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Life forms can catch rides to other planets on asteroid debris

Life forms can catch rides to other planets on asteroid debris

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Credit: Perplexity

Research Summary

A study supported by NASA shows that a resilient bacterium called Deinococcus radiodurans can survive extreme pressures similar to those produced when an asteroid strikes Mars and ejects material into space. In laboratory simulations, many bacteria survived pressures far beyond those previously thought lethal. The findings support the lithopanspermia hypothesis, which suggests that life could potentially travel between planets inside rock fragments. The research also raises important questions about the origins of life and highlights new challenges for planetary protection policies during space missions.

Life forms can catch rides to other planets on asteroid debris

Research Shock

Published on March 14, 2026 at 12:58 am

Summary

A study supported by NASA shows that a resilient bacterium called Deinococcus radiodurans can survive extreme pressures similar to those produced when an asteroid strikes Mars and ejects material into space. In laboratory simulations, many bacteria survived pressures far beyond those previously thought lethal. The findings support the lithopanspermia hypothesis, which suggests that life could potentially travel between planets inside rock fragments. The research also raises important questions about the origins of life and highlights new challenges for planetary protection policies during space missions.

The work demonstrates that a certain hardy bacterium easily withstands extreme pressure comparable to an ejection from Mars after an asteroid hit, as well as the inhospitable conditions it would face during the ensuing interplanetary journey.

The study in PNAS Nexus suggests that microorganisms can survive remarkably more extreme conditions than expected, and raises questions about origins of life. The work also has significant implications for planetary protection and space missions.

“Life might actually survive being ejected from one planet and moving to another,” says senior author K.T. Ramesh, an engineer who studies how materials behave in extreme conditions.

“This is a really big deal that changes the way you think about the question of how life begins and how life began on Earth.”

Impact craters cover the surfaces of most bodies in the solar system. Mars, a planet that could harbor life, is one of the most cratered celestial bodies. We know asteroid strikes can launch material across space—and Martian meteorites have been found on Earth.

However, scientists have long wondered if life forms could also be launched from an asteroid impact. Tucked inside ejected debris, they might land on another planet—a theory called the lithopanspermia hypothesis.

Previous experiments to test the theory have been inconclusive, and targeted organisms widely found on Earth, rather than a life form that would suit the extreme environments of other planets.

To study how a microorganism would realistically handle the stress of a planetary ejection, the team devised a way to replicate the pressure and a singular biological model.

The team chose to test Deinococcus radiodurans, a desert bacterium found in the high deserts of Chile that is notorious for its ability to survive the most inhospitable, space-like conditions—everything from extreme cold and dryness to intense radiation. It has a thick shell and a remarkable ability to self-repair.

“We do not yet know if there is life on Mars, but if there is, it is likely to have similar abilities,” Ramesh says.

The experiment simulated the pressure of an asteroid strike and ejection from Mars by sandwiching the microbe between metal plates and then firing a projectile at it from a gas gun. The projectile hit the plates at speeds up to 300 mph, generating 1 to 3 Gigapascals of pressure.

For perspective, the pressure at the bottom of the Mariana Trench, the deepest part of the Earth’s oceans, is a tenth of a Gigapascal. Even the lowest pressure in this experiment is more than ten times that.

After shooting the microbes, the team determined whether they survived and examined the survivors’ genetic material for clues to how they handled the pressure.

The bacteria proved very hard to kill. They survived nearly every test at 1.4 Gigapascal of pressure and 60% at 2.4 Gigapascals of pressure. The cells showed no signs of damage after the lower pressure hits, but after the higher pressure experiments, the team observed some ruptured membranes and internal damage.

“We expected it to be dead at that first pressure,” says lead author Lily Zhao, a graduate student. “We started shooting it faster and faster. We kept trying to kill it, but it was really hard to kill.”

In the end, what did die was the equipment. The steel configuration holding the plates fell apart before the bacteria did.

When asteroids hit Mars, ejected fragments experience a range of pressures, perhaps close to 5 Gigapascals, though some could see much higher. Here the microbe easily survived almost 3, much higher than previously thought possible.

“We have shown that it is possible for life to survive large-scale impact and ejection,” Zhao says. “What that means is that life can potentially move between planets. Maybe we’re Martians!”

The possibility of life spreading between planetary bodies has significant implications for planetary protection and space missions, the team says.

Space mission protocols evaluate the likelihood of life surviving on the target planet. When missions travel to planets that might sustain life, like Mars, there are tight restrictions and safety measures to prevent contaminating the planet with Earth life. And when a mission brings back materials from a planet, there are very strict measures to control the possible release of that life on Earth. Because this work demonstrates that materials from Mars might reach other bodies, particularly its two nearby moons that aren’t currently restricted, the team says policies might need to be reassessed.

Phobos, in particular, orbits so close to Mars that any ejecta that gets there is probably exposed to much less pressure than what is required to get to Earth, the team says.

“We might need to be very careful about which planets we visit,” Ramesh says.

