An organic solvent-, detergent-, and thermo-stable alkaline protease from the mesophilic, organic solvent-tolerant Bacillus licheniformis 3C5

Bacillus licheniformis 3C5, isolated as mesophilic bacterium, exhibited tolerance towards a wide range of non-polar and polar organic solvents at 45 degrees C. It produced an extracellular organic solvent-stable protease with an apparent molecular mass of approximately 32 kDa. The inhibitory effect of PMSF and EDTA suggested it is likely to be an alkaline serine protease. The protease was active over abroad range of temperatures (45-70 degrees C) and pH (8-10) range with an optimum activity at pH 10 and 65 degrees C. It was comparatively stable in the presence ofa relatively high concentration (35% (v/v)) of organic solvents and various types of detergents even at a relatively high temperature (45 degrees C). The protease production by B. licheniformis 3C5 was growth-dependent. The optimization of carbon and nitrogen sources for cell growth and protease production revealed that yeast extract was an important medium component to support both cell growth and the protease production. The overall properties of the protease produced by B. licheniformis 3C5 suggested that this thermo-stable, solvent-stable, detergent-stable alkaline protease is a promising potential biocatalyst for industrial and environmental applications.     

A novel organic solvent-stable alkaline protease from organic solvent–tolerant Bacillus licheniformis YP1A

An organic solvent-stable alkaline protease producing bacterium was isolated from the crude oil contaminant soil and identified as Bacillus licheniformis. The enzyme retained more than 95% of its initial activity after pre-incubation at 40 °C for 1 h in the presence of 50% (v/v) organic solvents such as DMSO, DMF, and cyclohexane. The protease was active in a broad range of pH from 8.0 to 12.0 with the optimum pH 9.5. The optimum temperature for this protease activity was 60 °C, and the enzyme remained active after incubation at 50–60 °C for 1 h. This organic solvent-stable protease could be used as a biocatalyst for organic solvent-based enzymatic synthesis.     

A novel nonionic surfactant- and solvent-stable alkaline serine protease from <Emphasis Type="Italic">Serratia</Emphasis> sp. SYBC H with duckweed as nitrogen source: production,purification, characteristics and application

A novel nonionic surfactant- and hydrophilic solvent-stable alkaline serine protease was purified from the culture supernatant of Serratia sp. SYBC H with duckweed as nitrogen source. The molecular mass of the purified protease is about 59 kDa as assayed via SDS-PAGE. The protease is highly active over the pH range between 5.0 and 11.0, with the maximum activity at pH 8.0. It is also fairly active over the temperature range between 30 and 80°C, with the maximum activity at 40°C. The protease activity was substantially stimulated by Mn²⁺ and Na⁺ (5 mM), up to 837.9 and 134.5% at 40°C, respectively. In addition, Mn²⁺ enhanced the thermostability of the protease significantly at 60°C. Over 90% of its initial activity remained even after incubating for 60 min at 40°C in 50% (v/v) hydrophilic organic solvents such as DMF, DMSO, acetone and MeOH. The protease retained 81.7, 83.6 and 76.2% of its initial activity in the presence of nonionic surfactants 20% (v/v) Tween 80, 25% (v/v) glycerol and Triton X-100, respectively. The protease is strongly inhibited by PMSF, suggesting that it is a serine protease. Washing experiments revealed that the protease has an excellent ability to remove blood stains.     

Screening and identification of a novel organic solvent-stable lipase producer

A strain named DS9 excreting organic solvent-stable lipase was screened and later identified asBacillus subtilis based on its phenotypes, biochemical test, and 16S rRNA gene sequence. Strain DS9 grows well on the medium with 10% (v/v) organic solvent with log P values equal to or above 2.5. The organic solvent-tolerant lipase excreted by strain DS9 had a wider tolerance for organic solvents. The relative activity of the lipase was above 60% at 37 °C, 200 rpm, 30 min in the present of 25% (v/v) organic solvents such as 1-butanol, hexanol, benzene, and toluene. The lipase was not only stable but also activated by n-hexane, xylene, heptane, isooctane, and n-decane. The optimal pH and temperature were 8.0 and 40 °C, respectively. Both the organic solvent-tolerant microorganism and the organic solvent-stable lipase produced by this strain could be used as a biocatalyst for application in non-aqueous biocatalysis.     

