Prediction of the Maximum Temperature for Life Based on the Stability of Metabolites to Decomposition in Water

Author(s)

Bains, William; Xiao, Yao; Yu, Changyong

Abstract

The components of life must survive in a cell long enough to perform their function in that cell. Because the rate of attack by water increases with temperature, we can, in principle, predict a maximum temperature above which an active terrestrial metabolism cannot function by analysis of the decomposition rates of the components of life, and comparison of those rates with the metabolites’ minimum metabolic half-lives. The present study is a first step in this direction, providing an analytical framework and method, and analyzing the stability of 63 small molecule metabolites based on literature data. Assuming that attack by water follows a first order rate equation, we extracted decomposition rate constants from literature data and estimated their statistical reliability. The resulting rate equations were then used to give a measure of confidence in the half-life of the metabolite concerned at different temperatures. There is little reliable data on metabolite decomposition or hydrolysis rates in the literature, the data is mostly confined to a small number of classes of chemicals, and the data available are sometimes mutually contradictory because of varying reaction conditions. However, a preliminary analysis suggests that terrestrial biochemistry is limited to environments below ~150–180 °C. We comment briefly on why pressure is likely to have a small effect on this.

Date issued

2015-03

URI

http://hdl.handle.net/1721.1/98186

Department

Massachusetts Institute of Technology. Department of Earth, Atmospheric, and Planetary Sciences

Journal

Life

Publisher

MDPI AG

Citation

Bains, William, Yao Xiao, and Changyong Yu. “Prediction of the Maximum Temperature for Life Based on the Stability of Metabolites to Decomposition in Water.” Life 5, no. 2 (March 26, 2015): 1054–1100.

Version: Final published version

ISSN

2075-1729