Gibberellins and pea seed development

The gibberellin (GA)-biosynthesis mutations, lh ⁱ , ls and Ie ⁵⁸³⁹ have been used to investigate the role(s) of the GAs in seed development of the garden pea (Pisum sativum L.). Seeds homozygous for lh ⁱ possess reduced GA levels, are more likely to abort during development, and weigh less at harvest, compared with wild-type seeds due to expression of the lh ⁱ mutation in the embryo and/ or endosperm. Compared with wild-type seeds, the lh ⁱ mutation reduces endogenous GA₁ and gibberellic acid (GA₃) levels in the embryo/endosperm a few days after anthesis and fertilizing lh ⁱ plants with wild-type pollen dramatically increases GA₁ and GA₃ levels in the embryo/ endosperm and restores normal seed development. By contrast, the ls and le ⁵⁸³⁹ mutations do not appear to reduce GA levels in the embryo/endosperm of seeds a few days after anthesis, and do not affect embryo or endosperm development. However, both the ls and lh ⁱ mutations substantially reduce endogenous GA levels in embryos at contact point (the first day the liquid endosperm disappears). Levels of GAs in seeds from crosses involving the ls and lh ⁱ mutations suggest that GAs are synthesised in both the embryo/endosperm and testa and that the expression of ls depends on the tissue and developmental stage examined. These results suggest that GAs (possibly GA₁ and/or GA₃) play an important role early in pea seed development by regulating the development of the embryo and/or endosperm. By contrast, the high GA levels found in wild-type seeds at contact point (and beyond) do not appear to have a physiological role in seed development.Abbreviations GA_n gibberellin A_n - DAA days after anthesis - WT wild-type We thank Noel Davies, Katherine McPherson and Peter Bobbi for technical assistance, Professor L. Mander (ANU, Canberra) for dideuterated GA standards, and the Australian Research Council and Frontier Research Program, The Institute of Physical and Chemical Research (RIKEN, Japan), for financial support.