The possible evolution and future of CO2-concentrating mechanisms

Journal of Experimental Botany
John A RavenPatricia Sánchez-Baracaldo

Abstract

CO2-concentrating mechanisms (CCMs), based either on active transport of inorganic carbon (biophysical CCMs) or on biochemistry involving supplementary carbon fixation into C4 acids (C4 and CAM), play a major role in global primary productivity. However, the ubiquitous CO2-fixing enzyme in autotrophs, Rubisco, evolved at a time when atmospheric CO2 levels were very much higher than today and O2 was very low and, as CO2 and O2 approached (by no means monotonically), today's levels, at some time subsequently many organisms evolved a CCM that increased the supply of CO2 and decreased Rubisco oxygenase activity. Given that CO2 levels and other environmental factors have altered considerably between when autotrophs evolved and the present day, and are predicted to continue to change into the future, we here examine the drivers for, and possible timing of, evolution of CCMs. CCMs probably evolved when CO2 fell to 2-16 times the present atmospheric level, depending on Rubisco kinetics. We also assess the effects of other key environmental factors such as temperature and nutrient levels on CCM activity and examine the evidence for evolutionary changes in CCM activity and related cellular processes as well as limitations on continuity o...Continue Reading

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Citations

Sep 16, 2017·Journal of Experimental Botany·Howard GriffithsRosalind E M Rickaby
Aug 16, 2017·Proceedings of the National Academy of Sciences of the United States of America·Patricia Sánchez-BaracaldoAndrew H Knoll
Dec 20, 2017·Philosophical Transactions of the Royal Society of London. Series B, Biological Sciences·John A Raven
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