Nonequilibrium States Promote One-Pot Nonenzymatic Carbon Fixation in the Reverse Tricarboxylic Acid Cycle and Amino Acid Synthesis

Several metabolites within the reductive tricarboxylic acid (rTCA) cycle have been found to form prebiotically. However, how these metabolites connect to each other and form rTCA cycle remains unresolved. The rTCA cycle is an ancient route and is considered significant for the emergence of life, since it connects to the routes of amino acids and nucleobases synthesis. A major challenge to complete the rTCA cycle under prebiotic conditions is the thermodynamically unfavorable reductive carboxylation of succinate to -ketoglutarate. Here, we address this challenge by using the nature of energy: nonequilibrium conditions. By calculating the changes in free energy, {Delta}G, of succinate to -ketoglutarate, and its downstream reactions: -ketoglutarate to glutamate and -ketoglutarate to isocitrate under different nonequilibrium conditions, we find that these two-step reactions are exergonic under nonequilibrium conditions at a 10000:1 reactant-to-product ratio at 1.013 bar, pH 10 and 70{degrees}C. To prove the concept, we catalyze succinate to glutamate at a 10000:1 reactant-to-product ratio, with NH2OH and sodium dithionite. The process is catalyzed by Fe(0), Fe3O4, and artificial proto-[4Fe4S] clusters in 1M NaCl at pH 10 and 70{degrees}C under 1 atm of 13CO2 for 48 hours. This nonequilibrium condition and one-pot system successfully promote the formation of -ketoglutarate through carbon fixation with succinate and its subsequent conversion to glutamate. These findings demonstrate nonequilibrium states enable -ketoglutarate formation through succinate and CO2, and suggest that a tendency toward natural thermodynamics may serve as a driving force for autocatalysis in the origin of life. ImportanceHow life began remains open, metabolism provides a key framework for origins. We use a simple and robust energetic principle to show that non-equilibrium conditions can drive the highly endergonic carboxylation step of the reverse tricarboxylic acid (rTCA) cycle, enabling one-pot synthesis of glutamate. This is work bridges the gap between protometabolites and protometabolsim, suggesting that metabolites may have accumulated first, creating concentration gradients that drove reactions and ultimately enabled the emergence of protometabolism. These findings provide a plausible pathway from prebiotic chemistry to the emergence of metabolism.