Browsing by Subject "Molecular genetics"
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Publication Effekt der Überproduktion von Enzymen des Glucosestoffwechsels auf das Wachstum und die Alkoholbildung in der Hefe Saccharomyces cerevisiae(2006) Emili, Markus; Heinisch, JürgenThe wine-, beer- and baker's yeast Saccharomyces cerevisiae is the major source in world wide alcohol production. Regarding the research in bioethanol production, the work presented here was aimed to examine the effect of the in vivo overproduction of all enzymes contributing to the conversion of glucose to ethanol in the yeast Saccharomyces cerevisiae with the prospect of increasing ethanol formation. S. cerevisiae is probably the best studied eucaryotic organism with respect to both classical and molecular genetics. It turned out to be of great advantage that two different multi-copy-vectors could be employed in these studies. Each of them was used in the first part of the work to insert half of the set of genes intended for overexpression. The first genes were inserted by restriction and ligation and later on a combination of the PCR-technique, with which the genomic fragments of interest were amplified, and the efficient homologous recombination in vivo was used. With these methods, the gene encoding a hexose transporter (HXT1), all the genes encoding glycolytic enzymes (HXK2, PGI1, PFK1, PFK2, FBA1, TPI1, TDH1 bzw. TDH2, PGK1, GPM1, ENO2, PYK1), as well as the genes encoding enzymes needed for the conversion of pyruvate to ethanol (PDC1, ADH1), were cloned. Following the isolation from yeast, the plasmids were amplified in E. coli and characterized by restriction analysis. The measurement of specific enzyme activity in crude extract of yeast transformants with such plasmids showed a slight overproduction (factor 1,5 to 3,0) for all enzymes, except for glyceraldehyde-3-phosphate dehydrogenase. For HXT1, an increased mRNA level (factor 14 in contrast to the control) was taken as evidence for overproduction. In the enzymatic determinations a clear tendency showing a lower overproduction with an increasing number of genes on the plasmids was observed. These findings suggest a negative feedback on glycolytic flux regulation. The the growth rates obtained in the second part of the work also showed a clear reduction with increasing numbers of plasmid-encoded genes. Regarding the physiological parameters, no changes in the coefficients for glucose consumption and ethanol formation could be found in comparison to a wild-type control, and the yield remained basically unchanged as well. Interestingly, abolishing the ATP-inhibition of phosphofructokinase by expression of a mutant allele of PFK1, resulted in a faster growth of transformants with an otherwise isogenic background. This result indicates the physiological relevance of the allosteric regulation at this essential glycolytic step. A lack of enzyme activity in one of the glycolytic steps in deletion mutants normally leads to growth inhibition on hexoses. On this basis, the construction of a yeast strain was initiated with the objective to obtain stable multi-copy transformants simply by growing cells on different sugars as carbon sources. In detail, this was done by crossing a strain carrying a pgi1-deletion with a strain carrying a pyk1-deletion followed by sporulation and tetrad dissection. Preliminary data with intermediate strain constructs indicate a clear increase in plasmid stability after growing cells on complex media. From the results of this thesis, valuable insights into the regulation of the glycolytic flux in vivo can be deduced, which may serve as a basis for ongoing research on the improvement of ethanol formation by yeast.