Response of light-grown wild-type and aurea-mutant tomato plants to end-of-day far-red light

Abstract

The effect of end-of-day (EOD) far-red (FR) light treatment on tomato ( Lycopersicon esculentum Mill.) plants of the wild type (WT) and an aurea ( au) mutant (which is deficient in the spectrophotometrically detectable light-labile phytochrome pool in etiolated seedlings) was studied. Both the WT and au mutant exhibit a quantitatively similar EOD-FR response ( i.e. stimulation of elongation growth) indicating that phytochrome is functional in light-grown seedlings of the au mutant. However, no dramatic effects of EOD-FR light on leaf elongation, chlorophyll, carotenoid and soluble protein levels were observed in either the WT or au mutant. The au mutant contained less chlorophyll and more soluble protein per unit fresh weight than the WT. Although practically no anthocyanin could be detected in leaves of the au mutant, the WT showed a tenfold reduction in anthocyanin in response to EOD-FR light. The lower productivity of the au mutant compared with the WT results from its reduced leaf surface area, since its maximum rate of photosynthesis or photosynthetic efficiency appears to be slightly higher than that of the WT. Phytochrome was extracted and partially purified from light-grown plants of the WT and au mutant and was quantified by spectrophotometry. On a fresh weight basis the phytochrome content of au-mutant plants was 66% of that of WT plants. It is proposed that the light-labile phytochrome pool regulates the synthesis of the photosynthetic apparatus in light-grown plants and that the light-stable phytochrome pool functions in the EOD-FR elongation response, the latter pool being present and functional in the au mutant.