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Humans Are Forcing the Rapid Evolution of Wildlife. Can Animals Change Fast Enough?

Human activities are causing wildlife species to evolve faster than scientists once thought possible in a phenomenon known as rapid evolution

• By Katarina Zimmer
• Conservation
• Dec 18, 2024

Illustration by .

KRISTIN WINCHELL IS USED TO GETTING STRANGE LOOKS FROM LOCALS when she walks through San Juan, Puerto Rico, with a lasso-bearing fishing pole. , a New York University evolutionary ecologist, is on the prowl for , catching them on fences and buildings. These little lizards have taught her some important lessons about wildlife鈥檚 ability to adapt to our human-dominated world. Anoles in Puerto Rican cities, she has found, tend to sport than their forest-dwelling relatives, helping them sprint across treeless expanses to avoid getting snapped up by predators. Their larger and more intricate may allow them to cling tightly to the smooth surfaces of buildings.

The city lizards also excel at handling the blistering urban heat. When Winchell and her collaborator, Princeton University evolutionary biologist , placed some of them under a heat lamp and slowly dialed up the temperature, they stayed active until around 105 degrees F, about 1.8 degrees higher than their forest counterparts. Indeed, in a series of studies published over the past decade, she and her colleagues have learned that the lizards have evolved an entire suite of adaptations to urban living, fundamentally rewiring their bodies to survive the crushing pressures of the city. And they鈥檝e done so in as little as a few decades, Winchell marvels. 鈥淚 think it鈥檚 pretty incredible that these animals are changing so rapidly, and that we can actually measure it and see it unfolding.鈥�

Scientists long considered evolution to be a slow, incremental process that unfolds over millions of years鈥攐r 鈥渕any thousands of generations,鈥� according to Charles Darwin, who came up with the theory of evolution in the 19th century. That paradigm provided little hope that wildlife would be able to evolve ways to withstand the mounting human threats they face, from pollution and poaching to habitat loss and climate change.

But studies like Winchell鈥檚 increasingly are finding that wildlife species can evolve much, much faster than scientists once thought possible鈥攕ometimes in a matter of decades or just several to dozens of animal generations. These potential evolutionary shifts have been documented across a wide range of species, including insects, birds, reptiles and mammals鈥攁nd the term 鈥渞apid evolution鈥� is now a solid part of the scientific vernacular.

鈥淚t gives us some level of hope that 鈥� nature has some kind of resilience,鈥� says freshwater ecologist of in New York state. 鈥淲e don鈥檛 want to push these ecosystems too far, or these animals won鈥檛 be able to handle those pressures. But [this] can buy us some time until we get human impacts on ecosystems mitigated and reversed.鈥�

Analyzing genomes for evidence

Faced with an existential threat like unbearable temperatures, wildlife populations can respond in several ways, such as . Individual animals also can during their lifetimes, learning to seek out shade or . Evolution is different because it involves a change in a species鈥� DNA over several generations.

The process happens via natural selection, in which animals with poorly adapted versions of genes die or fail to reproduce. Only individuals with better-adapted gene variants reproduce and pass their genes on to the next generation, so that the population as a whole becomes increasingly well adapted. In this way, 鈥渁daptation can build novel solutions to challenges that we can鈥檛 imagine happening within a single lifetime of an organism,鈥� says evolutionary ecologist of University of California, Davis.

Because evolutionary adaptation is at heart a genetic process, it can be tricky to prove. Scientists often analyze genomes in search of evidence. Winchell, for example, that city lizards were indeed genetically different from their forest relatives in genes related to limb and skin development and heat tolerance. Researchers also may test how animals from different populations鈥攕uch as lizards from cities versus forests鈥攆are under heat, to help rule out that individuals aren鈥檛 just quickly acclimatizing. Some scientists also track animal families over time to determine that beneficial traits are indeed being inherited and aren鈥檛 just showing up due to random changes in a population. These kinds of studies haven鈥檛 been done for all claims of rapid evolution, but it鈥檚 clear the process is occurring in at least some species.

Some of the most notable examples are warming-related, where some bird or mammal species seem to be getting smaller and gaining longer limbs or beaks鈥攖raits thought to help off-load heat. In of South African deserts, the rodents鈥� spines have become around 5 millimeters stouter and their feet slightly larger over 18 years of monitoring rising temperatures, according to ecologist of Canada鈥檚 University of Manitoba. As with many other shape-shifting examples, it鈥檚 unclear if the animals are evolving to adapt or if, for example, temperatures are causing animal embryos to develop differently. If the squirrels indeed are evolving, it would be remarkable, she says, given they鈥檙e already so well suited to desert life, using their bushy tails as shade parasols and cooling off in burrows.

