Feedback regulation of 3-hydroxy-3-methylglutaryl coenzyme A reductase in Saccharomyces cerevisiae.

In eukaryotic cells all isoprenoids are synthesized from a common precursor, mevalonate. The formation of mevalonate from 3-hydroxy-3-methylglutaryl coenzyme A (HMG-CoA) is catalyzed by HMG-CoA reductase and is the first committed step in isoprenoid biosynthesis. In mammalian cells, synthesis of HMG-CoA reductase is subject to feedback regulation at multiple molecular levels. We examined the state of feedback regulation of the synthesis of the HMG-CoA reductase isozyme encoded by the yeast gene HMG1 to examine the generality of this regulatory pattern. In yeast, synthesis of Hmg1p was subject to feedback regulation. This regulation of HMG-CoA reductase synthesis was independent of any change in the level of HMG1 mRNA. Furthermore, regulation of Hmg1p synthesis was keyed to the level of a nonsterol product of the mevalonate pathway. Manipulations of endogenous levels of several isoprenoid intermediates, either pharmacologically or genetically, suggested that mevalonate levels may control the synthesis of Hmg1p through effects on translation.

Distinct cis-acting elements direct pistil-specific and pollen-specific activity of the Brassica S locus glycoprotein gene promoter.

The promoter of the S Locus Glycoprotein (SLG) gene of Brassica is a tightly regulated promoter that is active specifically in reproductive organs. In transgenic tobacco, this promoter is active exclusively in cells of the pistil and in pollen. We transformed tobacco with truncated versions of the SLG13 promoter fused to the beta-glucuronidase reporter gene. We show that the promoter has a modular organization and consists of separable DNA elements that independently specify pistil- and pollen-specific expression. A 196-bp region (-339 to -143) is sufficient to confer stigma and style specificity to the marker gene. Two distinct, but functionally redundant, domains (-415 to -291 and -117 to -8) allow specific expression of the gene in pollen. The functional domains identified within the SLG13 promoter contain sequence elements that are highly conserved in different alleles of the SLG gene and in the S Locus Related SLR1 gene.

Genetic Ablation of Floral Cells in Arabidopsis.

A chimeric toxic gene consisting of the diphtheria toxin A chain gene fused to a promoter previously shown to direct pistil- and anther-specific expression was used to genetically target cell killing in transgenic Arabidopsis. Flowers of Arabidopsis transformants that carried the toxic gene fusion had distinct structural defects. The papillar cells at the stigma surface were stunted and were biosynthetically inactive. Anther development was also impaired by toxic gene expression, leading to abnormalities in anther dehiscence, pollen morphology, and pollen germination. The combined defects of pistil and anther rendered transformants that carried the toxic gene fusion self-sterile. However, the transformants were cross-fertile with untransformed plants: the viable pollen of ablated plants was rescued by wild-type stigmas, and, strikingly, the ablated papillar cells allowed the growth of wild-type pollen.

Ablation of Papillar Cell Function in Brassica Flowers Results in the Loss of Stigma Receptivity to Pollination.

Plant reproduction in crucifers is dependent on interactions that occur at the stigma surface between the male gametophyte (pollen and pollen tube) and papillar cells. To dissect these complex interactions, papillar cells were genetically ablated by targeting the expression of a toxin to appropriate cells of the flower with a flower-specific and developmentally regulated promoter. In transgenic Brassica plants that expressed the toxic gene fusion, flower morphology was normal except for aberrant papillar cell development and partial pollen sterility. Microscopic, biochemical, and functional analyses, mainly focused on papillar cell responses, revealed that papillar cells lost their ability to elongate, to synthesize cell-specific proteins, and to support pollen germination after self- or cross-pollination. This loss of stigma receptivity to pollination was mimicked by treating pistils with protein phosphatase inhibitors. Differences in the effects of genetic and chemical ablation on the pollination responses of Brassica and Arabidopsis flowers are discussed and are ascribed in part to a requirement for phosphorylation/dephosphorylation events in Brassica but not in Arabidopsis.

Activity of an S Locus Gene Promoter in Pistils and Anthers of Transgenic Brassica.

The pollen-stigma interaction of self-incompatibility in crucifers is correlated with glycoproteins localized in the cell wall of the stigmatic papillae that are encoded by the S locus glycoprotein (SLG) gene. When fused to the [beta]-glucuronidase (GUS) reporter gene, the 5[prime] upstream regulatory region of SLG directed high level expression in the papillae of transgenic Brassica plants. Histochemical and fluorometric assays revealed that, in addition to its primary site of expression in the stigmatic papillae, the SLG-GUS fusion was also expressed in the transmitting tissue of stigma, style, and ovary, and in anthers. This conclusion was verified by the detection of transgene-encoded GUS transcripts and endogenous SLG-homologous transcripts by RNA gel blot analysis. Significantly, in anthers, the SLG promoter was active not only sporophytically in the nurse cells of the tapetum, but also in the haploid microspores. Because self-incompatibility systems exhibiting sporophytic control of pollen phenotype are thought to have evolved from systems with gametophytic control, we suggest that sporophytic control was acquired without loss of gametophytic function.

A Brassica S locus gene promoter directs sporophytic expression in the anther tapetum of transgenic Arabidopsis.

The S locus glycoprotein (SLG) gene of Brassica encodes stigmatic glycoproteins that are implicated in the pollen-stigma interaction of self-incompatibility. We have transformed the related plant Arabidopsis thaliana with a chimaeric gene consisting of the promoter region of an SLG gene fused to the reporter gene beta-glucuronidase (GUS). In transgenic plants the gene was expressed in two cell types of the flower. In stigmas, the timing and distribution of GUS activity was similar to that previously described for SLG expression in Brassica. In anthers, expression was detected at an earlier stage of flower development with GUS activity restricted to the tapetal cell layer. The novel finding of SLG-promoter activity in the anther supports the hypothesis that sporophytic control of self-incompatibility is a result of SLG-gene expression in the tapetum.

A Brassica S-locus gene promoter targets toxic gene expression and cell death to the pistil and pollen of transgenic Nicotiana.

The S-locus glycoprotein gene of Brassica is derived from the genetic locus that controls the self-incompatibility response and the specific recognition between pollen and stigma. The promoter of this gene was used to direct expression of the diphtheria toxin A chain gene and the Escherichia coli beta-glucuronidase gene in transgenic Nicotiana tabacum. Expression of the promoter in cells of the pistil and in pollen suggests that a single gene may direct the self-incompatibility response in the two interacting cell types. Additionally, the fusion genes were expressed gametophytically in the heterologous host species, Nicotiana, rather than sporophytically as expected for Brassica. Thus, although the genes involved in self-incompatibility in Brassica and Nicotiana are not homologous in their coding regions, signals for expression of these genes are apparently conserved between the two genera. Our analysis of toxic gene fusion transformants shows that genetic ablation is useful for probing developmental processes and for studying temporal and spatial patterns of gene expression in plants.