Abstract
Mature seeds of both the high-starch starch-excess1 (sex1) mutant and the almost starchless phosphoglucomutase1 mutant of Arabidopsis (Arabidopsis thaliana) have 30% to 40% less lipid than seeds of wild-type plants. We show that this is a maternal effect and is not attributable to the defects in starch metabolism in the embryo itself. Low lipid contents and consequent slow postgerminative growth are seen only in mutant embryos that develop on maternal plants with mutant phenotypes. Mutant embryos that develop on plants with wild-type starch metabolism have wild-type lipid contents and postgerminative growth. The maternal effect on seed lipid content is attributable to carbohydrate starvation in the mutant fruit at night. Fruits on sex1 plants grow more slowly than those on wild-type plants, particularly at night, and have low sugars and elevated expression of starvation genes at night. Transcript levels of the transcription factor WRINKLED1, implicated in lipid synthesis, are reduced at night in sex1 but not in wild-type seeds, and so are transcript levels of key enzymes of glycolysis and fatty acid synthesis. sex1 embryos develop more slowly than wild-type embryos. We conclude that the reduced capacity of mutant plants to convert starch to sugars in leaves at night results in low nighttime carbohydrate availability in the developing fruit. This in turn reduces the rate of development and expression of genes encoding enzymes of storage product accumulation in the embryo. Thus, the supply of carbohydrate from the maternal plant to the developing fruit at night can have an important influence on oilseed composition and on postgerminative growth.
Highlights
Developing embryos of Arabidopsis thaliana and oilseed rape (Brassica napus), initially accumulate starch, but starch levels decline as the rates of storage lipid and protein synthesis increase (Hills, 2004; Andriotis et al, 2010c)
Starch accumulation in embryos of both Arabidopsis and oilseed rape is small compared with the final lipid content of the seed, at the point of maximum starch content this reserve constitutes a significant fraction of embryo weight and represents a major fate for carbon entering the embryo (Kang and Rawsthorne, 1994; Eastmond and Rawsthorne, 2000; Andriotis et al, 2010c)
To provide independent information about the relationship between availability of carbohydrate at night and seed lipid content, we examined seed lipid in gsl7 mutant plants in which carbohydrate supply to the inflorescence is restricted by impaired phloem transport rather than by defects in maternal starch metabolism
Summary
Developing embryos of Arabidopsis thaliana and oilseed rape (Brassica napus), initially accumulate starch, but starch levels decline as the rates of storage lipid and protein synthesis increase (Hills, 2004; Andriotis et al, 2010c). Starch accumulation in embryos of both Arabidopsis and oilseed rape is small compared with the final lipid content of the seed, at the point of maximum starch content this reserve constitutes a significant fraction of embryo weight and represents a major fate for carbon entering the embryo (Kang and Rawsthorne, 1994; Eastmond and Rawsthorne, 2000; Andriotis et al, 2010c). Mature seeds of the almost starchless mutant pgm (lacking plastidial phosphoglucomutase) contain up to 40% less lipid than wild-type seeds (Periappuram et al, 2000). Mature seeds of the starch-degradation mutant sex (lacking glucan, water dikinase GWD1; Yu et al, 2001) have ten times more starch than wild-type seeds, and about 30% less lipid (Andriotis et al, 2010c)
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