But do these behavioral changes in the bears’ hunting habits correspond to changes in their comparatively distinct genome? The scientists don’t have an answer yet. “We don’t even know that the behavioral differences and the demographic differences and physiological differences that Kristen [Laidre] has observed, if those are genetic changes or just part of the flexibility of the normal polar bear genotype,” Shapiro says. “That’s a great thing to focus on in the future, because it would be really interesting to understand.”
Shapiro’s Nature Ecology study also focused on what may have happened to other polar bear genomes during periods of low ice—in this case, around 120,000 or 125,000 years ago when, according to Shapiro, Arctic ice levels were similar to the present day’s. But here, she looked at the relationship between polar bears and brown bears.
Her team constructed a phylogenetic tree—sort of like an evolutionary map showing how the bears diverged from a common ancestor over time—using Bruno’s genome and those of currently living polar bears, brown bears, and a black bear. (Shapiro was able to utilize one of Laidre’s Southeast Greenland polar bear genomes in her analyses, although the time gap between its life and Bruno’s is enormous. The sample pool, she says, is “missing 100,000 years of evolution.”)
From this and other analyses, the scientists gained some evidence that about 20,000 years before Bruno was born, brown bears and polar bears mixed to generate hybrid offspring. The scientists hypothesized that during this warm period, polar bears might have made their way on shore. The carcasses of the marine mammals they hunted could have attracted brown bears—leading to mating opportunities. As a potential result of this ancient interbreeding, Shapiro says, up to 10 percent of the genome of the modern brown bear comes from polar bear ancestry.
Figuring out how and when polar bears and brown bears commingled, further specialized, or diverged is a difficult task, given the limited fossil record and complexities of evolution. “Evolution is a messy process,” says Andrew Derocher, a polar bear researcher at the University of Alberta who was unaffiliated with the studies. He likens the process of evolutionary speciation to a “massive bunch of vines that are creeping up the base of a tree,” crisscrossing and entangling. “Eventually, some of those vines might get their own trajectory, and that’s what our species are,” he says. “But in this process, they can cross over, they can reconnect and fuse, and it’s certainly impossible to pull it apart, because they’re so interconnected.”
Still, these two studies are linked, Laidre says, “in the sense of: Where have polar bears persisted when sea ice was low, and how?” The research may provide some insight into how bears in the past—and today’s Southeast Greenland bears—have survived in warmer climates with less ice.
But how genetic changes manifest in physical form, and how those changes may have helped bears survive past warming events, are still open questions, the scientists say. And these study results shouldn’t make us feel that the problem of Arctic warming is resolved, or that today’s bears can easily adapt to rapidly shrinking levels of sea ice. “It seems like global warming is happening too fast,” Lindqvist says. She wonders if the polar bears “can keep up.”
After all, polar bears depend on seals as their food source—and those seals depend on sea ice. “There’s parts of the Arctic that used to be excellent seal habitats and excellent polar bear habitats,” Derocher says. “But there’s no sea ice there anymore. And as a result, there’s virtually no bears. There’s very few seals, and the ecosystem has basically unraveled.”
What, then, might actually help? “Global action on climate change,” Laidre says. “That’s it.”
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