Fonte: Origins of Indonesian Hobbits finally revealed — ScienceDaily
No evidence of ‘hobbit’ ancestry in genomes of Flores Island pygmies
Pygmy population near cave where Homo floresiensis fossils were found appears to have evolved short stature independently from the mysterious ancient hominins
- Date:
- August 2, 2018
- Source:
- University of California – Santa Cruz
- Summary:
- Scientists sequenced the genomes of a pygmy population living near the cave in Indonesia where fossils were found of Homo floresiensis, a previously unknown, very small species of human nicknamed the hobbit. The analysis revealed evolutionary changes associated with diet and short stature in the pygmy population, but the researchers found no evidence of genetic elements that might have come from H. floresiensis.
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A fossil skeleton found in a cave on Flores Island, Indonesia, in 2004 turned out to be a previously unknown, very small species of human. Nicknamed the “hobbit” (officially Homo floresiensis), it remains a mysterious species with an unknown relationship to modern humans.
Intriguingly, the current inhabitants of Flores include a pygmy population living in a village near the Liang Bua cave where the fossils were found. An international team of scientists has now sequenced and analyzed the genomes of 32 people in this population. The analysis revealed evolutionary changes associated with diet and short stature in the pygmy population, but the researchers found no evidence of genetic elements that might have come from H. floresiensis.
“If there was any chance to know the hobbit genetically from the genomes of extant humans, this would have been it. But we don’t see it. There is no indication of gene flow from the hobbit into people living today,” said Richard E. Green, associate professor of biomolecular engineering at UC Santa Cruz and corresponding author of a paper on the findings published August 3 in Science.
Thus far, no one has been able to recover DNA from the H. floresiensis fossils. The researchers therefore searched the pygmy genome for any evidence of DNA sequences from an unknown ancient human lineage.
Green and other researchers previously recovered and sequenced DNA from fossils of other archaic humans — the Neanderthals and Denisovans — and determined that the genomes of some modern humans include DNA sequences inherited from those extinct human species. Those findings mean some interbreeding occurred in the distant past. The genomes of the Flores pygmies include small amounts of Neanderthal and Denisovan DNA, similar to other populations in Southeast Asia and Melanesia.
“Genetically, they’re not so different from other populations in that part of the world,” Green said.
Where they are different is in genes related to height and diet. Height is a very heritable trait, and geneticists have identified many genes for which certain variants are associated with taller or shorter stature. Green and his colleagues analyzed the Flores pygmy genomes with respect to height-associated genes identified in Europeans, and they found a high frequency of genetic variants associated with decreased height. This indicates that the evolution of short stature in the Flores pygmies was the result of natural selection acting on pre-existing genetic variation.
“It sounds like a boring result, but it’s actually quite meaningful,” Green said. “It means that these gene variants were present in a common ancestor of Europeans and the Flores pygmies. They became short by selection acting on this standing variation already present in the population, so there’s little need for genes from an archaic hominin to explain their small stature.”
Coauthor Peter Visscher at the University of Queensland, Australia, said the study addresses fundamental questions about human adaptation. “Just as livestock breeding happens through small changes in gene frequencies at very many loci, human adaptation works by exploiting the pool of polygenic variation available for selection,” Visscher said.
The Flores pygmy genome showed evidence of selection in genes for enzymes involved in fatty acid metabolism, called FADS enzymes (fatty acid desaturase). These genes have been associated with dietary adaptations in other populations, including the Inuit in Greenland. “It suggests that something in the past caused their diet to change dramatically, and they adapted by natural selection favoring certain variants of those genes,” Green said.
The fossil evidence indicates H. floresiensis was significantly smaller than the Flores pygmies, standing about three and a half feet tall (106 centimeters). The average height of the pygmies is more than a foot taller (145 centimeters).
The evolution of reduced body size in large mammals isolated on islands is a common phenomenon, often attributed to limited food resources and freedom from predators. At the time of H. floresiensis, Flores was also home to a dwarf elephant related to a now extinct species of mainland elephant. In general, large species tend to get smaller and small species tend to get larger on islands. The Flores giant rat is an example of the latter tendency.
“Weird things happen on islands,” Green said. “With the gene pool cut off from the larger population, an island population is free to evolve in unrestrained directions based on the demands of a small ecosystem.”
