Transesterification of divinyladipate with glucose at various temperatures by an alkaline protease of Streptomyces sp.

The transesterification of 1 M divinyladipate with 0.25 M glucose in dimethylformamide (DMF) catalyzed by 5 mg ml^–1 alkaline protease (24 units mg^–1 min^–1) from Streptomyces sp. gave 6-O-vinyladipoyl d-glucose as the main product with yields are between 60 and 90%. The optimum temperature for the reaction was about 50 °C.     

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.     

Thermoactive extracellular proteases of <Emphasis Type="Italic">Geobacillus caldoproteolyticus</Emphasis>, sp. nov., from sewage sludge

A proteolytic thermophilic bacterial strain, designated as strain SF03, was isolated from sewage sludge in Singapore. Strain SF03 is a strictly aerobic, Gram stain-positive, catalase-positive, oxidase-positive, and endospore-forming rod. It grows at temperatures ranging from 35 to 65°C, pH ranging from 6.0 to 9.0, and salinities ranging from 0 to 2.5%. Phylogenetic analyses revealed that strain SF03 was most similar to Saccharococcus thermophilus, Geobacillus caldoxylosilyticus, and G. thermoglucosidasius, with 16S rRNA gene sequence identities of 97.6, 97.5 and 97.2%, respectively. Based on taxonomic and 16S rRNA analyses, strain SF03 was named G. caldoproteolyticus sp. nov. Production of extracellular protease from strain SF03 was observed on a basal peptone medium supplemented with different carbon and nitrogen sources. Protease production was repressed by glucose, lactose, and casamino acids but was enhanced by sucrose and NH₄Cl. The cell growth and protease production were significantly improved when strain SF03 was cultivated on a 10% skim-milk culture medium, suggesting that the presence of protein induced the synthesis of protease. The protease produced by strain SF03 remained active over a pH range of 6.0–11.0 and a temperature range of 40–90°C, with an optimal pH of 8.0–9.0 and an optimal temperature of 70–80°C, respectively. The protease was stable over the temperature range of 40–70°C and retained 57 and 38% of its activity at 80 and 90°C, respectively, after 1 h.     

Production Dynamics and Characterization of Chitinolytic System of Streptomyces sp. NK1057, a Well Equipped Chitin Degrader

Streptomyces sp. NK 1057 produced four extracellular chitinases. Two (62 and 48 kDa) were endochitinaseswhile the other two (35 and 28 kDa) had chitobiosidaseactivity. Chi62 was produced in early growth phase whereas the other three were produced later. Chi48 was optimally active at pH 4.0 and 60 °C whereas Chi35 was optimally active at pH 6.0 and 40 °C. Both the enzymes had fairly good pH and temperature stability up to 50 °C, with Chi48 being more thermostable than Chi35. Chi48 was significantly inhibited by N-acetylglucosaminebut not by Hg²⁺ and the reverse was true for Chi35. Chi48 and Chi35 had isoelectric points of 5.1 and 6.0 and the N-terminal amino acid sequence of Chi35 determined uptofour amino acids, was Gln–Ser–Pro– Gly. Chi62 and Chi48 were able to inhibit the germination of Fusariumoxysporum spores by 57.4 and 61.2% respectively whereas; Chi35 and Chi28 did so by only 14.1 and 3.8%, suggesting endochitinaseto possess antifungal activity. Only Chi28 exhibited a lytic activity, 0.022 U ml^–1, towards Micrococcus lysodeikticus cells.     

Isolation and characterization of AStreptomyces C5 mutant strain hyperproductive of extracellular protease

Summary A pleiotropic streptomycete mutant was isolated that overproduced extracellular protease activity on azocasein, whereas the parent strain,Streptomyces C5, produced only negligible extracellular azocaseinase activity. Also unlike the parent strain, the mutant, designated C5-A13, was nonpigmented, and was unable to sporulate or produce antibiotics.     

Protease and lipase production by a strain ofSerratia marcescens (532 S)

