Isolation of thermostable D-hydantoinase-producing thermophilicBacillus sp SD-1

Summary A thermophilic bacterium which showed highest thermostability and activity of the hydantoinase was isolated from 1m000 thermophiles and identified to beBacillus sp. SD-1 according to morphological and physiological characteristics. The optimal growth temperature of the bacterium was about 60°C. The hydantoinase ofBacillus sp. SD-1 was strictly D-specific, and optimal pH and temperature were determined to be about 8.0 and 70°C, respectively. The D-hydantoinase was stable upto 70°C, and half-life of the enzyme was about 20 min at 80°C.     

Immobilization of endo-polygalacturonase from Aspergillus ustus on silica gel

Endo-polygalacturonase from Aspergillus ustus when immobilized on to modified silica gel retained 28% of its original activity. The immobilized enzyme could be re-used through 10 cycles of reaction with almost 90% retention of its original activity. It had increased thermostability over its soluble form: the half-life of the soluble enzyme at 40 °C was less than 10 h whereas the immobilized enzyme retained 82% of its activity after 10 h at 40 °C. Similarly, at 50 °C the half-life of the soluble enzyme was 30 min whereas that of the immobilized enzyme was 5 h.     

Production and characterization of a thermostable protease produced by an asporogenous mutant ofBacillus stearothermophilus

Summary An asporogenous mutant ofBacillus stearothermophilus (TPM-8) which produces 4-fold higher levels of a thermostable neutral protease than does wild-type strain 308-1 was obtained by mutagenesis with ethyl methanesulfonate. The protease produced by both the mutant and wild-type strain is a metalloprotease requiring Zn²⁺ and Ca²⁺ for activity and thermostability, respectively. It has a temperature optimum of 80°C at pH 7.0 and is highly thermostable, retaining 60% of its activity after 60 min at 85°C. The properties of the enzyme are similar to those of thermolysin.     

A thermostable glucoamylase from a thermophilic <Emphasis Type="Italic">Bacillus</Emphasis> sp.: characterization and thermostability

A thermostable glucoamylase (GA) showed optimum activity at 70°C and pH 5.0. It was highly stable at pH 7.0. The half-life of the enzyme at pH 7.0 was 13, 8, and 3 h 40 min at 60, 65, and 70°C respectively. The residual activity of the enzyme sample incubated at 5 psi (110°C) for 30 min was about 32% of the control set (incubated at 4°C), while no activity was observed at 10 and 15 psi. The thermostability of the enzyme was enhanced twofold in the presence of 0.5% (w/v) starch at 5 psi. Thin-layer chromatography indicated that this enzyme is a GA.     

Production of a high level of cellulase-free xylanase by the thermophilic fungus Thermomyces lanuginosus in laboratory and pilot scales using lignocellulosic materials

Thermomyces lanuginosus, isolated from self-heated jute stacks in Bangladesh, was able to produce a very high level of cellulase-free xylanase in shake cultures using inexpensive lignocellulosic biomass. Of the nine lignocellulosic substrates tested, corn cobs were found to be the best inducer of xylanase activity. The laboratory results of xylanase production have been successfully scaled up to VABIO (Voest-Alpine Biomass Technology Center) scale using a 15-m³ fermentor for industrial production and application of xylanase. In addition, some properties of the enzyme in crude culture filtrate produced on corn cobs are presented. The enzyme exhibited very satisfactory storage stability at 4–30°C either as crude culture filtrate or as spray- or freeze-dried powder. The crude enzyme was active over a broad range of pH and had activity optima at pH 6.5 and 70–75°C. The enzyme was almost thermostable (91–92%) at pH 6.5 and 9.0 after 41 h preincubation at 55°C and lost only 20–33% activity after 188 h. In contrast, it was much less thermostable at pH 5.0 and 11.0. Xylanases produced on different lignocellulosic substrates exhibited differences in thermostability at 55°C and pH 6.5. Correspondence to: J. Gomes     

Production and characterization of xylanase from Bacillus thermoalkalophilus grown on agricultural wastes

