The thermophilic fungus Scytalidium thermophilum produced large amounts of periplasmic beta- D-xylosidase activity when grown on xylan as carbon source. The presence of glucose in the fresh culture medium drastically reduced the level of beta- D-xylosidase activity, while cycloheximide prevented induction of the enzyme by xylan. The mycelial beta-xylosidase induced by xylan was purified using a procedure that included heating at 50 degrees C, ammonium sulfate fractioning (30-75%), and chromatography on Sephadex G-100 and DEAE-Sephadex A-50. The purified beta- D-xylosidase is a monomer with an estimated molecular mass of 45 kDa (SDS-PAGE) or 38 kDa (gel filtration). The enzyme is a neutral protein (pI 7.1), with a carbohydrate content of 12% and optima of temperature and pH of 60 degrees C and 5.0, respectively. beta- D-Xylosidase activity is strongly stimulated and protected against heat inactivation by calcium ions. In the absence of substrate, the enzyme is stable for 1 h at 60 degrees C and has half-lives of 11 and 30 min at 65 degrees C in the absence or presence of calcium, respectively. The purified beta- D-xylosidase hydrolyzed p-nitrophenol-beta- D-xylopyranoside and p-nitrophenol-beta- D-glucopyranoside, exhibiting apparent K(m) and V(max) values of 1.3 mM, 88 micromol min(-1) protein(-1) and 0.5 mM, 20 micromol min(-1) protein(-1), respectively. The purified enzyme hydrolyzed xylobiose, xylotriose, and xylotetraose, and is therefore a true beta- D-xylosidase. Enzyme activity was completely insensitive to xylose, which inhibits most beta-xylosidases, at concentrations up to 200 mM. Its thermal stability and high xylose tolerance qualify this enzyme for industrial applications. The high tolerance of S. thermophilum beta-xylosidase to xylose inhibition is a positive characteristic that distinguishes this enzyme from all others described in the literature.
The filamentous fungus Aspergillus caespitosus was a good producer of intracellular and extracellular invertases under submerged (SbmF) or solid-state fermentation (SSF), using agroindustrial residues, such as wheat bran, as carbon source. The production of extracellular enzyme under SSF at 30°C, for 72h, was enhanced using SR salt solution (1:1, w/v) to humidify the substrate. The extracellular activity under SSF using wheat bran was around 5.5-fold higher than that obtained in SbmF (Khanna medium) with the same carbon source. However, the production of enzyme with wheat bran plus oat meal was 2.2-fold higher than wheat bran isolated. The enzymatic production was affected by supplementation with nitrogen and phosphate sources. The addition of glucose in SbmF and SSF promoted the decreasing of extracellular activity, but the intracellular form obtained in SbmF was enhanced 3-5-fold. The invertase produced in SSF exhibited optimum temperature at 50°C while the extra-and intracellular enzymes produced in SbmF exhibited maximal activities at 60°C. All enzymatic forms exhibited maximal activities at pH 4.0-6.0 and were stable up to 1 hour at 50°C.
The simultaneous presence of two different trehalose-hydrolysing activities has been recognised in several fungal species. While these enzymes, known as acid and neutral trehalases, share a strict specificity for trehalose, they are nevertheless rather different in subcellular localisation and in several biochemical and regulatory properties. The function of these apparently redundant activities in the same cell was not completely understood until recently. Biochemical and genetic studies now suggest that these enzymes may have specialised and exclusive roles in fungal cells. It is thought that neutral trehalases mobilise cytosolic trehalose, under the control of developmental programs, chemical and nutrient signals, or stress responses. On the other hand, acid trehalases appear not to mobilise cytosolic trehalose, but to act as 'carbon scavenger' hydrolases enabling cells to utilise exogenous trehalose as a carbon source, under the control of carbon catabolic regulatory circuits. Although much needs to be learned about the molecular identity of trehalases, it seems that in fungi at least one class of acid trehalases evolved independently from the other trehalases.
β‐d‐Xylosidase production was maximal for Humicola grisea var. thermoidea grown on xylan as the sole carbon source. The main β‐d‐xylosidase activity was localised in the periplasm. β‐Xylosidase was purified from crude extracts by heat treatment, ammonium sulfate precipitation and chromatography on DEAE‐cellulose and Sephadex G‐100. The purified enzyme was a monomer of molecular mass estimated to be 43 kDa by SDS‐PAGE and gel filtration. Optima of pH and temperature were 6.0 and 50 °C, respectively. The enzyme activity was stimulated by Ca2+, Fe2+, and Mg2+. The purified β‐xylosidase did not exhibit xylanase, carboxymethylcelullase, galactosidase, glucosidase, fucosidase or arabinosidase activities. The purified β‐xylosidase hydrolysed xylobiose and xylo‐oligosaccharides of up to five monosaccharide units. The enzyme had a Km of 0.49 mM for p‐nitrophenyl‐β‐d‐xylopyranoside and was not inhibited by its product, xylose.
The production of pectinase was studied in Neurospora crassa, using the hyperproducer mutant exo-1, which synthesized and secreted five to six times more enzyme than the wild-type. Polygalacturonase, pectin lyase and pectate lyase were induced by pectin, and this induction was glucose-repressible. Polygalacturonase was induced by galactose four times more efficiently than by pectin; in contrast the activity of lyases was not affected by galactose. The inducing effect of galactose on polygalacturonase was not glucose-repressible. Extracellular pectinases were separated by ion exchange chromatography. Pectate and pectin lyases eluted into three main fractions containing both activities; polygalacturonase eluted as a single, symmetrical peak, apparently free of other protein contaminants, and was purified 56-fold. The purified polygalacturonase was a monomeric glycoprotein (38% carbohydrate content) of apparent molecular mass 36.6-37.0 kDa (Sephadex G-100 and urea-SDS-PAGE, respectively). The enzyme hydrolysed predominantly polypectate. Pectin was also hydrolysed, but at 7% of the rate for polypectate. Km and Vmax for polypectate hydrolysis were 5.0 mg ml-1 and 357 mumol min-1 (mg protein)-1, respectively. Temperature and pH optima were 45 degrees C and 6.0, respectively. The purified polygalacturonase reduced the viscosity of a sodium polypectate solution by 50% with an increase of 7% in reducing sugar groups. The products of hydrolysis at initial reaction times consisted of oligogalacturonates without detectable monomer. Thus, the purified Neurospora crassa enzyme was classified as an endopolygalacturonase [poly(1,4-alpha-D-galacturonide) glycanohydrolase; EC 3.2.1.15].
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