Doctoral Degrees (Institute for Wine Biotechnology)
Permanent URI for this collection
Browse
Browsing Doctoral Degrees (Institute for Wine Biotechnology) by Subject "Enzymatic hydrolysis"
Now showing 1 - 1 of 1
Results Per Page
Sort Options
- ItemInvestigating grape berry cell wall deconstruction by hydrolytic enzymes(Stellenbosch : Stellenbosch University, 2015-04) Zietsman, (Anscha) Johanna Jacoba; Vivier, Melane A.; Moore, John P.; Stellenbosch University. Faculty of Agrisciences. Dept. of Viticulture and Oenology. Institute for Wine Biotechnology.ENGLISH ABSTRACT: Maceration enzymes for the wine industry are preparations containing mainly pectinases, cellulases and hemicellulases, used during wine making to degrade the berry cell walls and release polyphenolic and aroma molecules to increase wine quality. These types of enzymes are also used for the harvesting of revenue-generating molecules from pomace (skins, pulp and seeds from grape processing waste), or as processing aids when used in the production of bioethanol. Grape berry cell walls are recalcitrant towards degradation, therefore knowledge about their structures and compositions, as well as how the application of enzymes modify these structures is essential in order to optimise these processes. The aim of this study was to extend current knowledge by using a mixture of existing and novel methodologies to study grape berry cell walls by focusing on the profiles of polymers present in the walls. Cell wall profiling techniques used in this study include the Comprehensive Microarray Polymer Profiling (CoMPP) method that employs monoclonal antibodies and Carbohydrate Binding Modules (CBM) which specifically recognise the polymers in the plant cell wall. With this method we measured the abundance of specific polymers and traced the fluctuation in their levels of abundance as influenced by external factors such as enzyme hydrolysis. The CoMPP method was coupled with monosaccharide profile analysis by GC-MS to determine the building blocks of the cell wall polymers, as well as with Infrared Spectroscopy to monitor the changes in the bulk chemistry profile. Data sets generated by the cell wall profiling methods were analysed with uni- and multivariate statistical methods to detect the major patterns in the data. This study highlighted the cell wall differences on the polymer level, in the berry skin cells of Pinotage grapes at different ripeness levels and how it changes during a standard wine fermentation, leading to the release of homogalacturonans and the exposing of arabinogalactan proteins. When maceration enzymes were added, further depectination was evident and the enzymes unravelled the cell wall of the ripe grapes. In overripe grapes no additional degradation could be observed due to maceration enzyme actions, presumably indicating that the endogenous grape enzymes already caused extensive degradation. When purified enzymes were incubated under buffered conditions with isolated skin cell walls from Pinotage grapes or with Chardonnay grape pomace, different levels of enzymatic hydrolysis were observed and defined. The sequence in which cell wall polymers were extracted, and the influence of specific enzymes in facilitating the extraction process, provided important information on the accessibility of specific cell wall polymers. Synergistic action between, for example an endo-polygalacturonase (EPG) and an endo-glucanase (EG) was demonstrated with CoMPP. This EPG and EG synergism was also demonstrated with a yeast strain (a Saccharomyces paradoxus x S. cerevisiae hybrid) fermented in a buffered pomace suspension. This yeast strain has a native EPG and was engineered to also express a recombinant EG from a genome integrated cassette. The cell walls isolated from the pomace after fermentation were unravelled and depectination took place, as evident from CoMPP data. The cell wall profiling techniques used in this study were proven to be fast and sensitive. It provided insights into the structure of grape cell walls and was used to evaluate the changes due to ripening, fermentation, enzymatic hydrolysis and a heat pre-processing treatment. In addition to the knowledge gained, we also demonstrated that these techniques can be used to evaluate different enzymes and enzyme combinations as well as the potential of microorganisms to degrade grape tissue.