
IT HAS been holding its breath for months. Locked under an airless seal of ice, the extraordinary animal waits. At last, the warmth of spring brings relief. Claws twitch, a brain rouses and a beak pushes through the lake鈥檚 thawing slush to take a lungful of air. Incredibly, the western painted turtle is none the worse for having endured the kind of oxygen starvation that would normally kill a human in minutes.
At more than 100 days, the turtle holds the record among four-legged animals for surviving without oxygen. It is by no means the only creature to boast jaw-dropping talents. The constellation of powers found across the animal kingdom seems fantastical: the ability to almost completely regenerate innards, to dodge ageing or cancer, to slumber immobile for months without bone or muscle wasting, to slow biological time or even enter a state of suspended animation that can withstand all manner of trials, from freezing to bombardment with gamma rays.
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Almost as implausible-sounding is the idea that humans might be able to borrow some of these abilities. Yet the discovery that these powers are underpinned by genes and biological processes we too possess makes this a distinct possibility. Some potential applications 鈥 such as putting people into a sort of hibernation for space travel 鈥 remain distant goals. But others 鈥 including keeping transplant organs fresh without cooling and developing new tactics to tackle cancer and ageing 鈥 seem feasible. In fact, the US has launched a research project to exploit animal powers that could help injured soldiers on the battlefield (see 鈥Stop the clock鈥).
鈥淭his is going to be mind-blowing,鈥 says Rochelle Buffenstein at Calico, a biotechnology company in California backed by Google that aims to combat ageing.
The astonishing skills of animals have long fascinated scientists, but until recently it was tricky to work out the genetic underpinnings of their adaptations. This changed with the advent of 鈥渙mics鈥, technologies revealing the instructions contained in all of an animal鈥檚 genes 鈥 its genome 鈥 and the shifting activity of these genes and other bodily molecules in response to changes in the environment. The genomes of an ever-expanding range of astounding animals are being sequenced. This allows scientists to open new doors on the biology behind their superpowers, to spot relevant stretches of DNA and cellular processes and to zero in on them for further investigation. 鈥淲e can actually see what has not been seen before,鈥 says Sarah Milton at Florida Atlantic University.

Milton鈥檚 interest is in turtles, in particular their brains. Although not quite in the painted turtle鈥檚 league, the red-eared slider, a freshwater terrapin, can survive an impressive six weeks without oxygen under the ice and two days at room temperature. This is a remarkable feat of brain preservation. Brains guzzle energy to keep the electrical charges on the inside and outside of their cells properly balanced. Stifle the oxygen supply in humans 鈥 for example, in a stroke 鈥 and there is a catastrophic power cut: the pumps that bail electrical charge across cell membranes fail, upsetting the electrical balance inside neurons. This makes them dump toxic quantities of chemical signals known as neurotransmitters onto their neighbours, triggering further electrical mayhem and cell death.
Paradoxically, restoring oxygen makes things worse. As energy-depleted cells resume power generation, they create harmful by-products, known as reactive oxygen species, which damage and kill yet more cells.
To survive this last step, red-eared sliders have several tricks. One is to modify their metabolism so that they . Another is to that defend cells against damage. Humans have similar defences, but we deploy them differently. For example, we ramp up production of some of these proteins after damage has occurred, whereas turtles are constantly making them. The similarities are good news because they suggest we could tweak our biology to make it more like that of the turtles, says Milton. Potential medical applications extend to any condition where oxygen starvation is a problem, including stroke and heart attack.
Frozen frogs
Other animals have superpowers that allow them to endure freezing and thawing. The poster beast for this is the wood frog, which survives harsh Canadian winters by letting up to two-thirds of its body freeze 鈥 so solidly that it makes a clinking noise if gently tapped. 鈥淏iochemistry still goes on at -5掳C, but at one 10,000th the normal rate,鈥 says Ken Storey at Carleton University in Canada. The animal鈥檚 secret is producing a chemical that stops moisture being sucked from its cells as ice forms in the spaces around them. This ability suggests a possible solution to a pressing medical problem.
