Researchers report that a newly discovered 3- to 5-million-year-old Tibetan fox from the Himalayan Mountains, Vulpes qiuzhudingi, is the likely ancestor of the living Arctic fox (Vulpes lagopus).
This evidence lends support to the idea that the evolution of present-day animals of the Arctic region is intimately connected to ancestors that first became adapted for life in cold regions in the high altitude environments of the Tibetan Plateau.
In addition to the arctic fox, Wang’s team also uncovered extinct species of a woolly rhino, three-toed horse, Tibetan bharal (also known as blue sheep), chiru (Tibetan antelope), snow leopard, and badger, as well as 23 other mammals.
For the last 2.5 million years, our planet has experienced cold and warm, millennia-long cycles that collectively have become known as the Ice Age.
During cold periods, continental-scale ice sheets blanketed large tracts of the northern hemisphere. As the climate warmed up, these colossal glaciers receded, leaving Yosemite-like valleys and other majestic geologic features behind.
The advance and retreat of the ice sheets also had a profound influence in the evolution and geographic distribution of many animals, including those now living in the Arctic regions.
Xiaoming Wang, an adjunct professor of Earth sciences and biological sciences at the University of Southern California Dornsife College of Letters, Arts and Sciences, is the lead author of a new study published in the Proceedings of the Royal Society B: Biological Sciences.
The origin of the cold-adapted Pleistocene megafauna has usually been sought either in the arctic tundra or in the cool steppes elsewhere. But the team’s new fossil assemblage offers an alternative scenario, which the authors call the “out of Tibet” hypothesis.
It argues that some of the Ice Age megafauna (which in North America include the woolly mammoth, saber-toothed cat, giant sloths, and others) used ancient Tibet as a “training ground” for developing adaptations that allowed them to cope with the severe climatic conditions.
These Tibetan ancestors were thus pre-adapted to cold climates during the Ice Age (2.6 to .01 million years ago).
Tibet, according to Wang, is a rich but grueling location for paleontological fieldwork. Fifteen summer seasons and a good deal of luck have honed his team’s success. The expeditions involve a one-week journey to Lhasa, then a four-day drive into the remote “layer cake” sediments of the Zanda Basin—a drive made in old-model Land Cruisers known to get stuck in streams.
At more than 14,000-foot elevations, it’s difficult to breathe, water freezes overnight in camps, and the team members disband every morning to walk alone in search of fossils.
Wang and his team have trained their eyes to search for ancient lake margins, where the megafauna they’re interested in are often found. They alternate camp nights with nights in town to keep their strength up for a couple of weeks.
“There are a lot of challenges,” says Wang, of the National History Museum of Los Angeles County, “but in paleontological terms, it is a relatively unexplored environment.”
Additional coauthors of the paper contributed from USC, the Chinese Academy of Sciences, the Page Museum at the La Brea Tar Pits, and the Gansu Provincial Museum. These authors, on a team with other geologists and paleontologists and led by Wang, uncovered the fossil specimens in the Zanda Basin in southern Tibet in 2010.