Nutritional factors affecting organic solvent-tolerant alkaline protease production by a newBacillus cereus strain 146

An organic solvent-tolerant bacterium designated as 146 capable of producing an organic solvent-stable alkaline protease was isolated from contaminated soil of a wood factory. The strain was a Gram-positive, spore-forming, nitrate-positive, rod-shaped organism capable of hydrolysing gelatine, starch, skim milk and identified asBacillus cereus. Activity of the protease was drastically increased in the presence of 1–decanol, isooctane, n-dodecane and n-tetradecane, but reduced in the presence of ethyl acetate, benzene, toluene, 1-heptanol, ethylbenzene and hexane. The bacterium was shown to require lactose as a carbon source and peptone as a nitrogen source. The optimum fermentation condition for the production of alkaline protease was in the presence of beef and yeast extract. Optimum pH was determined to be at 10.0 at incubation temperature of 37 °C for 48 h. Results from the studies suggest that 146 is a new strain of Bacillus cereus capable of producing organic solvent-tolerant alkaline protease with potential use in industries.     

Physical factors affecting the production of organic solvent-tolerant protease by Pseudomonas aeruginosa strain K

The physical factors affecting the production of an organic solvent-tolerant protease from Pseudomonas aeruginosa strain K was investigated. Growth and protease production were detected from 37 to 45 degrees C with 37 degrees C being the optimum temperature for P. aeruginosa. Maximum enzyme activity was achieved at static conditions with 4.0% (v/v) inoculum. Shifting the culture from stationary to shaking condition decreased the protease production (6.0-10.0% v/v). Extracellular organic solvent-tolerant protease was detected over a broad pH range from 6.0 to 9.0. However, the highest yield of protease was observed at pH 7.0. Neutral media increased the protease production compared to acidic or alkaline media.     

An organic solvent-tolerant protease from Pseudomonas aeruginosa strain K: Nutritional factors affecting protease production

An organic solvent-tolerant bacterium producing an organic solvent-stable protease was isolated from soil and identified as Pseudomonas aeruginosa strain K. Nutritional requirements for optimized protease production by this strain were investigated. Maximum protease activity was achieved with sorbitol as the sole carbon source, followed by starch and lactose at pH 7.0 and 37 °C. Dextrose, sucrose and glycerol greatly reduced the protease production. The best organic nitrogen source was casamino acid. Tryptone, soytone and yeast extract supported protease production while corn steep liquor and beef extract inhibited the protease activity. Significant protease production was observed with sodium nitrate as a sole nitrogen source however, ammonium nitrate completely inhibit it. More than 62% drop in production occurred in the presence of amino acids. Addition of metal ions such as K⁺, Mg²⁺ and Ca²⁺ maximized the enzyme production.     

Utilization of tannery solid waste for protease production by Synergistes sp. in solid‐state fermentation and partial protease characterization

Synergistes sp. DQ560074 produced a protease in submerged fermentation (SmF) at 400–420 U/mL and in solid‐state fermentation (SSF) at 745–755 U/g. The protease, which belongs to the aspartic protease class, was active over a wide range of pH (5–7) and at high temperatures (25–45°C). The protease is stable and active in various polar protic solvents (50% v/v) like ethanol, isopropanol, n–butanol, in polar aprotic solvents (50% v/v) like acetonitrile, and in non‐polar solvents (50% v/v) such as ethylacetate and toluene, but not in hydrophilic organic solvents (methyl alcohol and acetone). As far as we know, this is the first contribution to the production of a mesophilic protease with solvent stability in SSF using a proteinaceous solid waste.     

Optimization of novel and greener approach for the coproduction of uricase and alkaline protease in Bacillus licheniformis by Box–Behnken model

This study explores a novel concept of coproduction of uricase and alkaline protease by Bacillus licheniformis using single substrate in single step. Seven local bacterial strains were screened for uricase production, amongst which B. licheniformis is found to produce highest uricase along with alkaline protease. Optimization of various factors influencing maximum enzyme coproduction by B. licheniformis is performed. Maximum enzyme productivity of 0.386?U/mL uricase and 0.507?U/mL alkaline protease is obtained at 8?hr of incubation period, 1% (v/v) inoculum, and at 0.2% (w/v) uric acid when the organism is cultivated at 25°C, 180?rpm, in a media containing xylose as a carbon source, urea as a nitrogen source, and initial pH of 9.5. The statistical experimental design method of Box–Behnken was further applied to obtain optimal concentration of significant parameters such as pH (9.5), uric acid concentration (0.1%), and urea concentration (0.05%). The maximum uricase and alkaline protease production by B. licheniformis using Box–Behnken design was 0.616 and 0.582?U/mL, respectively, with 1.6- and 1.13-fold increase as compared to one factor at a time optimized media. This study will be useful to develop an economic, commercially viable, and scalable process for simultaneous production of uricase and protease enzymes.     