It is interesting that two different human species, one modern and the other now extinct, independently evolved short stature on Flores Island, he said. For now, however, the origins and relationships of the Flores hobbit, H. floresiensis, remain a mystery.
This work was supported in part by the Searle Scholars Program, U.S. National Institutes of Health, European Research Council, Australian Research Council, and the Ministry of Research and Technology of the Republic of Indonesia.
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Materials provided by University of California – Santa Cruz. Original written by Tim Stephens. Note: Content may be edited for style and length.
Journal Reference:
- Serena Tucci, Samuel H. Vohr, Rajiv C. Mccoy, Benjamin Vernot, Matthew R. Robinson, Chiara Barbieri, Brad J. Nelson, Wenqing Fu, Gludhug A. Purnomo, Herawati Sudoyo, Evan E. Eichler, Guido Barbujani, Peter M. Visscher, Joshua M. Akey, Richard E. Green. Evolutionary history and adaptation of a human pygmy population of Flores Island, Indonesia. Science, 2018 DOI: 10.1126/science.aar8486
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The most comprehensive study on the bones of Homo floresiensis, a species of tiny human discovered on the Indonesian island of Flores in 2003, has found that they most likely evolved from an ancestor in Africa and not from Homo erectus as has been widely believed.
The study by The Australian National University (ANU) found Homo floresiensis, dubbed “the hobbits” due to their small stature, were most likely a sister species of Homo habilis — one of the earliest known species of human found in Africa 1.75 million years ago.
Data from the study concluded there was no evidence for the popular theory that Homo floresiensis evolved from the much larger Homo erectus, the only other early hominid known to have lived in the region with fossils discovered on the Indonesian mainland of Java.
Study leader Dr Debbie Argue of the ANU School of Archaeology & Anthropology, said the results should help put to rest a debate that has been hotly contested ever since Homo floresiensis was discovered.
“The analyses show that on the family tree, Homo floresiensis was likely a sister species of Homo habilis. It means these two shared a common ancestor,” Dr Argue said.
“It’s possible that Homo floresiensis evolved in Africa and migrated, or the common ancestor moved from Africa then evolved into Homo floresiensis somewhere.”
Homo floresiensis is known to have lived on Flores until as recently as 54,000 years ago.
The study was the result of an Australian Research Council grant in 2010 that enabled the researchers to explore where the newly-found species fits in the human evolutionary tree.
Where previous research had focused mostly on the skull and lower jaw, this study used 133 data points ranging across the skull, jaws, teeth, arms, legs and shoulders.
Dr Argue said none of the data supported the theory that Homo floresiensis evolved from Homo erectus.
“We looked at whether Homo floresiensis could be descended from Homo erectus,” she said.
“We found that if you try and link them on the family tree, you get a very unsupported result. All the tests say it doesn’t fit — it’s just not a viable theory.”
Dr Argue said this was supported by the fact that in many features, such as the structure of the jaw, Homo floresiensis was more primitive than Homo erectus.
“Logically, it would be hard to understand how you could have that regression — why would the jaw of Homo erectus evolve back to the primitive condition we see in Homo floresiensis?”
Dr Argue said the analyses could also support the theory that Homo floresiensis could have branched off earlier in the timeline, more than 1.75 million years ago.
“If this was the case Homo floresiensis would have evolved before the earliest Homo habilis, which would make it very archaic indeed,” she said.
Professor Mike Lee of Flinders University and the South Australian Museum, used statistical modeling to analyse the data.
“When we did the analysis there was really clear support for the relationship with Homo habilis. Homo floresiensis occupied a very primitive position on the human evolutionary tree,” Professor Lee said.
“We can be 99 per cent sure it’s not related to Homo erectus and nearly 100 per cent chance it isn’t a malformed Homo sapiens,” Professor Lee said.
Story Source:
Materials provided by Australian National University. Note: Content may be edited for style and length.
Journal Reference:
- Debbie Argue, Colin P. Groves, Michael S.Y. Lee, William L. Jungers. The affinities of Homo floresiensis based on phylogenetic analyses of cranial, dental, and postcranial characters. Journal of Human Evolution, April 2017 DOI: 10.1016/j.jhevol.2017.02.006
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