Acessibilidade / Reportar erro

Enhanced production of alkaline protease by a mutant of Bacillus licheniformis N-2 for dehairing

Abstract

The purpose of the present investigations was to improve the yield of alkaline protease for leather dehairing by subjecting the indigenous proteolytic strain Bacillus licheniformis N-2 to various mutagenic treatments viz. UV irradiations, NTG (N-methyl-N-nitro-N-nitrosoguinidine) and MMS (methyl methane sulfonate). After screening on skim milk agar plates, a total of nine positive mutants were selected for shake flask experiments. Among these, the best proteolytic mutant designated as UV-9 showed 1.4 fold higher alkaline protease activity in preoptimized growth medium than the parent strain. The fermentation profile and kinetic parameters such u(h-1), Yp/s, Yp/x, Yx/s, q s, Qs, q p and Qp also indicated the superiority of the selected mutant UV-9 for alkaline protease production over the parent strain and rest of the mutants. The dehairing capability of mutant UV-9 alkaline protease was analyzed by soaking goat skin pieces for different time intervals (3-15 h) at 40 º C. A complete dehairing without degradation of collagen was achieved after 12 h, indicating its commercial exploitation in leather industry.

Bacillus mutants; mutagenic treatments; alkaline protease; dehairing agent


AGRICULTURE, AGRIBUSINESS AND BIOTECHNOLOGY

Enhanced production of alkaline protease by a mutant of Bacillus licheniformis N-2 for dehairing

Muhammad NadeemI,* * Author for correspondence: mnadeempk@yahoo.com ; Javed Iqbal QaziII; Shahjahan BaigI

IBiotechnology and Food Research Center; PCSIR Laboratories Complex; Lahore-54600; Pakistan

IIDepartment of Zoology; University of the Punjab; Lahore-54590; Pakistan

ABSTRACT

The purpose of the present investigations was to improve the yield of alkaline protease for leather dehairing by subjecting the indigenous proteolytic strain Bacillus licheniformis N-2 to various mutagenic treatments viz. UV irradiations, NTG (N-methyl-N-nitro-N-nitrosoguinidine) and MMS (methyl methane sulfonate). After screening on skim milk agar plates, a total of nine positive mutants were selected for shake flask experiments. Among these, the best proteolytic mutant designated as UV-9 showed 1.4 fold higher alkaline protease activity in preoptimized growth medium than the parent strain. The fermentation profile and kinetic parameters such u(h-1), Yp/s, Yp/x, Yx/s, qs, Qs, qp and Qp also indicated the superiority of the selected mutant UV-9 for alkaline protease production over the parent strain and rest of the mutants. The dehairing capability of mutant UV-9 alkaline protease was analyzed by soaking goat skin pieces for different time intervals (3-15 h) at 40 º C. A complete dehairing without degradation of collagen was achieved after 12 h, indicating its commercial exploitation in leather industry.

Key words:Bacillus mutants, mutagenic treatments, alkaline protease, dehairing agent

INTRODUCTION

Leather is one of the most dynamic sectors, in Pakistan, after cotton and textile industries where almost all the industries use lime and sulphide to remove hairs from hides and skins. Despite making significant contributions to the economy, the leather industry causes sever environment pollution due to the use of various chemicals and release of several detrimental materials (Pvanakrishnan and Dhar, 1986; Meraz et al., 2006). The process of leather processing contributes 80-90% of the total pollution in the leather industry and generates noxious gases as well as solid waste e.g. hydrogen sulphide and lime (Thanikaivelan et al., 2004). Many cases of deaths have also been reported due to these toxic chemicals (Balasubramanian and Pugalenthi, 2000). Alkaline protease can be used as an alternative to sulphide.

The alkaline protease enables the swelling of hair roots, subsequently attacks hairs follicle protein and then allows easy removal of hairs (Guptaet al., 2002). Microorganisms are attractive source of proteases because of their biochemical diversity and the ease of genetic manipulation. A large proportion of the alkaline proteases are derived from the microorganisms especially from Bacillus strains (Puri et al., 2002; Huang et al., 2003). The amount of protease produced from microorganisms depends on the nature of strains and the composition of the growth medium (Nadeem et al., 2006; Nadeem et al., 2007).