Isolation and identification of alkaline protease producer halotolerantBacillus licheniformis strain BA17

An alkaline protease producerBacillus licheniformis strain was isolated from Van Lake in Turkey. The strain is Gram positive, aerobic, motile, sporulating rod-shaped bacterium. Spores were ellipsoidal and positioned central in nonswollen sporangium. The cells were able to grow well at a pH range of 5.7–10. The optimal growth temperature was found to be 37 °C. Growth at a wide range of NaCl concentration (from 0 to 20%) showed that BA17 is halotolerant. Main fatty acid composition of BA17 was anteiso-C15:0 and iso-C15∶0. The strain was presumptively identified asB. licheniformis according to 16S rDNA gene sequence analysis. The most appropriate medium for the growth and protease production is composed of 0.5% yeast extract, 0.5% NaNO₃, 0.02% MgSO₄\7H₂O, 0.1% K₂HPO₄ and 0.5% maltose. The optimum temperature and pH of the alkaline protease of strain BA17 were found to be 60 °C and pH 11, respectively. The activity was completely lost in the presence of PMSF, suggesting that the preparation contains serine-alkaline protease(s).     

Ecological significance and some biotechnological application of an organic solvent stable alkaline serine protease from Bacillus subtilis strain DM-04

An organic solvent stable, alkaline serine protease (Bsubap-I) with molecular mass of 33.1 kDa, purified from Bacillus subtilis DM-04 showed optimum activity at temperature and pH range of 37–45 °C and 10.0–10.5, respectively. The enzyme activity of Bsubap-I was significantly enhanced in presence of Fe²⁺. The thermal resistance and stability and of Bsubap-I in presence of surfactants, detergents, and organic solvents, and its dehairing activity supported its candidature for application in laundry detergent formulations, ultrafiltration membrane cleaning, peptide synthesis and in leather industry. The broad substrate specificity and differential antibacterial property of Bsubap-I suggested the natural ecological role of this enzyme for the producing bacterium.     

Highly soluble expression and molecular characterization of an organic solvent-stable and thermotolerant lipase originating from the metagenome

A novel organic solvent-stable and thermotolerant lipase gene (designated ostl28) was cloned from a metagenomic library and overexpressed in Escherichia coli BL21 (DE3) in soluble form. OSTL28 contained 262 amino acids with relative molecular mass 30.1 kDa and isoelectric point 9.7. The optimum pH and temperature of the OSTL28 were 7.5 and 60 °C, respectively. OSTL28 was stable in the pH range of 4.5–9.5 and at temperatures below 65 °C. The enzyme could hydrolyze a wide range of ρ-nitrophenyl esters, but its best substrate is ρ-nitrophenyl laurate with the highest activity of 236 U/mg (54,000 U/L). The recombinant OSTL28 was highly resisted to organic solvents, especially glycerol and methanol. The metal ions, with the exception of Hg²⁺ and Ag⁺, did not have any influence on enzyme activity, whereas non-ionic surfactants and Al³⁺ slightly activated the enzyme. These features indicate that it is a potential biocatalyst for biodiesel production.     

Purification and characterization of a novel extracellular halophilic and organic solvent-tolerant amylopullulanase from the haloarchaeon, Halorubrum sp. strain Ha25

A halophilic archaeon, Halorubrum sp. strain Ha25, produced extracellular halophilic organic solvent-tolerant amylopullulanase. The maximum enzyme production was at high salt concentration, 3–4 M NaCl. Optimum pH and temperature for enzyme production were 7.0 and 40 °C, respectively. Molecular mass of purified enzyme was estimated to be about 140 kDa by SDS–PAGE. This enzyme was active on pullulan and starch as substrates. The apparent K _m for the enzyme activity on pullulan was 4 mg/ml and for soluble starch was 1.8 mg/ml. Optimum temperature for amylolytic and pullulytic activities was 50 °C. Optimum pH for amylolytic activity was 7 and for pullulytic activity was 7.5. This enzyme was active over a wide range of concentrations (0–4.5 M) of NaCl. The effect of organic solvents on the enzyme activities showed that this enzyme was more stable in the presence of non-polar organic solvents than polar solvents. This study is the first report on amylopullulanase production in halophilic bacteria and archaea.     

