct genus of drepanosaur from the Chinle Formation (Upper Triassic continental geological formation of fluvial, lacustrine, and palustrine to eolian deposits spread across the U.S. states of Nevada, Utah, northern Arizona, western New Mexico, and western Colorado).


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Ammonite (Olorotitan)




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Socrate




 

Triassic revolution: Animals grew back faster and smarter after mass extinction



Extraits de cet article:

Paleontologists in the U.K. and China have shown that the natural world bounced back vigorously following the End-Permian Extinction.

(...) predators became meaner and prey animals adapted rapidly to find new ways to survive. On land, the ancestors of mammals and birds became warm-blooded and could move around faster.

At the end of the Permian period, 252 million years ago, there was a devastating mass extinction, when nearly all of life died out, and this was followed by one of the most extraordinary times in the history of life. The Triassic period, from 252–201 million years ago, marks a dramatic re-birth of life on land and in the oceans, and was a time of massively rising energy levels.

"Everything was speeding up," said Professor Michael Benton of the University of Bristol School of Earth Sciences, the lead author of the new study.

(...) "After the end-Permian mass extinction, the fishes, lobsters, gastropods, and starfishes show nasty new hunting styles. They were faster, snappier, and stronger than their ancestors."

(...) On land too there were revolutionary changes. The latest Permian reptiles were generally slow-moving and used a kind of sprawling posture, like modern lizards, where the limbs stuck out at the side. When they walked, they probably generally moved slowly, and at speed, they could either run or breathe, but not both at the same time. This limited their stamina.

"Biologists have debated the origins of endothermy, or warm-bloodedness, in birds and mammals for a long time," said Prof Benton. "We can track their ancestry back to the Carboniferous, over 300 million years ago, and some researchers have suggested recently that they were already endothermic back then. Others say they became endothermic only in the Jurassic, say 170 million years ago. But all kinds of evidence from study of the cells in their bones, and even the chemistry of their bones, suggests that both groups became warm-blooded in the aftermath of the great end-Permian mass extinction, early in the Triassic."

The origins of endothermy in birds and mammals in the Early to Middle Triassic is suggested by two other changes: their ancestors mainly became upright in posture at this time. By standing high on their limbs like modern dogs, horses and birds, they could make longer strides. This probably goes hand-in-hand with some level of endothermy to enable them to move fast and for longer periods.

Second, it now seems that the Early and Middle Triassic bird and mammal ancestors had some form of insulation, hairs in the mammal line, feathers in the bird line. If this is true, and new fossil discoveries appear to confirm it, all the evidence is pointing to major changes in these reptiles as the world rebuilt itself after the end-Permian mass extinction.

"Altogether, animals on land and in the oceans were speeding up, using more energy, and moving faster," said Prof Benton. "Biologists call these kinds of processes 'arms races,' referring to the Cold War. As one side speeds up and becomes more warm-blooded, the other side has to as well. This affects competition between plant-eaters or competition between predators. It also refers to predator-prey relationships—if the predator gets faster, the prey does too in order to escape."

"It was the same underwater as well," said Dr. Wu. "As the predators became faster, snappier, and smarter in attacking their prey, these animals had to develop defenses. Some got thicker shells, or developed spines, or themselves became faster in order to help them escape."

"These are not new ideas," says Benton. "What is new is that we are now finding that they were all apparently happening about the same time, through the Triassic. This emphasizes a kind of positive aspect of mass extinctions. Mass extinctions of course were terrible news for all the victims. But the mass clear-out of ecosystems in this case gave huge numbers of opportunities for the biosphere to rebuild itself, and it did so at higher octane than before the crisis."



Samuel De Champlain (carts)




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Tristichopterids (artbyjrc)




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Stegocephalians (artbyjrc)




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Permien (Mario Lanzas)




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Pelycosauria Synapsids (Mario Lanzas)




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Paracrax gigantea (Christopher252)




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Appalachiosaurus (kepyle2055)




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Allosaure (kepyle2055)




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Hesperornis (RudolfHima)




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