Regulation and Manipulation of Flavonoid Gene Expression in Anthers of Petunia: the Molecular Basis of the Po Mutation

Overview

Journal Plant Cell

Publisher Oxford University Press

Specialties Biology
Cell Biology

Date 1991 Jan 1

PMID 1824333

Citations 24

Authors

A J van Tunen

L A Mur

K Recourt

A G Gerats

J N Mol

Affiliations

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Abstract

Molecular mechanisms governing development of the male reproductive organs of flowers, the anthers, are largely unknown. In this article, we report on the investigation of the molecular basis of a mutation involving the expression of a gene encoding the flavonoid biosynthesis enzyme chalcone flavanone isomerase (CHI) in anthers of petunia. In petunia, the gene Po regulates the expression of CHI in anthers: PoPo petunia lines contain CHI enzyme activity in petals and anthers, whereas popo lines contain the CHI enzyme only in petals but not in anthers. As a result of the Po mutation, the substrate of CHI accumulates and therefore the pollen of a popo line are yellow or greenish. The genome of petunia contains two chi genes, chiA and chiB. In a restriction fragment length polymorphism analysis, a 100% linkage was observed between Po and chiA. This result suggested that Po is identical to chiA and that Po is not a regulatory gene of chiA. Introduction of a chiA gene isolated from a PoPo line into a popo line resulted in a complementation of the mutation that was directly visible because the pollen color shifted from yellow to white. This proved that chiA and Po are identical. Because chiA encodes a functional CHI enzyme in flower petals of a popo line, we propose that the Po mutation is a mutation in the regulatory region of chiA abolishing chiA promoter activity in anthers but not in corollas. This change in anther color is a fine illustration of how floral pigmentation can be manipulated in a predictable way and suggests the use of CHI as a visible marker.

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