At the moment, preserving human organs for transplant operations is difficult because conventional freezing would destroy them. Two-thirds of all donated hearts go to waste every year. A team at Harvard University is now trying to to better preserve organs.
Storey is taking a different approach to this problem. His inspiration comes from animals that slow biological time without freezing. 鈥淭hat鈥檚 the new horizon: staying warm while turning everything off,鈥 he says. Creatures that hibernate at warmer temperatures include mammals, among them primates, our close relatives. This raises the possibility that we have retained at least some of the biological machinery needed to drastically slow our metabolic rate as they do. Storey and his team have found that there is indeed a 鈥 a shared set of biochemical responses in cells 鈥 for slowing metabolic rate.
To awaken these processes in humans, we need to pinpoint what switches them on and off. That is a challenge, but researchers are making progress. Being able to slow biological time in this way could be used to delay harmful processes such as those caused by injury, sepsis, stroke and heart disease. Ultimately, it might even make it possible for humans to travel into deep space.

An intriguing aspect of extraordinary adaptations is that they often have knock-on effects on the rest of an animal鈥檚 physiology. Many creatures that can survive without oxygen or that can lower their metabolic rates, for example, have unusually long, seemingly ageing-free lives. A case in point are naked mole rats, small rodents that should, based on body size, live for a mere five years, but instead can survive for 30. Even then, the cause of their demise is a mystery. 鈥淚 don鈥檛 know what they die of,鈥 says Buffenstein, who studies them.
A naked mole rat鈥檚 life is long but unenviable. The animals live underground in stifling tunnels where oxygen levels are extremely low. The earth they dig through is laced with toxic heavy metals and the tubers they eat are poisonous. On the bright side, living underground means they avoid predators and disease. This, it has been suggested, means they don鈥檛 have to race to reproduce and so have evolved to devote more of their resources to combating the cellular damage caused by their stressful environment. Over the years, scientists have tested this resilience by exposing them (or their cells in a dish) to a range of challenges including UV light, toxic compounds and high doses of chemotherapy drugs. The naked mole rat simply shrugs them off. 鈥淢ost of the time they just put their little third finger up at you and say, 鈥業 don鈥檛 care鈥,鈥 says Buffenstein.
This resilience means they don鈥檛 seem to age. As they get older, their heart function, bone density, muscle mass and metabolism stay healthy. A 30-year-old female mole rate is still highly fertile. What鈥檚 more, their resistance to developing cancer is legendary. In three decades of study, Buffenstein鈥檚 team has encountered only five cases of the disease when examining more than 2000 dead animals. They have also inserted versions of genes known to cause cancer into naked mole rat cells in a lab dish. In other mammals, this causes aggressive tumours to grow, but .
To fully explore the naked mole rat鈥檚 remarkable capabilities, we will need a complete version of its genome 鈥 our best effort currently has several gaps. But clues are emerging. Unlike red-eared sliders, naked mole rats don鈥檛 bother producing lots of antioxidants and so end up with bizarrely high levels of cellular damage from an early age. They seem to protect themselves from the consequences of this damage by boosting the activity of genes that stop damaged cells from dividing. These are genes that humans also possess. The rodent鈥檚 metabolism is unusual too 鈥 resembling that of animals on a calorie-restricted diet, which is associated with longevity.
Regenerating pythons
Interest in naked mole rats is high, but only time will tell whether we can tap into their powers to combat ageing and cancer. Meanwhile, another remarkable animal holds the promise of an even more futuristic capability. The python鈥檚 special power is extreme regeneration. These snakes starve for months before gobbling an entire animal in one sitting. So, to conserve energy, they let their internal organs shrivel between meals. 鈥淚n a fasting python, the intestine looks like a little tube that鈥檚 empty,鈥 says Todd Castoe at the University of Texas at Arlington. But when it does eat, a . Within a day, the small intestine has more than doubled its mass and other organs, including the liver, pancreas, heart and kidneys all swell by a half or more. Then, between 24 and 48 hours after eating, its innards start withering back to starvation mode, and the whole process is reversed in just two weeks.
