Abstract

Most physiology comparisons of C3 and C4 plants are made under current or elevated concentrations of atmospheric CO2 which do not reflect the low CO2 environment under which C4 photosynthesis has evolved. Accordingly, photosynthetic nitrogen (PNUE) and water (PWUE) use efficiency, and the activity of the photosynthetic carboxylases [Rubisco and phosphoenolpyruvate carboxylase (PEPC)] and decarboxylases [NADP-malic enzyme (NADP-ME) and phosphoenolpyruvate carboxykinase (PEP-CK)] were compared in eight C4 grasses with NAD-ME, PCK, and NADP-ME subtypes, one C3 grass, and one C3-C4 grass grown under ambient (400 μl l(-1)) and glacial (180 μl l(-1)) CO2. Glacial CO2 caused a smaller reduction of photosynthesis and a greater increase of stomatal conductance in C4 relative to C3 and C3-C4 species. Panicum bisulcatum (C3) acclimated to glacial [CO2] by doubling Rubisco activity, while Rubisco was unchanged in Panicum milioides (C3-C4), possibly due to its high leaf N and Rubisco contents. Glacial CO2 up-regulated Rubisco and PEPC activities in concert for several C4 grasses, while NADP-ME and PEP-CK activities were unchanged, reflecting the high control exerted by the carboxylases relative to the decarboxylases on the efficiency of C4 metabolism. Despite having larger stomatal conductance at glacial CO2, C4 species maintained greater PWUE and PNUE relative to C3-C4 and C3 species due to higher photosynthetic rates. Relative to other C4 subtypes, NAD-ME and PEP-CK grasses had the highest PWUE and PNUE, respectively; relative to C3, the C3-C4 grass had higher PWUE and similar PNUE at glacial CO2. Biomass accumulation was reduced by glacial CO2 in the C3 grass relative to the C3-C4 grass, while biomass was less reduced in NAD-ME grasses compared with NADP-ME and PCK grasses. Under glacial CO2, high resource use efficiency offers a key evolutionary advantage for the transition from C3 to C4 photosynthesis in water- and nutrient-limited environments.

Highlights

  • The decline in atmospheric CO2 concentration ([CO2]) in the late Oligocene (30 million years ago) is considered to be the primary driver for the evolution of the C4 photosynthetic pathway (Christin et al, 2008; Ehleringer et al, 1997; Sage et al, 2012)

  • Photosynthetic nitrogen (PNUE) and water (PWUE) use efficiency, and the activity of the photosynthetic carboxylases [Rubisco and phosphoenolpyruvate carboxylase (PEPC)] and decarboxylases [NADP-malic enzyme (NADP-ME) and phosphoenolpyruvate carboxykinase (PEP-CK)] were compared in eight C4 grasses with NAD-malic enzyme (NAD-ME), PCK, and NADP-ME subtypes, one C3–C4 species. Panicum bisulcatum (C3) grass, and one C3–C4 grass grown under ambient (400 μl l–1) and glacial (180 μl l–1) CO2

  • Biomass accumulation was reduced by glacial CO2 in the C3 grass relative to the C3–C4 grass, while biomass was less reduced in NAD-ME grasses compared with NADP-ME and PCK grasses

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Summary

Introduction

The decline in atmospheric CO2 concentration ([CO2]) in the late Oligocene (30 million years ago) is considered to be the primary driver for the evolution of the C4 photosynthetic pathway (Christin et al, 2008; Ehleringer et al, 1997; Sage et al, 2012). Low [CO2] promotes high rates of photorespiration and reduces the carboxylation efficiency of C3 photosynthesis. The key feature of C4 photosynthesis is the operation of a CO2-concentrating mechanism (CCM) which suppresses photorespiration by raising [CO2] around Rubisco (ribulose1,5-bisphosphate carboxylase/oxygenase). During C4 photosynthesis, phosphoenolpyruvate carboxylase (PEPC) catalyses the initial carboxylation of CO2 into organic C4 acids in the mesophyll. Decarboxylation of C4 acids in the bundle sheath releases CO2 for refixation by Rubisco (Hatch, 1987). The C4 photosynthetic pathway is classified into three biochemical

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