White and green rust chimneys accumulate RNA in a ferruginous chemical garden

TL;DR

This study demonstrates that ferruginous chemical gardens, specifically white and green rust chimneys, can rapidly accumulate RNA from dilute solutions, providing a new mechanism for prebiotic nucleic acid concentration on early Earth.

Contribution

It introduces a novel geochemical mechanism where rust chimneys sequester RNA, expanding understanding of prebiotic nucleic acid accumulation beyond wet-dry cycles.

Findings

RNA binds to Fe2+ ions in ferruginous solutions.

RNA accumulates in rust chimney structures during formation.

Rust chimneys could have promoted RNA survival in early Earth's oceans.

Abstract

Mechanisms of nucleic acid accumulation were likely critical to the emergence of life in the ferruginous oceans of the early Earth. How exactly prebiotic geological settings accumulated nucleic acids from dilute aqueous solutions, is poorly understood. As a possible solution to this concentration problem, we simulated the conditions of prebiotic low-temperature alkaline hydrothermal vents in co-precipitation experiments to investigate the potential of ferruginous chemical gardens to accumulate nucleic acids via sorption. The injection of an alkaline solution into an artificial ferruginous solution under anoxic conditions (O2 <0.01% of present atmospheric levels) and at ambient temperatures, caused the precipitation of amakinite (white rust), which quickly converted to chloride-containing fougerite (green rust). RNA was only extractable from the ferruginous solution in the presence of a phosphate buffer, suggesting RNA in solution was bound to Fe2+ ions. During chimney formation, this iron-bound RNA rapidly accumulated in the white and green rust chimney structure, as it was depleted from the surrounding solution. Our findings reveal that in the oceans of the early Earth, white and green rust chimneys were likely key geochemical features that can rapidly sequester and accumulate RNA. This represents a new mechanism for nucleic acid accumulation, in addition to wet dry cycles, and may have promoted RNA survival in a dilute prebiotic ocean.