Underlying this dramatic transformation is an equally dramatic burst of gene activity. Castoe鈥檚 team at different times before and after feeding. Predictably, many of the genes are involved in growth. But what intrigues Castoe are other genes that usually help protect cells against stress and were previously only associated with cancer and ageing. Turning these stress-response genes off while the growth ones remain on seems to trigger the organs to shrink back down again. 鈥淲e think we鈥檝e discovered a kind of back-door switch for how to modulate regenerative growth in a vertebrate,鈥 says Castoe.
The big question is what controls this dramatic response. The answer seems to be something in the snake鈥檚 blood. Add plasma 鈥 the liquid part of blood 鈥 from a recently fed snake to rat cells in a dish, and they undergo a burst of growth, to those the snake cells activate. This suggests that whatever is signalling to the python鈥檚 organs can talk to mammalian cells too. Castoe鈥檚 team is now hot on the trail of the mysterious signal. 鈥淚 don鈥檛 think you鈥檇 ever want a drug that made every one of your organs freak out and grow,鈥 he says. But the possibility of using insights from pythons to regenerate specific organs or block the growth of tumours is tantalising.
There is more to this research than mimicking animal superpowers. Extreme adaptations also offer a unique window into our own biology. For example, researchers are investigating pythons to better understand how our physiology changes after eating, in a bid to learn more about and .
Nature鈥檚 fantastic beasts can help us see what life is capable of, too. 鈥淲hat we鈥檙e learning about basic biology from such a weird perspective is so valuable,鈥 says Castoe. 鈥淚t鈥檚 almost like looking at a mountain from 90 degrees to one side.鈥
Stop the Clock

No animal goes to such extremes as the tardigrade, a creature so preposterously resilient that it can almost stop time. When faced with dehydration, these tiny eight-legged beasts, also known as water bears, slow their metabolisms to a point at which signs of life are barely detectable, a state known as cryptobiosis. Like this, they can survive bombardment with gamma radiation, extremes of temperature and the vacuum of outer space. They may have even survived crash-landing . The tardigrade鈥檚 ability to slow biological time has inspired scientists at the US Defense Advanced Research Projects Agency (DARPA) to set up a . Its aim is to buy time for soldiers injured in battle, where it is a challenge to administer treatments within the 鈥済olden hour鈥, the window that maximises their chances of survival.
DARPA鈥檚 scientists wanted to find biological processes shared by a wide range of animals able to slow down biological time, from tardigrades to hibernating bears. They homed in on the ability to hinder the activity of proteins that drive metabolism within cells. Then they identified three ways animals do this, and challenged other researchers to mimic these processes.
As a result, a team at Harvard University is trying to create drugs that reversibly lock proteins into an inactive state, . A second team is developing molecules that would link together inside cells to form lattices, and hence slowing their metabolic activity. Other teams are pursuing a third approach: aiming to produce , in vast quantities to both act as chaperones and crowd out other proteins.
Battlefield boon
Translating these developments into medicines will be a tall order. The Biostasis programme is taking it step by step and is aiming to get a usable technology out of each stage. The first step 鈥 stabilising individual proteins at room temperature 鈥 could aid the development of vaccines and antibody therapies that don鈥檛 need to be kept chilled, which would be a real boon in remote locations. Next, slowing the biology of whole cells could increase the shelf life of donated blood.
Finally, the ability to slow biological processes in tissues or whole animals could be used to reduce bleeding, tissue death and sepsis on the battlefield. It could also have civilian applications such as reducing damage from heart attacks and strokes. 鈥淚鈥檓 fascinated to see how far they can get with the tools that they build,鈥 says Tristan McClure-Begley, who heads the Biostasis programme.
Article amended on 21 October 2019
We corrected the number of legs that tardigrades have.