Atmospheric CO2 Decline and the Timing of CAM Plant Evolution

Overview

Journal Ann Bot

Publisher Oxford University Press

Specialty Biology

Date 2023 Aug 29

PMID 37642245

Authors

Rowan F Sage

Ian S Gilman

J Andrew C Smith

Katia Silvera

Erika J Edwards

Affiliations

Soon will be listed here.

Abstract

Background And Aims: CAM photosynthesis is hypothesized to have evolved in atmospheres of low CO2 concentration in recent geological time because of its ability to concentrate CO2 around Rubisco and boost water use efficiency relative to C3 photosynthesis. We assess this hypothesis by compiling estimates of when CAM clades arose using phylogenetic chronograms for 73 CAM clades. We further consider evidence of how atmospheric CO2 affects CAM relative to C3 photosynthesis.

Results: Where CAM origins can be inferred, strong CAM is estimated to have appeared in the past 30 million years in 46 of 48 examined clades, after atmospheric CO2 had declined from high (near 800 ppm) to lower (<450 ppm) values. In turn, 21 of 25 clades containing CAM species (but where CAM origins are less certain) also arose in the past 30 million years. In these clades, CAM is probably younger than the clade origin. We found evidence for repeated weak CAM evolution during the higher CO2 conditions before 30 million years ago, and possible strong CAM origins in the Crassulaceae during the Cretaceous period prior to atmospheric CO2 decline. Most CAM-specific clades arose in the past 15 million years, in a similar pattern observed for origins of C4 clades.

Conclusions: The evidence indicates strong CAM repeatedly evolved in reduced CO2 conditions of the past 30 million years. Weaker CAM can pre-date low CO2 and, in the Crassulaceae, strong CAM may also have arisen in water-limited microsites under relatively high CO2. Experimental evidence from extant CAM species demonstrates that elevated CO2 reduces the importance of nocturnal CO2 fixation by increasing the contribution of C3 photosynthesis to daily carbon gain. Thus, the advantage of strong CAM would be reduced in high CO2, such that its evolution appears less likely and restricted to more extreme environments than possible in low CO2.

Citing Articles

Crassulacean acid metabolism (CAM) at the crossroads: a special issue to honour 50 years of CAM research by Klaus Winter.

Sage R, Edwards E, Heyduk K, Cushman J Ann Bot. 2023; 132(4):553-561.

PMID: 37856823 PMC: 10799977. DOI: 10.1093/aob/mcad160.

Prospects and perspectives: inferring physiological and regulatory targets for CAM from molecular and modelling approaches.

Chomthong M, Griffiths H Ann Bot. 2023; 132(4):583-596.

PMID: 37742290 PMC: 10799989. DOI: 10.1093/aob/mcad142.

The CAM lineages of planet Earth.

Gilman I, Smith J, Holtum J, Sage R, Silvera K, Winter K Ann Bot. 2023; 132(4):627-654.

PMID: 37698538 PMC: 10799995. DOI: 10.1093/aob/mcad135.

CAM photosynthesis in Bulnesia retama (Zygophyllaceae), a non-succulent desert shrub from South America.

Mok D, Leung A, Searles P, Sage T, Sage R Ann Bot. 2023; 132(4):655-670.

PMID: 37625031 PMC: 10799978. DOI: 10.1093/aob/mcad114.

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