The team next hopes to explore whether repeat asteroid impacts result in hardier bacterial populations—or whether bacteria adapt to this kind of stress. They’d also like to see if other organisms, including fungi, can survive these conditions.

The work was supported by NASA’s Planetary Protection program.

Source: Johns Hopkins University

Category

Space

Tags

Asteroids, Space, Alien life

Disclosure Statement

This article is posted in Futurity by Johns Hopkins University. To read the original content, please visit Futurity.

Research Paper

https://academic.oup.com/pnasnexus/article/5/3/pgag018/8503064?login=false

The work demonstrates that a certain hardy bacterium easily withstands extreme pressure comparable to an ejection from Mars after an asteroid hit, as well as the inhospitable conditions it would face during the ensuing interplanetary journey.

The study in PNAS Nexus suggests that microorganisms can survive remarkably more extreme conditions than expected, and raises questions about origins of life. The work also has significant implications for planetary protection and space missions.

“Life might actually survive being ejected from one planet and moving to another,” says senior author K.T. Ramesh, an engineer who studies how materials behave in extreme conditions.

“This is a really big deal that changes the way you think about the question of how life begins and how life began on Earth.”

Impact craters cover the surfaces of most bodies in the solar system. Mars, a planet that could harbor life, is one of the most cratered celestial bodies. We know asteroid strikes can launch material across space—and Martian meteorites have been found on Earth.

However, scientists have long wondered if life forms could also be launched from an asteroid impact. Tucked inside ejected debris, they might land on another planet—a theory called the lithopanspermia hypothesis.

Previous experiments to test the theory have been inconclusive, and targeted organisms widely found on Earth, rather than a life form that would suit the extreme environments of other planets.

To study how a microorganism would realistically handle the stress of a planetary ejection, the team devised a way to replicate the pressure and a singular biological model.

The team chose to test Deinococcus radiodurans, a desert bacterium found in the high deserts of Chile that is notorious for its ability to survive the most inhospitable, space-like conditions—everything from extreme cold and dryness to intense radiation. It has a thick shell and a remarkable ability to self-repair.

“We do not yet know if there is life on Mars, but if there is, it is likely to have similar abilities,” Ramesh says.

The experiment simulated the pressure of an asteroid strike and ejection from Mars by sandwiching the microbe between metal plates and then firing a projectile at it from a gas gun. The projectile hit the plates at speeds up to 300 mph, generating 1 to 3 Gigapascals of pressure.

For perspective, the pressure at the bottom of the Mariana Trench, the deepest part of the Earth’s oceans, is a tenth of a Gigapascal. Even the lowest pressure in this experiment is more than ten times that.

After shooting the microbes, the team determined whether they survived and examined the survivors’ genetic material for clues to how they handled the pressure.

The bacteria proved very hard to kill. They survived nearly every test at 1.4 Gigapascal of pressure and 60% at 2.4 Gigapascals of pressure. The cells showed no signs of damage after the lower pressure hits, but after the higher pressure experiments, the team observed some ruptured membranes and internal damage.

“We expected it to be dead at that first pressure,” says lead author Lily Zhao, a graduate student. “We started shooting it faster and faster. We kept trying to kill it, but it was really hard to kill.”

In the end, what did die was the equipment. The steel configuration holding the plates fell apart before the bacteria did.

When asteroids hit Mars, ejected fragments experience a range of pressures, perhaps close to 5 Gigapascals, though some could see much higher. Here the microbe easily survived almost 3, much higher than previously thought possible.

“We have shown that it is possible for life to survive large-scale impact and ejection,” Zhao says. “What that means is that life can potentially move between planets. Maybe we’re Martians!”

The possibility of life spreading between planetary bodies has significant implications for planetary protection and space missions, the team says.

Space mission protocols evaluate the likelihood of life surviving on the target planet. When missions travel to planets that might sustain life, like Mars, there are tight restrictions and safety measures to prevent contaminating the planet with Earth life. And when a mission brings back materials from a planet, there are very strict measures to control the possible release of that life on Earth. Because this work demonstrates that materials from Mars might reach other bodies, particularly its two nearby moons that aren’t currently restricted, the team says policies might need to be reassessed.

Phobos, in particular, orbits so close to Mars that any ejecta that gets there is probably exposed to much less pressure than what is required to get to Earth, the team says.

“We might need to be very careful about which planets we visit,” Ramesh says.

The team next hopes to explore whether repeat asteroid impacts result in hardier bacterial populations—or whether bacteria adapt to this kind of stress. They’d also like to see if other organisms, including fungi, can survive these conditions.

The work was supported by NASA’s Planetary Protection program.

Source: Johns Hopkins University

Institution

Research Shock

Category

Space

Tags

AsteroidsSpaceAlien life

Disclosure statement

This article is posted in Futurity by Johns Hopkins University. To read the original content, please visit Futurity.

Research Paper

Read the full research paper

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Institution

Research Shock

Category

Space

Tags

AsteroidsSpaceAlien life

Disclosure statement

This article is posted in Futurity by Johns Hopkins University. To read the original content, please visit Futurity.

Research Paper

Read the full research paper