Summary Bacillus thermoalkalophilus isolated from termite-infested mound soils of the semi-arid zones of India had the ability to produce good amounts of xylanase(s) from cheap agricultural wastes. Of the two hemicellulosic substrates tested, bagasse was found to be the better inducer for xylanase production. Alkali treatment of bagasse and rice husk had varied effects on enzyme production. The enzyme preparation had activity optima at 60° C and 70° C and a half-life of 60 min at 65° C. The enzyme was stable for 24 h over a pH range of 4.0–6.0, while maximum activity was observed at pH 6.0–7.0. Enzyme production and activity were inhibited by the end-product of xylan hydrolysis, xylose. Offprint requests to: Ajit Varma     

Cloning of a gene encoding thermostable cellobiohydrolase from<Emphasis Type="Italic"> Thermoascus aurantiacus</Emphasis> and its expression in yeast

A gene encoding a cellobiohydrolase (CBH) was isolated from Thermoascus aurantiacus IFO 9748 and designated as cbh1. The deduced amino acid sequence encoded by cbh1 showed high homology with the sequence of glycoside hydrolase family 7. To confirm the sequence of the gene encoding the CBH, the cloned gene was expressed in the yeast Saccharomyces cerevisiae, in which no cellulase activity was found, and the gene product was purified and subjected to enzymatic characterization. The recombinant enzyme was confirmed as a CBH by analysis of the reaction product and designated as CBHI. Recombinant CBHI retained more than 80% of its initial activity after 1 h of incubation at 65 °C and was stable in the pH range 3.0–9.0. The optimal temperature for enzyme activity was about 65 °C and the optimal pH was about 6.0. The recombinant enzyme was found to be highly glycosylated and this glycosylation was shown to contribute to the thermostability of the enzyme. CBHI expression was shown to be induced at higher temperature in T. aurantiacus.     

Purification,characterization, and comparison of anα-glucosidase (endo-oligo-1, 4-glucosidase) from the mesophileBacillus subtilis and the obligate thermophileBacillus caldolyticus

Thep-nitrophenyl--d-maltoside hydrolyzing-glucosidase from the mesophileBacillus subtilis 25S and the obligate thermophileBacillus caldolyticus C2 was purified, characterized, and compared in order to determine the molecular mechanisms that may confer thermostability of starch-degrading enzymes. Both enzymes showed endo-oligo-1,4-glucosidase activity owing to their identical hydrolysis of linear malto-oligosaccharides to maltose and glucose as determined by thin-layer chromatography. Neither enzyme showed activity againstp-nitrophenyl--d-glucopyranoside, maltose, isomaltose, isomaltotriose, or panose. The enzymes may tentatively be classified as a panose-producing pullulanase owing to their hydrolysis of pullulan. The 25S and C2 enzymes were composed of two identical subunits of M_r 55,000 and 60,000 respectively. Both the 25S and C2 enzymes have a pI of 4.85, pH optimum of 7.5 and 7.0, and K_m values for the chromogenic substratep-nitrophenyl--d-maltoside of 2.96 mM and 1.31 mM respectively. The 25S enzyme exhibited optimal activity between 35 and 37°C, and complete inactivation after 10 min at 45°C, while the C2 enzyme showed optimal activity at 60°C and retained 100% of initial activity at 60°C for 2 h. The C2 enzyme required a minimum of 0.02% 2-mercaptoethanol or 0.01 mM EDTA for thermostability. A comparison of the amino acid compositions showed an increase in the number of proline, alanine, and leucine residues for the thermostable C2 enzyme. These alterations in hydrophobicity may influence enzyme thermostability; this may be a factor in the design of engineered proteins for industrial use.Florida Agricultural Experiment Station Journal Series No. 9985     

Enhanced stability of cellulase-free xylanase from Chainia sp. (NCL 82.5.1)

Summary Chainia sp. (NCL 82.5.1) produces an extracellular, cellulase-free xylanase. The ready accessibility of the enzyme to cellulose pulp due to its small size and the absence of cellulase are advantageous features. The enzyme is stable at 40°C for 1h and in a pH range of 5–9 at 4°C. Improved stability of the enzyme at higher temperature and pH are desirable. Effect of a variety of compounds was studied to enhance stability. Glycerol, sorbitol, mannitol (10%) or glycine (1M) had marginal effect on thermostability. Addition of Ca⁺² or PEG (10mM) increased the half-life of the enzyme at 60°C. Cysteine (10mM) or Tween-80 (1%) showed 70% protection against thermal inactivation. Xylan (3%) offered complete protection against inactivation of the emzyme at 60°C and at pH 9.NCL Communication No. 5907     

