Glutathione S -transferases (GSTs) traditionally have been studied in plants and other organisms for their ability to detoxify chemically diverse herbicides and other toxic organic compounds. Anthocyanins are among the few endogenous substrates of plant GSTs that have been identified. The Bronze2 ( Bz2 ) gene encodes a type III GST and performs the last genetically defined step of the maize anthocyanin pigment pathway. This step is the conjugation of glutathione to cyanidin 3-glucoside (C3G). Glutathionated C3G is transported to the vacuole via a tonoplast Mg-ATP-requiring glutathione pump (GS-X pump). Genetically, the comparable step in the petunia anthocyanin pathway is controlled by the Anthocyanin9 ( An9 ) gene. An9 was cloned by transposon tagging and found to encode a type I plant GST. Bz2 and An9 have evolved independently from distinct types of GSTs, but each is regulated by the conserved transcriptional activators of the anthocyanin pathway. Here, a phylogenetic analysis is presented, with special consideration given to the origin of these genes and their relaxed substrate requirements. In particle bombardment tests, An9 and Bz2 functionally complement both mutants. Among several other GSTs tested, only soybean GmGST26A (previously called GmHsp26A and GH2 / 4 ) and maize GSTIII were found to confer vacuolar sequestration of anthocyanin. Previously, these genes had not been associated with the anthocyanin pathway. Requirements for An9 and Bz2 gene function were investigated by sequencing functional and nonfunctional germinal revertants of an9-T3529 , bz2::Ds , and bz2::Mu1.
INTRODUCTIONGlutathione S -transferases (GSTs; EC 2.5.1.18) conjugate the glutathione tripeptide ( ␥ -Glu-Cys-Gly; GSH) to a broad variety of substrates. They are an ancient and ubiquitous gene family encoding ف 25-to 29-kD proteins that form both homodimers and heterodimers in vivo. GSTs are as plentiful as they are diverse. As a group, maize GSTs are among the most abundant nonphotosynthetic enzymes in plant cells, making up as much as 1% of the soluble leaf protein (SariGorla et al., 1993). At least 38 plant GSTs have been identified (Marrs, 1996), and a search of the Arabidopsis expressed sequence tag (EST) database identifies Ͼ 200 distinct ESTs with substantial homology to GSTs. It is striking that the GST family is so highly divergent; only a motif of ف 15 amino acids is moderately conserved in sequence and position among all plant GSTs (Marrs, 1996).Mammalian GST genes are divided into five groups ( ␣ , , , , and ) based on sequence similarities, immunological cross-reactivity, and substrate specificity. All identified plant GSTs fall into the most ancient class, that of theta. Droog et al. (1995) recently proposed three subdivisions of plant GSTs-type I, type II, and type III-based on a combination of sequence conservation, immunological cross-reactivity, and intron/exon structure of the gene. Type I GSTs have two introns, and many are induced, both transcriptionally and translationally, by environmental perturbations, ...
