2025-04-21 フランス国立科学研究センター(CNRS)
Photo of Nebula NGC 1333. The James Webb telescope detected interstellar ice there, which could be the origin of stars and planets. The study shows that this ice was apparently also behind the formation of organic molecules, including all intermediaries in the Krebs cycle. © ESA/Webb, NASA & CSA, A. Scholz, K. Muzic, A. Langeveld, R. Jayawardhana
<関連情報>
- https://www.cnrs.fr/en/press/chemical-basis-life-can-form-interstellar-ice
- https://www.pnas.org/doi/10.1073/pnas.2501839122
クエン酸サイクル中間体の生物学的起源 Abiotic origin of the citric acid cycle intermediates
Mason McAnally, Jana Bocková, Andrew M. Turner, +3 , and Ralf I. Kaiser
Proceedings of the National Academy of Sciences Published:April 21, 2025
DOI:https://doi.org/10.1073/pnas.2501839122
Significance
The chemistry of cold molecular clouds is remarkably rich in complex organic molecules. By replicating the conditions of ice-coated nanoparticles in these cold regions of space, laboratory simulation experiments provide compelling evidence on the synthesis of the complete set of organics of the citric acid cycle in interstellar analog ices exposed to ionizing radiation. These findings illustrate a plausible starting point for developing molecular precursors to life in deep space in conjunction with the incorporation of these building blocks into solar systems, as evidenced by Ryugu and Murchison, potentially laying the groundwork for metabolic evolution and the Origins of Life.
Abstract
The molecular framework for protometabolism—chemical reactions in a prebiotic environment preceding modern metabolism—has remained unknown in evolutionary biology. Mono-, di-, and tricarboxylic acids that comprise contemporary metabolism, such as the Krebs cycle, are of particular prebiotic relevance and are theorized to predate life on Earth. Researchers have struggled to unravel the molecular origins of respiration, with theories pointing toward abiotic origins later co-opted by the earliest living organisms; however, the molecular network of these molecules has remained elusive. Recent detections of carboxylic acids linked to the Krebs cycle on the Ryugu asteroid and Murchison meteorite rekindled interest in their extraterrestrial origins. Replicating conditions analogous to the environment of dense molecular clouds in laboratory simulation experiments, our work provides compelling evidence on the abiotic synthesis of the complete suite of biorelevant molecules central to the Krebs cycle. The opportunity for these biomolecules forming in deep space could provide molecular origins of protometabolism on early Earth and also provide the molecular feedstock to worlds beyond our own.