How hunting spawns evolution

Among the most striking examples of rapid evolution are responses to hunting. At Ram Mountain in the Canadian Rockies, evolutionary biologist of Canada鈥檚 Western University has been studying male bighorn sheep, which in most parts of Alberta can be shot legally only when their horns, viewed in profile, are large enough to nearly complete a circle. Over several decades of trophy hunting, Coltman and his colleagues saw average horn size in the population decrease. Coltman鈥檚 suggest that rams with long horns were killed more often, leaving mostly short-horned individuals that passed this trait on. One ram with especially short horns sired 25 offspring, he recalls. 鈥淗e was the most successful ram in the study period because he could never legally be harvested.鈥�

Other scientists have been amazed to find evidence of a similar evolutionary phenomenon in even longer-lived, slow-to-reproduce African savanna elephants. In Mozambique鈥檚 , elephants endured unprecedented levels of poaching for their tusks during a 20-year civil war. In the postwar 1990s, many female elephants were born without tusks, Campbell-Staton says. 鈥淚n the turnover of literally just a single generation,鈥� he says, 鈥測ou see this 鈥� selection and an evolutionary response.鈥�

In the Bahamas, a more benign human activity鈥攂uilding roads across tidal creeks鈥攁lso may have influenced evolution. When some roads ended up isolating creeks from the rest of the ocean, predatory fish such as barracuda and needlefish could no longer reach or survive in those creeks. That, in turn, caused populations of their mosquitofish prey to balloon. Those smaller fish then developed larger, more streamlined body shapes to better compete with one another, explains evolutionary ecologist of North Carolina State University.

Even the most unintentional effects of human activities can force evolutionary shifts. In Hawai鈥榠, researchers in 2006 that male Pacific field crickets had lost their mating call, probably to avoid being detected by a parasitic fly humans inadvertently introduced to the islands. Then in 2018, they the crickets had evolved a new call鈥攚hich sounded like purring鈥攍ikely undetectable to the fly. 鈥淚 don鈥檛 think I can overstate how remarkable that finding is: In response to an invasive parasite, a species rapidly evolves from having a song to not having a song and then to having a different song,鈥� Campbell-Staton says.

Trade-offs and traps

Evolutionary adaptation often comes with trade-offs, however. Large horns in bighorn rams may signal that they鈥檙e high-quality, strong males worth mating with, so by hunting the highest-quality animals, 鈥測ou might actually be depressing the population as a whole,鈥� Coltman says. In many U.S. cities, evolutionary biologist of Ohio鈥檚 Case Western Reserve University has a potential trade-off in acorn-inhabiting ants that have evolved a higher tolerance to heat. Ants with tend to have a higher metabolic rate, she says, meaning they might need more food than they feasibly could find.

Such trade-offs can happen because genes that underlie complex traits like heat tolerance may be linked to other traits, so changing one disrupts the other. When evolution occurs over long time periods, species have a chance to evolve ways of compensating, Campbell-Staton notes. 鈥淏ut in cases of rapid evolution, there鈥檚 just not enough time.鈥�

Rapid evolution also can lead species into traps. In the western United States, that happened to , which was adapted to lay its eggs on native plants such as the maiden blue-eyed Mary. But on one Nevada cattle farm colonized by a nonnative plantain introduced by European settlers, the butterfly had evolved to use the invasive plant instead, scientists reported in 1993. The plantain鈥檚 longer life span allowed checkerspot larvae to feed longer, boosting their survival. When, in 2005, farmers stopped ranching the meadow, native grasses overgrew the plantain. With nowhere to lay its eggs, the butterfly population went extinct. As rapid as rapid evolution can be, it鈥檚 often not rapid enough to keep pace with the fast-changing habits of humans.

Even for slower-burning threats like climate change, species are struggling to keep pace. One of Bay鈥檚 found that the fate of some corals in the Pacific鈥檚 Cook Islands hinges on the speed of change. Using computer simulations, she and her colleagues predicted that the corals would go extinct by mid-century if warming continues at current levels, but they could adapt and persist if nations take more action to fight climate change. And when Diamond recently examined several previous studies on the adaptability of a range of urban animals, including lizards and acorn ants, she found that although many species have adapted to small temperature increases, they鈥檇 falter at several degrees of warming. 鈥淭hey鈥檙e definitely giving it their best shot,鈥� Diamond says. But as of now, 鈥渢hey鈥檙e not quite keeping pace with the changes in the environment.鈥�

The fate of evolving wildlife depends not only on the speed of human activities but also on a species鈥� biology, including the genes underpinning traits. Complex adaptations like heat tolerance, which involves many genes, take longer to evolve than traits with a simple genetic basis. In Atlantic killifish, for instance, pollution tolerance appears linked to only a few genes, which helped fish living by toxic sites along the U.S. East Coast evolve tolerance in just a few dozen generations.

The imperative of genetic diversity

Adaptation also depends on the overall health of a wildlife population. The larger a population, the more genetically diverse it will be, and the higher the likelihood that some individuals will harbor useful genes to cope with threats. Connectivity to other populations also helps, says evolutionary biologist of Colorado State University. She and her colleagues recently discovered that the , a denizen of western riparian habitats, has more genetic variants linked to heat tolerance than it did decades ago鈥攁nd the bird possibly got those variants by interbreeding with a different flycatcher subspecies from San Diego that may have flown in.

Yet the flycatcher is declining in spite of its beneficial DNA, Ruegg says. She and other scientists stress that the onus remains on humans not only to dial down pressures but also to help wildlife adapt by preserving natural habitats. 鈥淲hat we can do,鈥� Ruegg says, 鈥渋s do our best to ensure the genetic health of populations, and that gives them the best shot at responding to the unknown.鈥�

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