Xylanase production under solid-state fermentation and its characterization by an isolated strain of <Emphasis Type="Italic">Aspergillus foetidus</Emphasis> in India

Summary A locally isolated strain of Aspergillus foetidus MTCC 4898 was studied for xylanase (EC 3.2.1.8) production using lignocellulosic substrates under solid state fermentation. Corncobs were found as the best substrates for high yield of xylanases with poor cellulase production. The influence of various parameters such as temperature, pH, moistening agents, moisture level, nitrogen sources and pretreatment of substrates were evaluated with respect to xylanase yield, specific activity and cellulase production. Influence of nitrogen sources on protease secretion was also examined. Maximum xylanase production (3065 U/g) was obtained on untreated corncobs moistened with modified Mandels and Strenberg medium, pH 5.0 at 1 5 moisture levels at 30 °C in 4 days of cultivation. Submerged fermentation under the same conditions gave higher yield (3300 U/g) in 5 days of cultivation, but productivity was less. Ammonium sulphate fractionation yielded 3.56-fold purified xylanase with 76% recovery. Optimum pH and temperature for xylanase activity were found to be 5.3 and 50 °C respectively. Kinetic parameters like K_m and V_max were found to be 3.58 mg/ml and 570 μmol/mg/min. Activity of the enzyme was found to be enhanced by cystiene hydrochloride, CoCl₂, xylose and Tween 80, while significantly inhibited by Hg⁺⁺, Cu⁺⁺ and glucose. The enzyme was found to be stable at 40 °C. The half life at 50 °C was 57.53 min. However thermostability was enhanced by glycerol, trehalose and Ca⁺⁺. The crude enzyme was stable during lyophilization and could be stored at less than 0 °C.     

Temperature response of trehalase from a mesophilic (Neurospora crassa) and a thermophilic (Thermomyces lanuginosus) fungus

The purified trehalases of the mesophilic fungus, Neurospora crassa, and the thermophilic fungus, Thermomyces lanuginosus, had similar temperature and pH optima for activity, but differed in molecular weight, electrophoretic mobility and Michaelis constant. At lower concentration, trehalases from both fungi were inactivated to similar extent at 60°C. While purified trehalase of T. lanuginosus was afforded protection against heat-inactivation by proteinaceous protective factor(s) present in mycelial extracts, by bovine serum albumin and by casein, these did not afford protection to N. crassa trehalase against heat inactivation. Both trehalases exhibited discontinuous Arrhenius plots with temperature of discontinuity at 40°C. The activation energy calculated from the slope of the Arrhenius plot was higher for the T. lanuginosus enzyme. The plots of apparent K _m versus 1/T for trehalases of N. crassa and T. lanuginosus were linear from 30° to 60°C.The results show that purified trehalases of the mesophilic and the thermophilic fungus are distinct. Although, these exhibit similar thermostability of their catalytic function at low concentration, distinctive thermal stability characteristics of thermophilic enzyme become apparent at high protein concentration. This could be brought about in the cell by the enzyme itself, or by other proteins.     

Polyelectrolyte complex formation mediated immobilization of chitosan-invertase neoglycoconjugate on pectin-coated chitin

Saccharomyces cerevisiae invertase, chemically modified with chitosan, was immobilized on pectin-coated chitin support via polyelectrolyte complex formation. The yield of immobilized enzyme protein was determined as 85% and the immobilized biocatalyst retained 97% of the initial chitosan-invertase activity. The optimum temperature for invertase was increased by 10 °C and its thermostability was enhanced by about 10 °C after immobilization. The immobilized enzyme was stable against incubation in high ionic strength solutions and was 4-fold more resistant to thermal treatment at 65 °C than the native counterpart. The biocatalyst prepared retained 96 and 95% of the original catalytic activity after ten cycles of reuse and 74 h of continuous operational regime in a packed bed reactor, respectively.     

