Thermoascus aurantiacus harbors an esterase/lipase that is highly activated by anionic surfactant.

Fungal lipolytic enzymes play crucial roles in various lipid bio-industry processes. Here, we elucidated the biochemical and structural characteristics of an unexplored fungal lipolytic enzyme (TaLip) from Thermoascus aurantiacus var. levisporus, a strain renowned for its significant industrial relevance in carbohydrate-active enzyme production. TaLip belongs to a poorly understood phylogenetic branch within the class 3 lipase family and prefers to hydrolyze mainly short-chain esters. Nonetheless, it also displays activity against natural long-chain triacylglycerols. Furthermore, our analyses revealed that the surfactant sodium dodecyl sulfate (SDS) enhances the hydrolytic activity of TaLip on pNP butyrate by up to 5.0-fold. Biophysical studies suggest that interactions with SDS may prevent TaLip aggregation, thereby preserving the integrity and stability of its monomeric form and improving its performance. These findings highlight the resilience of TaLip as a lipolytic enzyme capable of functioning in tandem with surfactants, offering an intriguing enzymatic model for further exploration of surfactant tolerance and activation in biotechnological applications.

Application of a recombinant GH10 endoxylanase from Thermoascus aurantiacus for xylooligosaccharide production from sugarcane bagasse and probiotic bacterial growth.

Xylooligosaccharides (XOs) are a promising class of prebiotics capable of selectively stimulating the growth of the beneficial intestinal microbiota against intestinal pathogens. They can be obtained from xylan present in residual lignocellulosic material from agriculture. Thus, in this study we produced XOs by extracting xylan from sugarcane bagasse and hydrolyzing it using the GH10 xylanase from Thermoascus aurantiacus expressed by Pichia pastoris. An alkaline method to extract xylan is described, which resulted in 83.40% of xylan recovery and low amounts of cellulose and lignin. The enzymatic hydrolysate exhibited a mixture of XOs containing mainly xylobiose, xylotriose and xylotetraose. These oligosaccharides stimulated the growth of Lactobacillus casei, L. rhamnosus, L. fermentum and L. bulgaricus strains, which were able to produce organic acids, especially acetic acid. These findings demonstrate the possibility to redirect crop by-products to produce XOs and their use as a supplement to stimulate the growth of probiotic strains.

Heterologous secretory expression of ß-glucosidase from Thermoascus aurantiacus in industrial Saccharomyces cerevisiae strains.

The use of plant biomass for biofuel production will require efficient utilization of the sugars in lignocellulose, primarily cellobiose, because it is the major soluble by-product of cellulose and acts as a strong inhibitor, especially for cellobiohydrolase, which plays a key role in cellulose hydrolysis. Commonly used ethanologenic yeast Saccharomyces cerevisiae is unable to utilize cellobiose; accordingly, genetic engineering efforts have been made to transfer ß-glucosidase genes enabling cellobiose utilization. Nonetheless, laboratory yeast strains have been employed for most of this research, and such strains may be difficult to use in industrial processes because of their generally weaker resistance to stressors and worse fermenting abilities. The purpose of this study was to engineer industrial yeast strains to ferment cellobiose after stable integration of tabgl1 gene that encodes a ß-glucosidase from Thermoascus aurantiacus (TaBgl1). The recombinant S. cerevisiae strains obtained in this study secrete TaBgl1, which can hydrolyze cellobiose and produce ethanol. This study clearly indicates that the extent of glycosylation of secreted TaBgl1 depends from the yeast strains used and is greatly influenced by carbon sources (cellobiose or glucose). The recombinant yeast strains showed high osmotolerance and resistance to various concentrations of ethanol and furfural and to high temperatures. Therefore, these yeast strains are suitable for ethanol production processes with saccharified lignocellulose.

Production of xylanase and CMCase on solid state fermentation in different residues by Thermoascus aurantiacus miehe

The use of waste as raw material is important for government economy and natural balance. The purpose of this work was to study the production of CMCase and xylanase by a Brazilian strain of Thermoascus aurantiacus in solid state fermentation (SSF) using different agricultural residues (wheat bran, sugarcane bagasse, orange bagasse, corncob, green grass, dried grass, sawdust and corn straw) as substrates without enrichment of the medium and characterize the crude enzymes.The study of the extracellular cellulolytic and hemicellulolytic enzymes showed that T. arantiacus is more xylanolytic than cellulolytic. The highest levels of enzymes were produced in corncob, grasses and corn straw. All the enzymes were stable at room temperature by 24 h over a broad pH range (3.0-9.0) and also were stable at 60ºC for 1 h. The optimum pH and temperature for xylanase and CMCase were 5.0-5.5 and 5.0 and 75ºC, respectively. The microorganism grew quickly in stationary, simple and low cost medium. The secreted extracellular enzymes presented properties that match with those frequently required in industrial environment.

O emprego de residuos como matéria prima é importante como estrategia governamental e para o balanço ambiental. O propósito deste trabalho foi estudar a produção de CMCase e xilanase de uma linhagem de Thermoascus aurantiacus isolado de solo brasileiro em fermentação em estado sólido (SSF) usando diferentes resíduos agrícolas (farelo de trigo, bagaço de cana, bagaço de laranja, sabugo de milho, grama verde, grama seca, serragem de eucalipto e palha de milho) como substratos sem enriquecimento dos meios e caracterizar as enzimas. O estudo das enzimas hemiceluloliticas extracelulares mostrou que o fungo T. arantiacus é mais xilanolítico do que celulolítico. Ele produziu maiores níveis das enzimas em meios contendo sabugo de milho, grama e palha de milho. Todas as enzimas foram estáveis por 24 h à temperatura ambiente numa ampla faixa de pH (3,0 - 9,0) e também foram estáveis a 60ºC por 1 h. O pH ótimo e temperatura ótima para xilanase e CMCase foram 5,0- 5,5 e 5,0 e 75ºC, respectivamente. O microrganismo cresceu muito bem estacionariamente no meio simples, de baixo custo. As enzimas estáveis secretadas extracelularmente apresentam as características necessárias para sua aplicação industrial.