Summary Production of both exolipase and exoprotease activities bySerratia marcescens 532 S isolated from an aerobic fixed-biomass reactor were strongly influenced by nutritional factors which acted as inducers or repressors. In batch culture, protease and lipase activities were produced after the exponential phase. NH₄Cl, amino acids and simple carbon sources caused repression of protease activity. At a concentration of 1.5 g L^–1, the individual addition of maltose, mannitol, acetate, fructose or glucose, repressed exoprotease production, with the greatest effect by glucose. An inverse relationship existed between exoprotease synthesis and increasing glucose concentrations. Lipids activated lipase production, the most significant increase occurred when Tween 80 was added in the medium. Thus, glucidolytic, proteolytic and lipolytic activities could be efficiently expressed in batch cultures only successively.At low dilution rate of chemostat cultures with a constant glucose input concentration of 2 g L^–1, glucidolytic, proteolytic and lipolytic activities were produced, but did not have the same regulation: atD values <0.08 h^–1, the level of protease activity dropped while that of lipase showed a corresponding increase. Above these values, increasingD led to a decrease of the two hydrolase activities, at the level of the specific activities as well as in the specific rate of biosynthesis of each enzyme. Similar results were obtained in chemostat culture with a constant specific growth rate of 0.04 h^–1 with increasing glucose input concentrations, i.e. protease and lipase activities decreased when the specific glucose uptake rates were enhanced.     

Extracellular laccase activity in Tetraploa aristata

Tetraploa aristata CLPS 419 produced maximum extracellular laccase activity at over 9 mU ml^–1 in shaking cultures supplemented with glucose and 3.5 mU ml^–1 in sucrose-grown ones. Laccase activity did not exceed 0.7 mU ml^–1 in stationary cultures with glucose and was not detected in similar cultures with sucrose or in ones grown on lignin.     

Production of neutral and alkaline extracellular proteases by the thermophilic fungus, Scytalidium thermophilum, grown on microcrystalline cellulose

Extracellular proteases produced by Scytalidium thermophilum, grown on microcrystalline cellulose, were most active at pH 6.5–8 and 37–45 °C when incubated for 60 min. Highest protease activity was at day 3 where endoglucanase activity was low. Protease activity measurements with and without the protease inhibitors, p-chloromercuribenzoate, PMSF, antipain, E-64, EDTA and pepstatin A, suggest production of thiol-containing serine protease and serine proteases. Endoglucanase and Avicel-adsorbable endoglucanase activity in culture medium was not significantly affected by protease inhibitors.     

Production of a hypoglycemic, extracellular polysaccharide from the submerged culture of the mushroom, Phellinus linteus

Mycelial growth and extracellular polysaccharide production of Phellinus linteus were optimal at pH 5 and 25 °C. Maximum biomass production (14.2 g l^–1) was after 15 d of cultivation, whereas, extracellular polysaccharide was maximal (3.5 g l^–1) after 21 d. The hypoglycemic effect of the polysaccharide, investigated in streptozotocin-induced diabetic rats, decreased plasma glucose, total cholesterol and triacylglycerol concentrations by 49%, 32%, and 28%, respectively, and aspartate aminotransferase activity by 20%. The results indicate the potential of this polysaccharide to prevent hyperglycemia in diabetic patients.     

Preparation of vinyl thymidine ester catalyzed by protease and its chemical polymerization

Transesterification reaction of 0.25 M thymidine with 1 M divinyladipate in dimethylformamide (DMF) was catalyzed by an alkaline protease (5 mg ml^–1) from Streptomyces sp. (20 units mg^–1 min) at 30 °C for 7 days to give 5-O-vinyladipoyl thymidine (yield 77%) without formation of any by-products. Poly(vinyl alcohol) containing thymidine branches could be obtained by its free-radical polymerization.     

Separation and partial purification of extracellular amylase and protease from Bacillus caldolyticus

Summary The extracellular amylase and protease from Bacillus caldolyticus can be concentrated by ammonium sulfate precipitation after growth on either solid or in liquid media containing starch, glucose, and brain-heart infusion. Using the Diaflo ultrafiltration system with membranes of various permeability, the enzymes could be separated from each other by extensive flushing with buffer. Best results were obtained with the 50–70% ammonium sulfate fraction as starting material, yielding 72% of the total amylase activity in the low molecular weight fraction (UM-10 fraction: 10000–30000), while 54 and 25% respectively of the protease were retained in the two high molecular weight fractions (50000–100000, and more than 100000). Similar results were obtained with the 20–50% ammonium sulfate fraction, while the fraction of 0–20% saturation contained a low molecular weight protease. The native amylase seems to consist of a number of sub-units, which after extensive flushing accumulate in the fraction with an approximate molecular weight between 10000 and 30000. The enzyme could also be precipitated from cell-free liquid media with ammonium sulfate, followed by separation and purification on ultra-filtration cells. According to the specific activity of the UM-10 fractions a 400-fold purification was obtained compared to the amylase activity of the cell-free medium.Direct concentration and separation from liquid media, omitting ammonium sulfate treatment, was also found to be possible, although prolonged flushing with buffer was necessary to obtain satisfactory separation.During purification from the ammonium sulfate fractions, amylase activity was found to decrease but could be restored by Ca-ions. At 70°C, a final concentration of 0.5 mM CaCl₂, was sufficient for full restoration, while three times that amount was necessary at 80°C. Determination of the K _m-values for Ca at different temperatures resulted in an asymptotically increasing curve at temperatures beyond 75°C. Addition of Ca had a pronounced effect on the stability of the amylase at 80°C but not at 90°C. Protease activity and stability was not affected by Ca-ions.     