An alkali-thermotolerant extracellular protease from a newly isolated Streptomyces sp. DP2

Of six alkalitolerant, extracellular protease producing bacterial strains isolated, DP2 displayed maximum activity. This organism was designated as Streptomyces sp. DP2 and identified as Streptomyces ambofaciens. Maximum protease yield was observed after 48 hours of submerged fermentation using various carbon and nitrogen sources. Fructose was found to be the best substrate for protease production, followed by maltose, lactose and wheat bran. Mustard cake is reported for the first time as the most ideal nitrogen source although soybean meal also gave comparable yield. The protease produced by Streptomyces sp. DP2 exhibited extensive activity over a broad pH range (4–12) with maximum activity at pH 8, and was active over a broad range of elevated temperatures (50–100°C), and possessed thermostability at 60–90°C for up to 1 hour. Enzyme activity was reduced by EDTA (25%), SDS (16%), and PMSF (6%). This novel alkaline protease has both alkali- and thermostability that may have industrial significance.     

A thermostable manganese-containing superoxide dismutase from the thermophilic fungus Thermomyces lanuginosus

A thermostable superoxide dismutase (SOD) from a Thermomyces lanuginosus strain (P134) was purified to homogeneity by fractional ammonium sulfate precipitation, ion-exchange chromatography on DEAE-Sepharose, Phenyl-Sepharose hydrophobic interaction chromatography, and gel filtration on Sephacryl S-100. The molecular mass of a single band of the enzyme was estimated to be 22.4 kDa, using sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Using gel filtration on Sephacryl S-100, the molecular mass was estimated to be 89.1 kDa, indicating that this enzyme was composed of four identical subunits of 22.4 kDa each. The SOD was found to be inhibited by NaN₃, but not by KCN or H₂O₂, suggesting that the SOD in T. lanuginosus was of the manganese superoxide dismutase type. The SOD exhibited maximal activity at pH 7.5. The optimum temperature for the activity was 55°C. It was thermostable at 50 and 60°C and retained 55% activity after 60 min at 70°C. The half-life of the SOD at 80°C was approximately 28 min and even retained 20% activity after 20 min at 90°C.     

Immobilization of alkaline protease from Conidiobolus macrosporus for reuse and improved thermal stability

Alkaline protease from Conidiobolus macrosporus was immobilized on polyamide using glutaraldehyde as a bifunctional agent. The immobilized enzyme was optimally active at a higher temperature of 50°C than the free enzyme (40°C ) and showed a ten-fold increased thermostability at 60°C compared to that of the free enzyme. The efficiency of immobilization was 58% under the optimal conditions of pH and temperature. There was a 14-fold decrease in the K _m of immobilized enzyme compared to the free enzyme. The immobilized enzyme was fully active even after twenty-two cycles of repeated use. It retained 80% activity at 50°C in presence of 8 M urea exhibiting its stability to the denaturant and was compatible with several commercial detergents.     

Thermostability of enzymes of the tricarboxylic acid cycle ofBacillus coagulans

The thermostability of four enzymes of the tricarboxylic acid cycle has been studied in the facultative thermophile,Bacillus coagulans. Although isocitrate dehydrogenase appeared to be more temperature-sensitive in whole-cell extracts of cultures grown at 30°C compared with that in cultures grown at 55°C, this difference could be largely eliminated by the removal of cell-wall material. The specific activity of each of the enzymes examined was approximately threefold higher in cultures grown at 55°C than in those grown at 30°C. The maximum temperature, Arrhenius plot and effect of stabilizing agents for each enzyme were examined and found to be independent of growth temperature. Sodium chloride (10% w/v) was an effective protective agent for fumarase, aconitase and malate dehydrogenase. Protection from thermal denaturation of isocitrate dehydrogenase, aconitase and fumarase but not malate dehydrogenase was also given when the enzymes were heated in the presence of their substrates. These results are discussed in light of the generalized theories of facultative thermophily which have been proposed.     

