Can improved canopy light transmission ameliorate loss o photosynthetic efficiency in the shade? An investigation of natural variation in Sorghum bicolor

Previous studies have found that maximum quantum yield of CO2 assimilation (Phi(CO2,max,app)) declines in lower canopies of maize and miscanthus, a maladaptive response to self-shading. These observations were limited to single genotypes, leaving it unclear whether the maladaptive shade response is a general property of this C-4 grass tribe, the Andropogoneae. We explored the generality of this maladaptation by testing the hypothesis that erect leaf forms (erectophiles), which allow more light into the lower canopy, suffer less of a decline in photosynthetic efficiency than drooping leaf (planophile) forms. On average, Phi(CO2,max,app) declined 27% in lower canopy leaves across 35 accessions, but the decline was over twice as great in planophiles than in erectophiles. The loss of photosynthetic efficiency involved a decoupling between electron transport and assimilation. This was not associated with increased bundle sheath leakage, based on C-13 measurements. In both planophiles and erectophiles, shaded leaves had greater leaf absorptivity and lower activities of key C-4 enzymes than sun leaves. The erectophile form is considered more productive because it allows a more effective distribution of light through the canopy to support photosynthesis. We show that in sorghum, it provides a second benefit, maintenance of higher Phi(CO2,max,app) to support efficient use of that light resource.

Automated summary

In a study of 35 accessions, it was found that the maximum quantum yield of CO2 assimilation declined in lower canopy leaves, with planophile forms experiencing a greater decline than erectophile forms. This decline was associated with a decoupling between electron transport and assimilation, and not with increased bundle sheath leakage. Shaded leaves in both planophiles and erectophiles had higher leaf absorptivity and lower activities of key C-4 enzymes compared to sun leaves.