Solubilisation and mineralisation of [14C]lignocellulose from wheat straw by Streptomyces cyaneus CECT 3335 during growth in solid-state fermentation

Nine Streptomyces strains were screened for their ability to solubilise and mineralise ¹⁴C-labelled lignin during growth in solid-state fermentation. Streptomyces viridosporus was confirmed as an active lignin-degrading organism along with a new isolate, Streptomyces sp. UAH 15, further classified as Streptomyces cyaneus CECT 3335. This organism was able to solubilise and mineralise the [¹⁴C]lignin fraction of lignocellulose (44.96 ± 1.77% and 3.41 ± 0.48% respectively) after 21 days of incubation. Cell-free filtrates from Streptomyces sp. grown in solid-state fermentation were capable of solubilising up to 20% of the [¹⁴C]lignin after 2 days incubation, with most of the product detected in the acid-soluble rather than in the water-soluble fraction. Identification of the extracellular enzymes produced during growth of S. cyaneus CECT 3335 revealed that extracellular peroxidase and phenol oxidase activities were present, with the activity of phenol oxidase being 100 times greater than peroxidase activity. The activity of these two enzymes was found to correlate with both solubilisation and mineralisation rates. This is the first report of phenol oxidase activity produced by a Streptomyces strain during growth in solid-state fermentation. A role for the enzyme in the solubilisation and mineralisation of lignocellulose by S. cyaneus is suggested. Received: 12 May 1997 / Accepted: 19 May 1997     

A novel alkaline, thermostable, protease-free lipase from Pseudomonas sp.

An extracellular, alkali-tolerant, thermostable lipase was from a Pseudomonas sp. It had optimal activity at 65 °C and retained 75% of its activity at 65 °C for 90 min. The pH optimum was 9.6 and it retained more than 70% activity between pH 5 and 9 for 2 h. The culture broth was free of protease and, at 30 °C, the culture filtrate retained all the activity for at least 7 days, without any stabilizer. In shake flask culture, addition of groundnut oil (3 g l^–1) towards the end of growth phase increased the activity from 4 U ml^–1 to 8 ml^–1.     

Properties of extracellular proteases from three psychrotolerant Stenotrophomonas maltophilia isolated from Antarctic soil

Three Antarctic psychrotolerant Stenotrophomonas maltophilia were isolated and the characteristics of their extracellular serine proteases were described. The isolates were able to grow at 14 and 34°C, but grew better between 20 and 28°C. The highest protease secretion was reached at 20–24°C. The purified enzyme preparations had maximal activity at 55–60°C and alkaline pH. They showed high pH stability, retaining more than 60% of residual activity after 3 h of incubation at a pH range of 4–12. The thermal stability was slightly lower compared with a commercial mesophilic protease, with 74–79% residual activity after 90 min at 40°C and 50% inactivation at 50°C between 43 and 69 min. These properties suggest that the Antarctic isolates could be adapted to cold by means of synthesising more enzymes with high activity but that the proteases they produce are not truly cold-active, being more similar to mesophilic enzymes.     

Enhanced production and characterization of a highly thermostable alkaline protease from Bacillus sp. P-2

An obligatory alkalophilic Bacillus sp. P-2, which produced a thermostable alkaline protease was isolated by selective screening from water samples. Protease production at 30 °C in static conditions was highest (66 U/ml) when glucose (1% w/v) was used with combination of yeast extract and peptone (0.25% w/v, each), in the basal medium. Protease production by Bacillus sp. P-2 was suppressed up to 90% when inorganic nitrogen sources were supplemented in the production medium. Among the various agro-byproducts used in different growth systems (solid state, submerged fermentation and biphasic system), wheat bran was found to be the best in terms of maximum enhancement of protease yield as compared to rice bran and sunflower seed cake. The protease was optimally active at pH 9.6, retaining more than 80% of its activity in the pH range of 7–10. The optimum temperature for maximum protease activity was 90 °C. The enzyme was stable at 90 °C for more than 1h and retained 95 and 37% of its activity at 99 °C and 121 °C, respectively, after 1 h. The half-life of protease at 121 °C was 47 min.     

