Abstract
Phosphorus, as phosphate, plays a paramount role in biology. Since phosphate transfer reactions are an integral part of contemporary life, phosphate may have been incorporated into the initial molecules at the very beginning. To facilitate the studies into early phosphate utilization, we should look retrospectively to phosphate-rich molecules present in today’s cells. Overlooked by origin of life studies until now, inositol and the inositol phosphates, of which some species possess more phosphate groups that carbon atoms, represent ideal molecules to consider in this context. The current sophisticated association of inositol with phosphate, and the roles that some inositol phosphates play in regulating cellular phosphate homeostasis, intriguingly suggest that inositol might have played some role in the prebiotic process of phosphate exploitation. Inositol can be synthesized abiotically and, unlike glucose or ribose, is chemically stable. This stability makes inositol the ideal candidate for the earliest organophosphate molecules, as primitive inositol phosphates. I also present arguments suggesting roles for some inositol phosphates in early chemical evolution events. Finally, the possible prebiotic synthesis of inositol pyrophosphates could have generated high-energy molecules to be utilized in primitive trans-phosphorylating processes.
Highlights
The element phosphorus, in its phosphate form (PO4 −3 ), plays a paramount role in biology.Phosphate’s negative charges at physiological pH, its tetrahedral molecular geometry, and its ability to coordinate hydrogen bonds through its oxygen groups are characteristics that have made this molecule essential in living organisms
Inositol pyrophosphates are evolutionarily ancient speculation that their ability to control phosphate homeostasis represents the original/initial function molecules: the enzymes for synthesising them are omnipresent in eukaryote genomes [39,40]
Much of the attention in origin of life research has been given to RNA and DNA: their prebiotic synthesis, condensation, and replication, and to their ability to initiate some kind of enzymology in the RNA world [85]
Summary
The element phosphorus, in its phosphate form (PO4 −3 ), plays a paramount role in biology. Magnesium is often the essential cofactor in today’s cellular biochemical processes involving phosphate groups [10] This suggests that we should look closely at several aspects of current phosphate biology: knowing how phosphate homeostasis is managed could give insights into prebiotic phosphate exploitation. Another abundant bivalent cation present in early Earth’s oceans was calcium. Phosphate and calcium homeostasis in today’s eukaryotic cells are regulated by different members of the same class of molecules, the inositol phosphates [13,14] This leads to the question: can the biology of inositol phosphates give insight into the prebiotic processes of phosphate exploitation?
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