Thermostable alkaline protease from newly isolated <Emphasis Type="Italic">Vibrio</Emphasis> sp.: extraction,purification and characterisation

An extracellular alkaline protease-producing Vibrio sp. was isolated from mangrove sediments of Vellar estuary. A 9.36-fold purification was achieved by a three-step purification procedure and the molecular weight of the enzyme was determined as 33 kDa by SDS-PAGE. The enzyme was active in a broad range of pH (6.0–11.0) and temperature (30–70°C), the optimum being at pH 9.0 and temperature 55°C. The enzyme was stable at alkaline pH range of 9–11 and up to a temperature of 60°C, after incubation for 1 h. Metals like Co²⁺, Hg²⁺, Ni²⁺ and Cu²⁺ inhibited the enzyme activity, whereas Fe²⁺, Ca²⁺ and Mn²⁺ were found to enhance the activity. The protease was found to be highly stable in the presence of oxidizing agents like H₂O₂, detergents such as SDS and Triton-X-100 and also some of the commonly used commercial detergents. The organic solvents like xylene, isopropanol, hexane and benzene were found to enhance as well as stabilize the enzyme activity. The extracellular production of the enzyme, the pH and thermal stability, and the stability in presence of oxidants, surfactants, commercial detergents and organic solvents, altogether suggest that it can be used as a laundry additive.     

Studies on α-amylase production by Bacillus licheniformis MIR-61

An acid α-amylase hyperproducing strain, designated as MIR-61, was isolated in a screening procedure from South American soil samples. MIR-61, a 60°C thermoresistant strain, was identified using 98 biochemical and morphological tests and characterized as Bacillus licheniformis by numerical taxonomy. Batch cultures of B. licheniformis MIR-61 showed extracellular α-amylase and α-glucosidase activities during the exponential growth phase. The production of α-amylase was studied at free and constant pH values at 37 and 45°C. Maximum α-amylase activity (4,767 kU/dm³ in a liquid medium) was detected at 45°C at a constant pH (7.0) in the late exponential phase. The α-amylase production by B. licheniformis MIR-61 is 10 to 300 times higher than the enzyme production reported in strains of the same species. Optimum α-amylase activity was found at 50 to 67°C in an acid pH range from 5.5 to 6.0. These properties would allow its use in starch industry processes.     

Organic solvent tolerance of an alkaline protease from salt-tolerant alkaliphilic <Emphasis Type="Italic">Streptomyces clavuligerus</Emphasis> strain Mit-1

A salt-tolerant alkaliphilic actinomycete, Mit-1 was isolated from Mithapur, coastal region of Gujarat, India. The strain was identified as Streptomyces clavuligerus and based on 16S rRNA gene sequence (EU146061) homology; it was related to Streptomyces sp. (AY641538.1). The organism could grow with up to 15% salt and pH 11, optimally at 5% and pH 9. It was able to tolerate and secrete alkaline protease in the presence of a number of organic solvents including xylene, ethanol, acetone, butanol, benzene and chloroform. Besides, it could also utilize these solvents as the sole source of carbon with significant enzyme production. However, the organism produced spongy cell mass with all solvents and an orange brown soluble pigment was evident with benzene and xylene. Further, the enzyme secretion increased by 50-fold in the presence of butanol. With acetone and ethanol; the enzyme was highly active at 60–80°C and displayed optimum activity at 70°C. The protease was significantly stable and catalyzed the reaction in the presence of xylene, acetone and butanol. However, ethanol and benzene affected the catalysis of the enzyme adversely. Crude enzyme preparation was more stable at 37°C in solvents as compared to partially purified and purified enzymes. The study holds significance as only few salt-tolerant alkaliphilic actinomycetes are explored and information on their enzymatic potential is still scares. To the best of our knowledge this is the first report on organic solvent tolerant protease from salt-tolerant alkaliphilic actinomycetes.     

