Take our AI Survey
Science News has partnered with Trusting News to gather feedback on the potential use of AI in journalism. Currently, we do not publish any content produced by generative AI (see our policy). We do want to hear your views on how Science News could use AI responsibly. Let us know by participating in a short 10 question survey.
DNA’s storage density is many orders of magnitude higher than that of any device humans have created. For example, if every movie ever made was encoded in DNA, it would fit inside the volume of a sugar cube with room to spare. But DNA is also incredibly fragile and needs careful handling and storage. Existing storage methods require freezing temperatures, specialized equipment or hazardous chemicals such as hydrofluoric acid. Researchers have tried storing DNA at room temperature in silica and other materials, without success.
Banal and colleagues’ new method, called Thermoset-REinforced Xeropreservation (T-REX), encapsulates DNA in glassy polymer networks at room temperature. Using a combination of lock-and-key chemicals that “open up” the polymer’s structure, the researchers can retrieve the DNA. The material is similar to polystyrene plastic, picked by the team because it isn’t easily broken down by nature: Anything encapsulated in plastic can endure for a very long time. But the team made a tiny yet important addition to the plastic — a chemical weakness in the form of a molecule called thionolactone. “That allows us to deconstruct the polymer to get the information back,” Banal says.
To test the resilience of the polymer, the researchers encapsulated strands of DNA containing the encoded Jurassic Park theme music and a human’s entire genetic instruction book in the amberlike material and then exposed it to temperatures of 55° Celsius, 65° C and 75° C at 70 percent humidity over seven days. The team used benign reagents, rather than hydrofluoric acid, to extract the stored DNA, then used DNA-reading techniques to retrieve the stored information, all in a matter of hours — not the days needed to do this with silica-based materials.
Once extracted, the DNA can even be re-encapsulated using the same material, in “a circular kind of chemistry that is actually very beautiful,” Banal says.
The T-REX method appears to be more efficient than existing methods to store DNA at room temperature, says Dina Zielinski, a computational biologist at Whitelab Genomics, a company in Paris focused on creating digital tools to accelerate drug development. “So even though one could argue that the improvements are incremental [compared with silica methods], they do bring us closer to practically being able to store nucleic acid for hundreds, even thousands, of years at room temperature, which has broad-reaching impact.”
Banal and colleagues are working on making the method simpler so that it can one day be used in the field to collect and preserve genetic data or other specimens, like seeds or proteins, in remote locations — or even used to transport biological molecules for space research.