The Evolutionary Origin of C4 Photosynthesis in the Grass Subtribe Neurachninae.

The Australian grass subtribe Neurachninae contains closely related species that use C3, C4, and C2 photosynthesis. To gain insight into the evolution of C4 photosynthesis in grasses, we examined leaf gas exchange, anatomy and ultrastructure, and tissue localization of Gly decarboxylase subunit P (GLDP) in nine Neurachninae species. We identified previously unrecognized variation in leaf structure and physiology within Neurachne that represents varying degrees of C3-C4 intermediacy in the Neurachninae. These include inverse correlations between the apparent photosynthetic carbon dioxide (CO2) compensation point in the absence of day respiration (C * ) and chloroplast and mitochondrial investment in the mestome sheath (MS), where CO2 is concentrated in C2 and C4 Neurachne species; width of the MS cells; frequency of plasmodesmata in the MS cell walls adjoining the parenchymatous bundle sheath; and the proportion of leaf GLDP invested in the MS tissue. Less than 12% of the leaf GLDP was allocated to the MS of completely C3 Neurachninae species with C * values of 56-61 µmol mol-1, whereas two-thirds of leaf GLDP was in the MS of Neurachne lanigera, which exhibits a newly-identified, partial C2 phenotype with C * of 44 µmol mol-1 Increased investment of GLDP in MS tissue of the C2 species was attributed to more MS mitochondria and less GLDP in mesophyll mitochondria. These results are consistent with a model where C4 evolution in Neurachninae initially occurred via an increase in organelle and GLDP content in MS cells, which generated a sink for photorespired CO2 in MS tissues.

Survival and exopolysaccharide production in Sinorhizobium meliloti WSM419 are affected by calcium and low pH.

Cells of Sinorhizobium meliloti WSM419 showed an adaptive acid-tolerance response when grown at pH 5.8 instead of pH 7.0. Increasing concentrations of calcium in the exposure medium significantly decreased the death rate of WSM419 cells under conditions of acid stress (pH 4.0). The effect of calcium on survival at pH 4.0 however, appears unconnected to exopolysaccharide (EPS), since a strain with a mutation in exoY (Rm0540) responded to calcium in the exposure medium in the same way as its wild-type parent (Rm2011). The concentration of calcium in the growth medium also affected subsequent survival at pH 4.0, and the effect varied with pH. In cells grown at pH 5.8, higher calcium concentrations also markedly increased the rate of synthesis of EPS; this was not seen in cells grown at pH 7.0. 1H NMR spectra for isolated EPS from WSM419 cultures grown at pH 5.8 and pH 7.0 showed that low pH markedly lowered the degree of substitution with acetyl and pyruvyl groups, but not the degree of substitution with succinyl groups; calcium concentration did not affect the pattern of substitution at either pH. For EPS to be involved in the effect of calcium concentration in the growth medium on survival would imply a deleterious effect of the EPS produced at low pH.