This 2013 video from the USA says about itself:
A tiny, furry-tailed creature was the earliest ancestor of placental mammals — a widely diverse group of animals ranging from bats to humans — according to a new study by a team of international scientists, including a core group of Museum researchers. In findings published in the February 8 issue of the journal Science, the researchers analyzed the world’s largest dataset of genetic and physical traits to find that placental mammals diversified into present-day lineages much later than is commonly thought: after the extinction event 65 million years ago that eliminated non-avian dinosaurs. This finding, and the visualization of the placental ancestor — an insect-eating animal that weighed less than a pound — was made with the help of a cloud-based and publicly accessible database called MorphoBank.
MorphoBank is an initiative funded primarily by NSF with additional support from Stony Brook University, the American Museum of Natural History, the National Oceanic and Atmospheric Administration, and the National Evolutionary Synthesis Center.
From the University of Bristol in England:
15 February 2016
Rooting the family tree of placental mammals
Placental mammals consist of three main groups that diverged rapidly, evolving in wildly different directions: Afrotheria (for example, elephants and tenrecs), Xenarthra (such as armadillos and sloths) and Boreoeutheria (all other placental mammals). The relationships between them have been a subject of fierce controversy with multiple studies coming to incompatible conclusions over the last decade leading some researchers to suggest that these relationships might be impossible to resolve.
There are thus many outstanding questions such as which is the oldest sibling of the three? Did the mammals go their separate ways due to South America and Africa breaking apart? And if not, when did placentals split up?
“This has been one of the areas of greatest debate in evolutionary biology, with many researchers considering it impossible to resolve,” said lead author Dr Tarver of Bristol’s School of Earth Sciences. “Now we’ve proven these problems can be solved – you just need to analyse genome-scale datasets using models that accurately reflect genomic evolution.”
The researchers assembled the largest mammalian phylogenomic dataset ever collected before testing it with a variety of models of molecular evolution, choosing the most robust model and then analysing the data using several supercomputer clusters at the University of Bristol and the University of Texas Advanced Computing Centre. “We tested it to destruction,” said Dr Tarver. “We threw the kitchen sink at it.”
“A complication in reconstructing evolutionary histories from genomic data is that different parts of genomes can and often do give conflicting accounts of the history,” said Dr Siavash Mirarab at the University of California San Diego, USA. “Individual genes within the same species can have different histories. This is one reason why the controversy has stood so long – many thought the relationships couldn’t be resolved.”
To address the complexities of analysing large numbers of genes shared among many species, the researchers paired two fundamentally different approaches – concatenated and coalescent-based analyses – to confirm the findings. When the dust settled, the team had a specific family tree showing that Atlantogenata (containing the sibling groups of African Afrotheria and the South American Xenarthra) is the sister group to all other placentals.
Because many conflicting family trees have already been published, the team then gathered three of the most influential rivals and tested them against each other with the same model. All of the previous studies suddenly fell into line, their data agreeing with Tarver and colleagues.
With the origins of the family tree resolved, what does this mean for placental mammals? The researchers folded in another layer – a molecular clock analysis. “The molecular clock analysis uses a combination of fossils and genomic data to estimate when these lineages diverged from each other,” said author Dr Mario Dos-Reis of Queen Mary London, UK. “The results show that the afrotherians and xenarthrens diverged from one another around 90 million years ago.”
Previously, scientists thought that when Africa and South America separated from each other over 100 million years ago, they broke up the family of placental mammals, who went their separate evolutionary ways divided by geography. But the researchers found that placental mammals didn’t split up until after Africa and South America had already separated.
“We propose that South America’s living endemic Xenarthra (for exmaple, sloths, anteaters, and armadillos) colonized the island-continent via overwater dispersal,” said study author Dr Rob Asher of the University of Cambridge, UK.
Dr Asher suggests that this isn’t as difficult as you might think. Mammals are among the great adventurers of the animal kingdom, and at the time the proto-Atlantic was only a few hundred miles wide. We already know that New World monkeys crossed the Atlantic later, when it was much bigger, probably on rafts formed from storm debris. And, of course, mammals repeatedly colonised remote islands like Madagascar.
“You don’t always need to overturn the status quo to make a big impact,” said Dr Tarver. “All of the competing hypotheses had some evidence to support them – that’s precisely why it was the source of such controversy. Proving the roots of the placental family tree with hard empirical evidence is a massive accomplishment.”
‘The Interrelationships of Placental Mammals and the Limits of Phylogenetic Inference‘ by James E. Tarver, Mario dos Reis, Siavash Mirarab, Raymond J. Moran, Sean Parker, Joseph E. O’Reilly, Benjamin L. King, Mary J. O’Connell, Robert J. Asher, Tandy Warnow, Kevin J. Peterson, Philip C.J. Donoghue and Davide Pisani in Genome Biology and Evolution.