Tardigrades: Surviving extreme radiation
When you think about the toughest animal in the world, you might think of a lion or tiger. But a less well-known contender for this title is a tiny animal known as a tardigrade, which is renowned for surviving extreme conditions. This includes being frozen, heated past the boiling point of water, completely dried out, exposed to the vacuum of outer space, and even being bombarded with extremely high levels of ionizing radiation (; ).
How tardigrades endure these extremes is one of the prevailing mysteries of physiology. Now, in eLife, Jean-Paul Concordet and Anne de Cian from the Muséum National d'Histoire Naturelle and colleagues – including Marwan Anoud, Emmanuelle Delagoutte and Quentin Helleu as joint first authors – report new insights into how tardigrades survive exposure to ionizing radiation ().
Ionizing radiation typically damages cells by causing their DNA to fragment (). In the past, it was thought that organisms capable of surviving extreme doses of radiation, like tardigrades, might do so by blocking and preventing the radiation from harming their DNA. A previous report suggests that tardigrades utilize a protein known as Dsup to prevent DNA damage during radiation exposure (). However, Anoud et al. found that tardigrades accumulate the same amount of DNA damage as organisms and cells which are intolerant to radiation, such as human cells grown in a dish (). If tardigrades do not survive ionizing radiation by directly blocking DNA damage, how do they endure such an insult?
To investigate, the team (who are based at various institutes in France and Italy) examined three species of tardigrade, using a technique known as RNA sequencing, to see which genes are switched on when exposed to ionizing radiation. They also tested tardigrades exposed to bleomycin – a drug that mimics the effects of radiation by creating double-stranded breaks in DNA.
Anoud et al. found that tardigrades upregulated the expression of genes involved in the DNA repair machinery that is common across many life forms, ranging from single-celled organisms to humans. The DNA damage the tardigrades initially accumulated following radiation or treatment with bleomycin also gradually disappeared after the exposure. Overall, these results strongly suggest that to cope with the DNA damage caused by ionizing radiation, tardigrades mount a robust set of repair mechanisms to help stitch their shattered genome back together.
In addition to seeing that DNA repair machinery is upregulated following ionizing radiation, Anoud et al. identified a new gene only present in tardigrades, which encodes a protein they named TDR1 (short for tardigrade DNA repair protein 1). Further experiments revealed that TDR1 can enter the cell nucleus and bind to DNA. This may be due to conserved portions of TDR1, which are largely positively charged, electrostatically interacting with negatively charged DNA. Moreover, at high concentrations, TDR1 not only binds to DNA, but forms aggregates in a concentration-dependent manner. Finally, Anoud et al. found that introducing the gene for TDR1 into healthy human cells reduced the amount of DNA damage caused by bleomycin, indicating that the TDR1 protein helps with DNA repair ().
Expressing the tardigrade protein TDR1 in human cells increases DNA damage repair.
While it is still unclear exactly how tardigrades fix DNA damage, this study suggests that their ability to survive extreme radiation is related to their strong DNA repair ability, which TDR1 likely plays a crucial role in. Anoud et al. found that TDR1 did not accumulate at DNA damage sites like some other repair proteins (). Instead, they propose that the protein mends DNA by binding to it and forming aggregates which compact the fragmented DNA and help maintain the organization of the damaged genome.
However, more research is needed to fully understand the mechanism responsible for TDR1 and other proteins helping tardigrades to survive ionizing radiation. Ultimately, knowing how these tiny organisms efficiently repair their DNA could lead to novel strategies for protecting human cells from radiation damage, which could benefit cancer treatment and space exploration.
This article is republished from . Read the original.
Enjoy reading ASBMB Today?
Become a member to receive the print edition four times a year and the digital edition weekly.
Learn moreGet the latest from ASBMB Today
Enter your email address, and we’ll send you a weekly email with recent articles, interviews and more.
Latest in Science
Science highlights or most popular articles
Guiding grocery carts to shape healthy habits
Robert “Nate” Helsley will receive the Walter A. Shaw Young Investigator in Lipid Research Award at the 2025 ASBMB Annual Meeting, April 12–15 in Chicago.
Quantifying how proteins in microbe and host interact
“To develop better vaccines, we need new methods and a better understanding of the antibody responses that develop in immune individuals,” author Johan Malmström said.
Leading the charge for gender equity
Nicole Woitowich will receive the ASBMB Emerging Leadership Award at the 2025 ASBMB Annual meeting, April 12–15 in Chicago.
CRISPR gene editing: Moving closer to home
With the first medical therapy approved, there’s a lot going on in the genome editing field, including the discovery of CRISPR-like DNA-snippers called Fanzors in an odd menagerie of eukaryotic critters.
Finding a missing piece for neurodegenerative disease research
Ursula Jakob and a team at the University of Michigan have found that the molecule polyphosphate could be what scientists call the “mystery density” inside fibrils associated with Alzheimer’s, Parkinson’s and related conditions.
From the journals: JLR
Enzymes as a therapeutic target for liver disease. Role of AMPK in chronic liver disease Zebrafish as a model for retinal dysfunction. Read about the recent JLR papers on these topics.