Phenolic cross-links and inter-unit linkages result from the oxidative coupling of hydroxycinnamates leading to lignin assembly and cross-linking with cell wall polysaccharides and extensin proteins.
Background
Ascomycetous yeasts from the kingdom fungi inhabit every biome in nature. While filamentous fungi have been studied extensively regarding their enzymatic degradation of the complex polymers comprising lignocellulose, yeasts have been largely overlooked. As yeasts are key organisms used in industry, understanding their enzymatic strategies for biomass conversion is an important factor in developing new and more efficient cell factories. The aim of this study was to identify polysaccharide-degrading yeasts by mining CAZymes in 332 yeast genomes from the phylum Ascomycota. Selected CAZyme-rich yeasts were then characterized in more detail through growth and enzymatic activity assays.
Results
The CAZyme analysis revealed a large spread in the number of CAZyme-encoding genes in the ascomycetous yeast genomes. We identified a total of 217 predicted CAZyme families, including several CAZymes likely involved in degradation of plant polysaccharides. Growth characterization of 40 CAZyme-rich yeasts revealed no cellulolytic yeasts, but several species from the Trichomonascaceae and CUG-Ser1 clades were able to grow on xylan, mixed-linkage β-glucan and xyloglucan. Blastobotrys mokoenaii, Sugiyamaella lignohabitans, Spencermartinsiella europaea and several Scheffersomyces species displayed superior growth on xylan and well as high enzymatic activities. These species possess genes for several putative xylanolytic enzymes, including ones from the well-studied xylanase-containing glycoside hydrolase families GH10 and GH30, which appear to be attached to the cell surface. B. mokoenaii was the only species containing a GH11 xylanase, which was shown to be secreted. Surprisingly, no known xylanases were predicted in the xylanolytic species Wickerhamomyces canadensis, suggesting that this yeast possesses novel xylanases. In addition, by examining non-sequenced yeasts closely related to the xylanolytic yeasts, we were able to identify novel species with high xylanolytic capacities.
Conclusions
Our approach of combining high-throughput bioinformatic CAZyme-prediction with growth and enzyme characterization proved to be a powerful pipeline for discovery of novel xylan-degrading yeasts and enzymes. The identified yeasts display diverse profiles in terms of growth, enzymatic activities and xylan substrate preferences, pointing towards different strategies for degradation and utilization of xylan. Together, the results provide novel insights into how yeast degrade xylan, which can be used to improve cell factory design and industrial bioconversion processes.
The effect of a commercial multienzyme product obtained by fermentation from Aspergillus aculeatus on soybean and soybean meal was investigated using viscosity measurements, dietary fibre component analysis and different microscopy techniques utilizing histochemical dyes and antibody labelling. The results obtained demonstrated a strong viscosity reducing effect of the enzyme preparation on soluble galactomannan and xyloglucan polysaccharides and in addition non-starch polysaccharide analysis demonstrated a notable solubilisation of all polysaccharide constituents. The degradation of these components as native integral parts of cell walls upon exposure to the enzyme was visualized with microscopy. Two histochemical dyes, coriphosphine O and alcian blue were successfully used to follow pectin solubilisation after enzyme treatment. Commercial antibodies recognizing specific components of pectin and hemicellulose components of soybean cell wall were also used to visualize several enzyme activities in the commercial enzyme preparation The challenges of using commercial antibodies elicited from a given plant source to detect similar epitiopes on another plant source are also discussed. Non-starch polysaccharide analysis of the insoluble dietary fibre constituents before and after enzyme treatment corroborated the visualized mode of action demonstrated by microscopy. The combination of techniques provided visual and quantitative measurements of the solubilisation and degradation of hemicellulose pectic soybean cell wall components as part of the undesirable antinutrients in animal feed.
Together with bacteria and fungi, yeasts actively take part in the global carbon cycle. Over a hundred yeast species have been shown to grow on the major plant polysaccharide xylan, which requires an arsenal of carbohydrate active enzymes. However, which enzymatic strategies yeasts use to deconstruct xylan and what specific biological roles they play in its conversion remain unclear. In fact, genome analyses reveal that many xylan-metabolizing yeasts lack expected xylanolytic enzymes. Guided by bioinformatics, we have here selected three xylan-metabolizing ascomycetous yeasts for in-depth characterization of growth behavior and xylanolytic enzymes. The savanna soil yeastBlastobotrys mokoenaiidisplays superior growth on xylan thanks to an efficient secreted glycoside hydrolase family 11 (GH11) xylanase; solving its crystal structure revealed a high similarity to xylanases from filamentous fungi. The termite gut-associatedScheffersomyces lignosusin contrast grows more slowly and its xylanase activity was found to be mainly cell surface-associated. The wood-isolatedWickerhamomyces canadensissurprisingly could not utilize xylan as the sole carbon source without adding xylooligosaccharides, exogenous xylanases or even by co-culturing withB. mokoenaii, suggesting thatW. canadensisrelies on initial xylan hydrolysis by neighboring cells. Furthermore, our characterization of a novelW. canadensisGH5 subfamily 49 (GH5_49) xylanase represents the first demonstrated activity in this subfamily. Our collective results provide new information on the variable xylanolytic systems evolved by yeasts and their potential roles in natural carbohydrate conversion.
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