Improved thermal stability and activity in the cold-adapted lipase B from Candida antarctica following chemical modification with oxidized polysaccharides

In order to improve the thermal stability (t_1/2) and activity of lipase B from cold-adapted Candida antarctica (CALB), amino groups of the enzyme were chemically linked to a range of oxidized polysaccharides using a range of reducing agents. By chemically modifying CALB using 0.1% dextran (250 kDa) at pH 8.6 for 10 days using borane–pyridine complex as reducing agent, increased thermal stability (t_1/2, 168 min at 70°C) and activity (65% higher specific activity) was achieved compared to the unmodified enzyme (t_1/2, 18 min at 70°C). Improvements in thermostability were generally better with high molecular weight polymers such as dextran (40 and 250 kDa) or ficoll (70 and 400 kDa) in comparison to low molecular weight inulin (5 kDa). The shape of the polymer also appeared to be important with elongated, elipsoidal-shaped dextran providing better thermostabilization than spherical-shaped ficoll. Borane–pyridine complex was found to be a good, non-toxic reducing agent for improving thermostability, compared with sodium borohydride and sodium cyanoborohydride. An interesting finding was that, in all cases, specific activity of the modified enzymes increased with a concomitant increase in thermostability. This response defies the general principle of a trade-off between activity and stability, and demonstrates that chemical modification provides new avenues for improving the thermal stability of enzymes from psychrophiles without sacrificing their activity.     

Thermostable d-hydantoinase from thermophilic Bacillus stearothermophilus SD-1: characteristics of purified enzyme

One thousand thermophiles isolated from soils were screened for hydantoinase and its thermostability. One thermophilic bacterium that showed the highest thermostability and activity of hydantoinase was identified to be Bacillus stearothermophilus SD-1 according to morphological and physiological characteristics. The hydantoinase of B. stearothermophilus SD-1 was purified to homogeneity via ammonium sulfate fractionation, anion-exchange chromatography, heat treatment, hydrophobic-interaction chromatography, and preparative gel electrophoresis. The relative molecular mass of the hydantoinase was determined to be 126 kDa by gel-filtration chromatography, and a value of 54 kDa was obtained as a molecular mass of the subunit on analytical sodiumdodecylsulfate/polyacrylamide gel electrophoresis. The hydantoinase was strictly d-specific and metal-dependent. The optimal pH and temperature were about 8.0 and 65°C respectively, and the half-life of the d-hydantoinase was estimated to be 30 min at 80°C, indicating the most thermostable enzyme so far.     

Partial characterization ofAspergillus fumigatus polygalacturonases for the degumming of natural fibers

Summary Aspergillus fumigatus strain 4, cultured on citrus pectin as the sole carbon source, produced polygalacturonases whose activity was optimum at 65°C and pH 3.5–4.5. The enzymes presented a bimodal thermostability for 10 min, but not 60 min, of incubation. Polygalacturonases showed pH stability between 3.0 to 9.0. The enzymes were stable when stored at 4–6°C for 90 days, but their activity was reduced by 24% when they were stored at 26–30°C. Orange pulp was the best pectic carbon source tested for the production of pectinases capable of retting ramie fibers. The reutilization of these enzymes was possible, suggesting the viability of industrial use of pectinases for degumming ramie fibers.     

Purification and properties of malate dehydrogenase from the extreme thermophileBacillus caldolyticus

The enzyme malate dehydrogenase (EC 1.1.1.37) from an extreme thermophileB. Caldolyticus was purified to about 91% homogeneity. The molar mass of the enzyme was determined as 73 000 daltons and it is composed of two subunits, each with a molar mass of 37 000. Initial velocity studies with oxaloacetic acid and NADH as substrates at pH 8.1, over a range of temperatures, indicate that the enzyme operates via a sequential type mechanism. Van't Hoff plots of the kinetic parameters displayed sharp changes in slope at characteristic temperatures, whereas the Arrhenius plot exhibited no such breaks over the temperature interval investigated. The enzyme was found to be stable at 41°C and lower temperatures. At 51°C and 59°C an almost immediate 20% reduction in activity was obtained, but no further inactivation occurred during the 60 min of incubation. At 59°C the enzyme lost 50% of its initial activity in about 38 s. High concentration of NADH was observed to greatly stabilize the enzyme at that temperature.It is suggested that the slope changes in the Van't Hoff plots and the stability profies at 51°C and 59°C are representative of a temperature induced conformational change in the enzyme.Proceedings of the Fourth College Park Colloquium on Chemical Evolution:Limits of Life, University of Maryland, College Park, 18–20 October 1978.