Transgenic modification of germline and somatic cells: examples from animals and plants - Gene regulation of flowering

A major change in the development of plants occurs upon floral induction. Meristems in certain positions become organized to form flowers. We are studying this process using a combination of genetic, molecular and physiological approaches in Antirrhinum. In particular, we are exploiting transposon-i...

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Published in:Philosophical transactions of the Royal Society of London. Series B. Biological sciences 1993-02, Vol.339 (1288), p.193-197
Main Authors: Bradley, D., Carpenter, R., Elliott, R., Simon, R., Romero, J., Hantke, S., Doyle, S., Mooney, M., Luo, D., McSteen, P., Copsey, L., Robinson, C., Coen, E.
Format: Article
Language:English
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Summary:A major change in the development of plants occurs upon floral induction. Meristems in certain positions become organized to form flowers. We are studying this process using a combination of genetic, molecular and physiological approaches in Antirrhinum. In particular, we are exploiting transposon-induced mutations in genes controlling early switches in floral development. These mutations cause homeotic and heterochronic phenotypes and three categories of genes have been identified. The first includes floricaula (flo), which is required to switch inflorescence meristems to a floral state. This gene has been isolated and shown to be expressed transiently in bract, sepal, petal and carpel primordia. The second group of genes controls the identity (and sometimes the number) of organs in a whorl. These genes affect overlapping whorls and their mutant phenotypes suggest a co binatorial model for gene action in determining the fate of floral primordia. Some of the regulatory interactions between these genes have been revealed by studying cis-or trans-acting mutations which have resulted in ectopic gene expression. Genes of the third category determine the identity of organs within one whorl and thus affect the symmetry of the flower. We propose that the interactions of these homeotic genes control the basic patterns of inflorescence and flower development not only in Antirrhinum, but also in a diverse range of plant species.
ISSN:0962-8436
1471-2970
DOI:10.1098/rstb.1993.0016