Penn State researchers are building on the unique resilience of tardigrades, or “water bears,” to assess how the organisms would respond to and protect Martian resources. These tiny extremophiles are famous for their ability to survive in the vacuum of space. However, this study focused primarily on their molecular responses to Mars-like conditions, and the specific types of proteins that tardigrades use to protect their DNA and cellular structures. By studying the proteins produced by tardigrades, researchers have gained important information about biotechnological applications that could be used in future space expeditions. This information will not only help determine conditions for possible habitation on other planets, but also provide models for developing resilient, biomimetic materials that could be used to protect critical infrastructure and biological assets on the Martian surface.
Habitability cracked: How tardigrades survived the pressure of Mars
Tardigrades are best known for their ability to enter a dormant state called cryptobiosis, but Penn State researchers are studying the very specific molecular mechanisms that allow them to do this. Researchers have discovered a new class of “disordered proteins” with no clear three-dimensional structure that appear to form biological glass around the tardigrade’s DNA and other key cellular components when the tardigrades experience extreme stress, such as extreme radiation or low humidity from a Martian-like environment. The glass cover would likely prevent cells from shattering or being permanently damaged in a harsh environment like Mars.
Water bears are turning protein into protection
The results of this study suggest that the tardigrade’s survival strategy can be exploited to create a protective coating for valuable resources on Mars. By studying how these microorganisms stabilize their biomaterials, researchers hope to create biomimetic coatings that could protect sensitive technologies such as electronics and pharmaceuticals from degradation caused by cosmic radiation and extreme temperatures—effectively moving from passive observation of biological systems to designing “active protection systems” that would mark a major shift in how we think about sustaining human life on Mars in the long term.Understanding how tardigrades adapt can serve as an experimental framework when developing resilient infrastructure for Mars. The Penn State research team points out that biosynthetic analogues of ruptured proteins could potentially be synthesized to create self-healing or ultra-durable materials for building habitats. By designing similar organizational systems and methods that replicate these types of natural protection systems, future missions will eliminate the need for extensive heavy-duty shielding on spacecraft and be able to utilize lightweight, biocompatible polymeric materials that respond to the environment similar to how tardigrades respond when transitioning into their “tun” state, allowing for longer-lasting and more successful construction solutions.
Mars’ biological blueprint
By demonstrating that organisms on Earth can exploit specific molecular pathways in order to survive in an environment similar to Mars, this research is expanding the definition of a habitable environment; it also creates a reference point against which the likelihood of other alien bodies being considered habitable can be measured. Essentially, if we can adapt these biological models, the means to survive on Mars could be considered biologically engineerable, rather than just surviving through mechanical endurance. For NASA, this biological framework is critical to advancing its long-term plans to establish a sustained human presence on the moon and eventually Mars.