Two extracellular endoxylanases from alkaliphilic Bacillus firmus differ in their synthesis

To investigate the synthesis of two extracellular endoxylanases, xylan-binding and unbound xylanases from an alkaliphilic Bacillus firmus, washed cells were incubated in alkaline mineral salt media containing various carbon sources. The 23 kDa xylan-binding endoxylanase (XBE), which hydrolyses insoluble xylan, was produced before the 45 kDa, unbound endoxylanase. All the carbon sources tested at 5 mg ml^–1, including glucose, induced production of XBE but the unbound xylanase was totally repressed by glucose. The production of XBE increased when glucose concentration increased but was not synthesized until the glucose in the medium was less than 1 mg ml^–1.     

Polysaccharide synthesis by Phanerochaete chrysosporium during degradation of kraft lignin

Summary Phanerochaete chrysosporium (Sporotrichum pulverulentum) produced an extracellular glucan type polysaccharide when grown in a chemostat under nitrogen limitation. When cells were transferred to a standing mode of cultivation in the presence of excess glucose (6 gl^–1), the amount of non-glucose total carbohydrates in the culture increased from 0.58 gl^–1 to 1.76 gl^–1 during 15 day experiments. The change in total carbohydrates was due to an increase in extracellular and cell-bound glucan type polysaccharide. This increase occured simultaneously with formation of mycelial mats and appearance of ligninolytic activity. When the cultures were agitated under atmospheric oxygen rather than 100% O₂, their non-glucose total carbohydrate content increased to 2.15 gl^–1 in 4 days. The excess polysaccharide formation had an inhibitory effect on lignin degradation as more lignin was degraded by cells with lower polysaccharide content. The lignin that was associated with cells after the degradation had stopped could be further degraded by new active cells.     

Extracellular Glucose Oxidase of Penicillium funiculosum 46.1

A method for isolating extracellular glucose oxidase from the fungus Penicillium funiculosum 46.1 using ultrafiltration membranes was developed. Two samples of the enzyme with a specific activity of 914–956 IU were obtained. The enzyme exhibited a high catalytic activity at pH above 6.0. The effective rate constant of glucose oxidase inactivation at pH 2.6 and 16°C was 2.74 × 10^–6 s^–1. This constant decreased significantly as the pH of the medium increased (4.0–10.0). The temperature optimum for glucose oxidase–catalyzed -D-glucose oxidation was in the range 30–65°C. At temperatures below 30°C, the activation energy for -D-glucose oxidation was 6.42 kcal/mol; at higher temperatures, this parameter was equal to 0.61 kcal/mol. Kinetic parameters of glucose oxidase–catalyzed -D-glucose oxidation depended on the initial concentration of the enzyme in the solution. Glucose oxidase also catalyzed the oxidation of 2-deoxy-D-glucose, maltose, and galactose.     

Production and properties of xylanases from thermophilic actinomycetes

30 strains of xylanolytic thermophilic actinomycetes were isolated from composted grass and cattle manure and identified as members of the generaThermomonospora, Saccharomonospora, Microbispora, Streptomyces andActinomadura. Screening of these strains for extracellular xylanase indicated that strains ofSaccharomonospora andMicrobispora generally were poor xylanase producers (0.5–1.5 U/ml) whereas relatively high activities were observed in cultures ofStreptomyces andActionomadura (4–12 U/ml).A preliminary characterization of the enzymes of strains of the latter genera suggested that xylanases of all the strains ofActinomadura exhibited higher thermostabilities than those ofStreptomyces. To evaluate the potential of thermophilicActinomadura for industrial applications, xylanases of three strains were studied in more detail. The highest activity levels for xylanases were observed in cultures grown on xylan and wheat bran. The optimal pH and temperature for xylanase activities ranged from 6.0 to 7.0 and 70 to 80°C. The enzymes exhibited considerable thermostability at their optimum temperature. The half-lives at 75°C were in the range from 6.5 to 17h. Hydrolysis of xylan by extracellular xylanases yielded xylobiose, xylose and arabinose as principal products. Estimated by the amount of reducing sugars liberated the degree of hydrolysis was 55 to 65%. Complete utilization of xylan is presumably achieved by -xylosidase activities which could be shown to be largely cell-associated in the 3Actinomadura strains.     

Tannase production by Bacillus licheniformis

Bacillus licheniformis KBR 6 produced maximum extracellular tannase activity at 0.21 U ml^–1 with 1.5% (w/v) tannic acid either in the absence or presence of glucose (1 g l^–1) after 18–21 h growth though the organism did not attain maximum growth until 36 h.