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Monitoring the influence of stress factors on yeasts of the genus Metschnikowia using molecular techniques
Kuljovská, Tereza ; Kovalčík, Adriána (referee) ; Němcová, Andrea (advisor)
Molecular techniques are used widely nowadays, especially in the identification of various species of microorganisms, and provide reliable and accurate results in a relatively short period of time. This work deals with the characterization of Metschnikowia yeasts exposed to various stress factors and the monitoring of their genomic DNA by PCR-DGGE and PFGE methods. The work was focused on the analysis of ribosomal rDNA, specifically the ITS1 and 5,8-ITS2 regions and genes encoding the domains D1/D2, that are part of the large 26S rDNA ribosomal subunit, which are commonly used in the characterization of fungal eukaryotic communities. Three types of stress factors were selected for the experiments: osmotic stress (NaCl environment), oxidative stress (addition of H2O2 to the medium) and nutritional stress (addition of hemp flour / leaves and flowers as a carbon source). The analysis was performed for particular strains Metschnikowia andauensis, Metschnikowia pulcherrima, M. chrysoperlae, M. shanxiensis, M. sinensis and M. zizyphicola. The results showed that addition of the NaCl, H2O2 and hemp components at higher concentrations to the production media does not disrupt the ribosomal DNA when detected by PCR-DGGE. Mutations have not been observed by comparing these strains with yeast that was cultivated under optimal conditions. Despite stress factors, PFGE analysis of karyotypes showed that DNA of some yeast species does not prove any damage and remain intact. Remaining strains proved certain degree of damage, and bands were not detected on the gel for these strains. In the given circumstances, it can be stated that the high adaptability of these species to a stress environment makes them promising biotechnology producers. These yeasts have great potential for usage in agriculture as a tool for biocontrolling of fruit or vines.
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Monitoring the influence of stress factors on yeasts of the genus Metschnikowia using molecular techniques
Kuljovská, Tereza ; Kovalčík, Adriána (referee) ; Němcová, Andrea (advisor)
Molecular techniques are used widely nowadays, especially in the identification of various species of microorganisms, and provide reliable and accurate results in a relatively short period of time. This work deals with the characterization of Metschnikowia yeasts exposed to various stress factors and the monitoring of their genomic DNA by PCR-DGGE and PFGE methods. The work was focused on the analysis of ribosomal rDNA, specifically the ITS1 and 5,8-ITS2 regions and genes encoding the domains D1/D2, that are part of the large 26S rDNA ribosomal subunit, which are commonly used in the characterization of fungal eukaryotic communities. Three types of stress factors were selected for the experiments: osmotic stress (NaCl environment), oxidative stress (addition of H2O2 to the medium) and nutritional stress (addition of hemp flour / leaves and flowers as a carbon source). The analysis was performed for particular strains Metschnikowia andauensis, Metschnikowia pulcherrima, M. chrysoperlae, M. shanxiensis, M. sinensis and M. zizyphicola. The results showed that addition of the NaCl, H2O2 and hemp components at higher concentrations to the production media does not disrupt the ribosomal DNA when detected by PCR-DGGE. Mutations have not been observed by comparing these strains with yeast that was cultivated under optimal conditions. Despite stress factors, PFGE analysis of karyotypes showed that DNA of some yeast species does not prove any damage and remain intact. Remaining strains proved certain degree of damage, and bands were not detected on the gel for these strains. In the given circumstances, it can be stated that the high adaptability of these species to a stress environment makes them promising biotechnology producers. These yeasts have great potential for usage in agriculture as a tool for biocontrolling of fruit or vines.
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