An article from Oxford University on ox.ac.uk - Humans and Neanderthals: less different than polar and brown bears - reports on the recent research that suggests ancient humans, Neanderthals and Denisovans were genetically closer than polar bears and brown bears, and so, like the bears, were able to easily produce healthy, fertile hybrids.

Altamura Man (left). Reconstruction of Altamura Man, Altamura, Italy. Credit: Kennis & Kennis Reconstructions. Charles Darwin (right). Photographed by Julia Margaret Cameron.

The study, led by the University of Oxford’s School of Archaeology and published 3 June in the journal Proceedings of the Royal Society B, shows that the genetic distance values between humans and our ancient relatives were smaller than the distance between pairs of species which are known to easily hybridise and have fertile young.

Professor Greger Larson, Director of the Palaeogenomics & Bio-Archaeology Research Network (PalaeoBARN) at Oxford and senior author of the study explains that ‘Our desire to categorise the world into discrete boxes has led us to think of species as completely separate units. Biology does not care about these rigid definitions, and lots of species, even those that are far apart evolutionarily, swap genes all the time. Our predictive metric allows for a quick and easy determination of how likely it is for any two species to produce fertile hybrid offspring. This comparative measure suggests that humans and Neanderthals and Denisovans were able to produce live fertile young with ease.’

The long history of matings between Neanderthals, humans, and Denisovans has only recently been demonstrated through the analysis of ancient genomes. The ability of mammalian species, including ancient humans, to produce fertile hybrid offspring has been hard to predict, and the relative fertility of the hybrids remains an open question. Some geneticists have even said that Neanderthals and humans were at the ‘edge of biological compatibility’.

So the team developed a metric using genetic distances to predict the relative fertility of the first generation of hybrids between any two mammalian species. They did this by analysing genetic sequence data from different species that had previously been shown to produce hybrid offspring. By correlating the genetic distance with the relative fertility of the hybrid offspring, it was possible to show that the greater the evolutionary distance between any two species, the less likely it is that the offspring between them would be fertile. In addition, the team used the distance values to determine a threshold of fertility.

When the distance values between humans, Neanderthals and Denisovans were calculated, they were even smaller than the values between several pairs of species which are known readily and easily to hybridise - including polar bears and brown bears, and coyotes and wolves. This suggests we could have predicted the existence of Neanderthals and Denisovans in our genomes as soon as the first genetic sequences were generated.

This proxy can also be used to predict the likelihood that any two mammal species can give birth to live hybrids, a useful tool that can be used in decisions about whether to place animals together in zoos.

Richard Benjamin Allen, joint first author of the study adds ‘Many decisions in conservation biology have been made on the basis that related organisms that produce hybrids in captivity should be prevented from doing so. Such an approach has not considered the significant role that hybridisation has played in evolution in the wild, especially in populations under the threat of extinction. Our study can be used to inform future conservation efforts of related species where hybridisation or surrogacy programs could be viable alternatives.'

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