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A simple mechanism could have been decisive for the development of life by Staff Writers Munich, Germany (SPX) May 28, 2018
The question of the origin of life remains one of the oldest unanswered scientific questions. A team at the Technical University of Munich (TUM) has now shown for the first time that phase separation is an extremely efficient way of controlling the selection of chemical building blocks and providing advantages to certain molecules. Life needs energy. Without energy, cells cannot move or divide, not even basic functions such as the production of simple proteins could be maintained. If energy is lacking, more complex connections disintegrate quickly, early life would die immediately. Chemist Job Boekhoven and his team at TUM have now succeeded in using phase separation to find a mechanism in simple molecules that enables extremely unstable molecules such as those found in the primordial soup to have a higher degree of stability. They could survive longer, even if they had to survive a period without external energy supply.
The principle of simplicity The reaction produces unstable anhydrides. In principle, these non-equilibrium products quickly disintegrate into carboxylic acids again. The scientists showed that the anhydrides that survived the longest were those that could form a kind of oil droplet in the aqueous environment.
Molecules in the garage Boekhoven explains the principle of phase separation with an analogy: "Imagine an old and rusty car: Leave it outside in the rain, and it continues to rust and decomposes because rusting is accelerated by water. Put it in the garage, and it stops rusting because you separate it from the rain." In a way, a similar process occurs in the primordial soup experiment: Inside the oil droplet (garage) with the long-chain anhydride molecules there is no water, so its molecules survive longer. If the molecules compete with each other for energy, again those that can protect themselves by forming oil droplets are likelier to survive, while their competitors get hydrolyzed.
Next goal: viable information carriers Marta Tena-Solsona, Caren Wanzke, Benedikt Riess, Andreas R. Bausch, Job Boekhoven; Self-selection of dissipative assemblies driven by primitive chemical reaction networks. Nature Communications, May 23, 2018 - DOI: 10.1038/s41467-018-04488-y
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