Purification and characterization of solvent stable,alkaline protease from Bacillus firmus CAS 7 by microbial conversion of marine wastes and molecular mechanism underlying solvent stability

A marine bacterium Bacillus firmus CAS 7 produced protease in the medium supplemented with 3:1 shrimp and crab shell powder at 55 °C and was purified with the specific activity of 473.4 U/mg. The purified protease was highly stable up to 70 °C, pH 11.0 and 30% NaCl. The protease purified was quite stable in the presence of anionic and non-ionic surfactants and organic solvents. The molecular dynamics simulation confirmed that the competition between organic solvent and water for the enzyme surface was comparatively higher in water–miscible organic solvent which is responsible for organic solvent stability. The purified protease from B. firmus CAS 7 could be greatly useful to develop industrial processes performed under harsh conditions or with denaturants and organic solvents. The protease production by microbial conversion of marine wastes suggested its potential utilization to generate high value-added products.     

Thermostable alkaline proteases of Bacillus licheniformis MIR 29: isolation,production and characterization

 Bacillus licheniformis MIR 29 has been isolated and produces extracellular proteases. It is able to grow at temperatures up to 60 °C and at pH values up to 9.0. Casein was the best carbon source for production of a thermostable protease activity which, in some conditions, is 90% extracellular. The synthesis of alkaline protease is not constitutive; different levels of production were found with different carbon and nitrogen sources. Casein was thought to be an inducer of enzyme synthesis. The optimal pH and temperature of the enzyme activity were 12 °C and 60 °C, respectively. The enzyme was stable up to 60 °C in the absence of stabilizers. The protease activity was inhibited with phenylmethylsulphonyl fluoride, indicating a serine-protease activity. The proteolytic activity was lowered by molecules present in the culture supernatant, which include amino acids and peptides, indicating end-product inhibition. Electrophoresis assay on denaturating gels showed two bands with alkaline protease activity, in the 25 to 40-kDa molecular mass range. Received: 7 June 1995/Received revision: 14 September 1995/Accepted: 20 September 1995     

Production and characterization of a solvent-tolerant protease from a novel marine isolate Bacillus tequilensis P15

Thirty-six proteolytic bacteria were isolated from the Jakhau coast, Kutch, India, amongst which isolate P15 identified as Bacillus tequilensis (JQ904626) was found to produce an extracellular solvent-- and detergent-tolerant protease (116.69?±?0.48 U/ml) and was selected for further investigation. Deoiled Jatropha seedcake (JSC) was found to be a suitable substrate for protease production under submerged condition. Upon optimization of process parameters following one-factor-at-a-time approach, an overall 6.4-fold (860.27?±?18.48 U/ml) increase in protease production was achieved. The maximum protease yield was obtained using a medium containing 2 % (w/v) deoiled JSC as substrate (pH of 8.0) upon 36 h of fermentation at 30 °C. The optimum temperature and pH for activity of B. tequilensis P15 protease was found to be 50 °C and 8.0, respectively. The enzyme exhibited a half-life of 190 min at 50 °C, which was enhanced to 270 min in presence of 5 mM Ca²⁺. The enzyme exhibited significant stability in almost all the solvents tested in the range of log P _ow varying from 8.8 to ?0.76. The enzyme activity was strongly inhibited by PMSF at 5 mM concentration, whereas the presence of EDTA (5 mM) and pCMB (5 mM) enhanced enzyme activity by 20.9 and 13.7 %, respectively. The enzyme was also found to be stable in the presence of surfactants, commercial detergents and bleach-oxidant (H₂O₂). This protease was demonstrated to be effective in removal of blood stains from fabrics, dehairing of hide, and stripping off the gelatin from used photographic films.     

Cloning and characterization of a novel GH44 family endoglucanase from mangrove soil metagenomic library

A novel endoglucanase gene, mgcel44, was isolated from a mangrove soil metagenomic library by functional-based screening. It encodes a 648-aa peptide with a catalytic domain of glycosyl hydrolase family 44. The deduced amino acid sequence of mgcel44 shares less than 50 % identity with endoglucanases in GenBank database. mgcel44 was cloned and overexpressed in Escherichia coli. The recombinant enzyme, MgCel44, has a molecular mass of 70.8 kDa as determined by SDS-PAGE. Its optimal pH and temperature for activity were 6 and 45 °C, respectively. It was highly active at 25–45 °C and pH 5–8. Its activity was enhanced in 0.5 M NaCl by >1.6-fold and stable up to 1.5 M NaCl. MgCel44 was resistant to several organic solvents and had high activity at 15 % (v/v) solvent after incubating for 24 h at 25 °C.