Department of Microbiology

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Browsing Department of Microbiology by browse.metadata.advisor "Bellstedt, D. U."

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    Regulated expression of the Schizosaccharomyces pombe malic enzyme gene
    (Stellenbosch : Stellenbosch University, 2000-03) Van der Merwe, Marizeth; Viljoen, M.; Bellstedt, D. U.; Stellenbosch University. Faculty of Science. Dept. of Microbiology.
    ENGLISH ABSTRACT: The fission yeast Schizosaccharomyces pombe is able to effectively degrade extracellular L-malate by means of a permease for the active transport of L-malate and a malic enzyme that catalyses the intracellular oxidative decarboxylation of L-malate to pyruvate and CO2. Sequence analysis of the S. pombe NAD-dependent malic enzyme gene, mae2, revealed an open reading frame of 1695 nucleotides, encoding a polypeptide of 565 amino acids. Mutational analyses of the mae2 promoter region revealed several putative cis-acting elements. Two of these elements have homology with binding sites for eukaryotic cAMPdependent regulatory proteins. The UAS I showed homology with the invert of the ADRI binding site, an AP-2 binding site and the TGGCA element. The other putative cAMPdependent site, UAS2, showed homology with the binding site for ATF/CREB and proved to be a strong activator sequence that is required for expression of the mae2 gene. Three negative acting elements, DRS I, DRS2 and DRS3 seem to function co-operatively to repress transcription of the mae2 gene. In this study northern and western blot analyses, as well as malic enzyme assays, showed increased levels of mae2 transcription and enzyme activity when cells were grown under fermentative conditions. The levels of mae2 expression increased approximately 4-fold in 30% glucose and 3-fold under anaerobic conditions. These increased levels of malic enzyme may provide additional pyruvate for various metabolic processes when the mitochondria are not fully functional under fermentative conditions. The regulated expression of the mae2 gene was further investigated using mae2-1acZ fusion plasmids that carried mutations in the DASI, UAS2 or the triple mutated DRSI/URS2/URS3 elements. These plasmids were transformed into S. pombe strains with mutations in the cAMP-dependent or stress-activated signal transduction pathways to determine the signal for the increased expression of the mae2 gene. The cAMP-dependent (Pkal ) and general stress activated (Styl) pathways often act in parallel to regulate the activation of transcription factors necessary for the expression of several S. pombe genes under different physiological conditions. The results presented here suggest that regulatory proteins involved in the Pka l and Styl pathways play a role in the regulation of the mae2 gene under fermentative conditions. Furthermore, some of the regulatory cis-acting elements in the mae2 promoter may interact with these trans-acting factors to regulate the transcription of the gene under different growth conditions. The mechanism of this interaction is not yet known and further research is required to identify all the transcription factors involved in the regulation of the mae2 gene.