| Popis: |
SummaryTogether 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.ImportanceMicrobes that take part in the degradation of the polysaccharide xylan, the major hemicellulose component in plant biomass, are equipped with specialized enzyme machineries to hydrolyze the polymer into monosaccharides for further metabolism. However, despite being found in virtually every habitat, little is known of how yeasts break down and metabolize xylan and what biological role they may play in its turnover in nature. Here, we have explored the enzymatic xylan deconstruction strategies of three underexplored yeasts from diverse environments:Blastobotrys mokoenaiifrom soil,Scheffersomyces lignosusfrom insect guts andWickerhamomyces canadensisfrom trees, and show that each species has a distinct behavior regarding xylan conversion. These findings may be of high relevance for future design and development of microbial cell factories and biorefineries utilizing renewable plant biomass. |
