Membrane Domain of Plant 3-Hydroxy-3-Methylglutaryl Coenzyme A Reductase: Targeting, Topology, and Function

Denbow, Cynthia J.

06 May 1997

The rate limiting step in isoprenoid biosynthesis is catalyzed by 3-hydroxy-3-methylglutaryl CoA reductase (HMGR, EC 1.1.1.34). In plants, HMGR is encoded by small gene families whose members are differentially expressed. In tomato, hmg2 was previously isolated and sequenced. We report the isolation and sequence analysis of a clone (pCD4) encompassing exon I of tomato hmg1 which encodes the putative membrane domain. Sequence comparisons of plant HMGR proteins reveal two hydrophobic stretches within the amino terminus which are highly conserved among species. Using in vitro transcription and translation systems, the membrane domain structure of two tomato HMGR isoforms, HMG1 and HMG2, were analyzed. Results from these experiments reveal that tomato HMGRs are targeted to microsomal membranes in a cotranslational fashion that does not involve cleavage of an N-terminal targeting peptide. Membrane topography of HMGR was revealed by protease protection studies, indicating that both tomato HMGRs span the membrane two times such that both the C- and N-termini are located within the cytosol. HMG2 but not HMG1 was glycosylated in the in vitro system. Deletion of the hmg1 5' untranslated regions and sequences encoding the first six highly charged amino acids resulted in inefficient translation in vitro. However, targeting to microsomes was unchanged. HMG1 membrane domain was tagged with a FLAG epitope to facilitate in vivo studies. Agrobacterium-mediated transformation was used to introduce the tagged hmg1 gene into two Nicotiana tabacum cell lines, BY-2 and KY-14. The slow growth kinetics of KY-14 prevented effective recovery of transformed lines, however, Northern analyses of BY-2 showed that the hmg1 transgene was expressed. Comparisons of BY-2 and KY-14 revealed differences in defense responses to elicitor treatment. BY-2 cells showed minimal defense capabilities, whereas KY-14 cells were rapidly induced as indicated by increased HMGR enzyme activity and browning of the cells. HMGR enzyme activity was decreased in both KY-14 and BY-2 cells following sterol treatment, but the reduction was more pronounced in KY-14 cells. Thus transgenic BY-2 cells may be useful in future in vivo immunolocalization studies, but analyses of HMGR transcriptional regulation and regulated degradation will require use of the more responsive KY-14 cells.. / Ph. D.

protein degradation

membrane topology

protein targeting

tomato HMGR

epitope-tag

transgenic cells

Functional analyses of tomato 3-hydroxy-3-methylglutaryl coenzyme a reductase (HMGR) genes in transgenic plants engineered for altered HMGR expression

Yu, Xueshu

06 June 2008

3-Hydroxy-3-methylglutaryl CoA reductase (HMGR, EC 1.1.1.34) mediates the first regulatory step (HMG-CoA reduction to mevalonate) in isoprenoid biosynthesis. The tomato genome contains at least four differentially regulated hmg isogenes encoding HMGR. Functions of tomato hmg2 in defense responses were studied by promoter analyses of hmg2:GUS gene fusions, overexpression of hmg2 cDNA, and antisense inhibition of hmg1 and hmg2 in transgenic plants. Activity of the hmg2 promoter is developmentally regulated showing expression in seedling cotyledons and hypocotyls, in trichomes, and in reproductive tissues including pollen, stigmas, ovules, petals and mature seeds. hmg2:GUS activity is rapidly induced by wounding or in response to pathogenic viruses or bacteria. hmg2:GUS expression is localized to tissue surrounding lesions generated through interactions with either TMV or the bacterial pathogen, Erwinia carotovora subsp. carotovora (Ecc). Tomato hmg2 cDNA was cloned by PCR, expressed in E. coli to confirm its HMGR activity, inserted behind the double enhanced CaMV 35S promoter, and engineered into tobacco. Southern and northern analyses confirmed transformation and message expression. Enzyme activity was enhanced compared to nontransformed plants. Selected transgenic plants were significantly reduced for Ecc tissue maceration. The size of necrotic lesions induced by TMV was also significantly reduced compared to the nontransformed or vector controls. Thus, genetic manipulation of the rate-limiting step in a major defense pathway provides a novel strategy for enhancing disease resistance. We also generated transgenic tobacco and tomato containing antisense constructs for tomato hmg1 and hmg2 to study their effect on disease resistance. Full-length hmg2 and 5' regions of hmg1 or hmg2 were inserted in the antisense orientation behind a 35S promoter. Tomato expressing the full-length hmg2 antisense showed lower HMGR enzyme activity and were more susceptible to soft rot by Ecc than control plants. In contrast, expression of either antisense hmg/ or antisense hmg2 in the heterologous tobacco system resulted in plants with enhanced resistance to Ecc and reduced TMV lesion sizes. These results may indicate that antisense inhibition is non-specifically exerted on isogenes other than the defense-specific HMGR gene. / Ph. D.

tomato HMGR

disease resistance

genetic engineering

over-expression

antisense inhibition

LD5655.V856 1995.Y84