Abstract
The numerous and varied roles of phosphorylated organic molecules in biochemistry suggest they may have been important to the origin of life. The prominence of phosphorylated molecules presents a conundrum given that phosphorylation is a thermodynamically unfavorable, endergonic process in water, and most natural sources of phosphate are poorly soluble. We recently demonstrated that a semi-aqueous solvent consisting of urea, ammonium formate, and water (UAFW) supports the dissolution of phosphate and the phosphorylation of nucleosides. However, the prebiotic feasibility and robustness of the UAFW system are unclear. Here, we study the UAFW system as a medium in which phosphate minerals are potentially solubilized. Specifically, we conduct a series of chemical experiments alongside thermodynamic models that simulate the formation of ammonium formate from the hydrolysis of hydrogen cyanide, and demonstrate the stability of formamide in such solvents (as an aqueous mixture). The dissolution of hydroxylapatite requires a liquid medium, and we investigate whether a UAFW system is solid or liquid over varied conditions, finding that this characteristic is controlled by the molar ratios of the three components. For liquid UAFW mixtures, we also find the solubility of phosphate is higher when the quantity of ammonium formate is greater than urea. We suggest the urea within the system can lower the activity of water, help create a stable and persistent solution, and may act as a condensing agent/catalyst to improve nucleoside phosphorylation yields.
Highlights
While ubiquitous in biology, phosphorus is a comparatively minor element in terrestrial rocks
We recently demonstrated that a semi-aqueous solvent consisting of urea, ammonium formate, and water (UAFW) supports the dissolution of phosphate and the phosphorylation of nucleosides
For liquid UAFW mixtures, we find the solubility of phosphate is higher when the quantity of ammonium formate is greater than urea
Summary
Phosphorus is a comparatively minor element in terrestrial rocks. In contrast to the other major elements of life—carbon, hydrogen, nitrogen, oxygen, and sulfur (CHNOS)—phosphorus does not have a major volatile phase on Earth. On the surface of Earth, phosphorus is a lithophile element associated with silicates. The redox conditions on the Earth’s surface favor the +5 oxidation state (Pasek 2019), and phosphorus primarily exists in mineral sources as phosphate (PO43 −). These phosphate minerals are the primary source of phosphorus for the phosphorus cycle on Earth (Föllmi 1996)
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