Abstract
In C(3) plants, CO(2) assimilation is limited by ribulose 1,5-bisphosphate (RuBP) regeneration rate at high CO(2). RuBP regeneration rate in turn is determined by either the chloroplast electron transport capacity to generate NADPH and ATP or the activity of Calvin cycle enzymes involved in regeneration of RuBP. Here, transgenic tobacco (Nicotiana tabacum 'W38') expressing an antisense gene directed at the transcript of either the Rieske iron-sulfur protein of the cytochrome (Cyt) b(6)/f complex or the δ-subunit of chloroplast ATP synthase have been used to investigate the effect of a reduction of these complexes on chloroplast electron transport rate (ETR). Reductions in δ-subunit of ATP synthase content did not alter chlorophyll, Cyt b(6)/f complex, or Rubisco content, but reduced ETR estimated either from measurements of chlorophyll fluorescence or CO(2) assimilation rates at high CO(2). Plants with low ATP synthase content exhibited higher nonphotochemical quenching and achieved higher ETR per ATP synthase than the wild type. The proportional increase in ETR per ATP synthase complex was greatest at 35°C, showing that the ATP synthase activity can vary in vivo. In comparison, there was no difference in the ETR per Cyt b(6)/f complex in plants with reduced Cyt b(6)/f content and the wild type. The ETR decreased more drastically with reductions in Cyt b(6)/f complex than ATP synthase content. This suggests that chloroplast ETR is more limited by Cyt b(6)/f than ATP synthase content and is a potential target for enhancing photosynthetic capacity in crops.
Highlights
In C3 plants, CO2 assimilation is limited by ribulose 1,5-bisphosphate (RuBP) regeneration rate at high CO2
We show that at high CO2 when the rate of RuBP regeneration limits CO2 assimilation, chloroplast electron transport rate (ETR) is more limited by Cyt b6/f than ATP synthase content and confirm that ATP synthase activity is modulated in vivo
It was previously shown that reduction in the ATP synthase (d) subunit led to a reduction in ATP synthase (Price et al, 1995) and that the reduction on Rieske FeS protein led to a reduction in the complete Cyt b6/f complex (Price et al, 1998).We assume that alterations in photosynthetic properties are primarily the result of the reduction in either ATP synthase or Cyt b6/f complex
Summary
In C3 plants, CO2 assimilation is limited by ribulose 1,5-bisphosphate (RuBP) regeneration rate at high CO2. Photosynthetic CO2 assimilation rate can be viewed as being limited either by the capacity of Rubisco to consume ribulose 1,5bisP (RuBP; at lower CO2) or by the capacity of the chloroplast electron transport to generate ATP and NADPH for RuBP regeneration (at higher CO2; Farquhar et al, 1980). Within this framework of limitations, significant uncertainties remain in our understanding of how electron transport and ATP synthesis are coordinated and affect electron transport capacity and photosynthesis (Baker et al, 2007).
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