The effect of the le mutation on the growth and gibberellin (GA) content of developing fruits was investigated using the near-isogenic lines of Pisum sativum L. 205+ (LeLe) and 205- (lele). Although stem elongation is known to be reduced in 205- plants by approximately 65%, the growth of pods and seeds was unaffected by the le mutation. GA1, GA3, and GA20 stimulated parthenocarpic development of unpollinated ovaries on both 205+ and 205- plants. GA20 was less active on 205- ovaries than on 205+, whereas GA1 had similar, high activity in both lines. The activity of GA3 was even higher than that of GA1 in both lines. Decapitation of 205+ plants induced parthenocarpic development of unpollinated ovaries, but this treatment was much less effective on 205- plants. The contents of GA1 and GA8 in entire ovaries 6 d after anthesis, as well as in the pod and fertilized ovules, were substantially lower in 205- than in 205+ plants, whereas the reverse was true for the levels of GA20 and GA29. These results suggest that 3[beta]-hydroxylation of GA20 to GA1 is reduced in ovaries as well as in vegetative tissues. Thus, the le mutation appears to be expressed in young reproductive organs of the 205- line, even though it does not affect the fruit phenotype. Because the content of GA3 in the ovary was similar in the two lines, one explanation for the normal fruit size in the 205- line is that GA3 is the native regulator of pod growth. Alternatively, sufficient GA1 may still be produced in 205- fruits to maintain normal pod growth.
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