A hyper-productive organism growing on an economical substrate is the prime need of any fermentation process. Mutation can play an important role in improving the yield of alkaline protease with excellent dehairing effect (Wang et al., 2007). However, many of the proteases with high unit activities have faced failure for successful application because they could not meet the specific requirements of different industrial process. With respect to dehairing protease, the enzyme should exhibit remarkable capabilities of dehairing without damaging the fibrous collagen (Macedo et al., 2005). Considering these facts, the present attempt was made to develop hyper-productive organisms by employing different mutation techniques. The best proteolytic mutant was selected after comprehensive screening study. The alkaline protease produced from a selected mutant was used as dehairing agent against goat skins to assess its potential applications in leather industries.

MATERIALS AND METHODS

Microorganism and culture maintenance

Bacillus licheniformis N-2, a wild strain isolated from decaying organic soil sample was used in this study (Nadeem et al., 2007). The culture of B. licheniformis N-2 and its mutants were grown on nutrient agar (Oxoid) slants at 37º C for 24 h and then preserved at 4º C for one month. The slants were sub-cultured routinely after an interval of 4-5 weeks to revive the culture.

Preparation of cell suspension

A 24 h old loopful culture of B. licheniformis N-2 was transferred from slant into 50 mL nutrient broth (Oxoid) and incubated at 37º C for 12 h at 140 rpm in water bath shaker (Eyela, Japan). After that, 10 mL of the inoculated broth was centrifuged at 9000 x g for 10 min at 4º C to separate the cell biomass. The cell biomass pellet was then dissolved in 10 mL sterilized normal saline under aseptic conditions to prepare cell suspension (approximately 108-10 cells/mL) for subsequent experiments.

Mutagenesis by UV treatment

Various serial dilutions of cell suspension were prepared and the dilution 10-7/mL was distributed into different sterilized glass Petri plates (2 mL in each Petri plate). These plates were exposed to UV radiations (254 nm) for variable time intervals ranging from 5 to 120 min in UV chamber keeping the distance of UV source fixed at 11.5 cm. After required exposer, the sterilized nutrient agar media (Oxoid) were poured into each Petri plate and the plates were placed in dark for 2 h to stabilize the nutrient agar medium. Then the plates were incubated at 37º C for 48 h and the % of survival was calculated over the control (plate was kept aside in dark without UV treatment).

Mutagenesis by NTG (N-methyl-N-nitro-N-nitrosoguinidine) and MMS (methyl methane sulfonate) treatments

One milliliter of cell suspension was taken in different test tubes. Then 1 mL each of NTG (1 mg/mL) and MMS (100 uL/mL) was added in respective test tube except control. The treated cell suspensions were incubated at 37º C for different time intervals (15-120 min) to determine the survival rate. After required period of treatment, the cells were centrifuged at 9000 x g for 10 min at 4º C, washed with sterilized normal saline twice, diluted and poured into the sterilized Petri plates. After keeping in dark for 2 h, these Petri plate were incubated at 37º C for 48 h and the plates having minimum % of survival rate over the control (without treatment) were selected for screening of hyper-proteolytic mutants.

Screening of hyper-proteolytic mutants

After various mutagenic treatments, all the selected isolates were streaked on skim milk agar plates. The skim milk agar medium was composed of (g/L): skim milk (10), peptone (1), sodium chloride (5), and agar (20). The pH of the medium was adjusted at 10 with 1N HCl / NaOH before sterilization at 121º C for 15 min. The streaked skim milk agar medium plates were incubated at 37º C for 24 h and the isolates exhibiting maximum zone of hydrolysis as compared to wild type were selected for further study.

Enzyme production study

Shake flask experiments were carried out in 250 mL Erlenmeyer flasks with 50 mL of growth media for comparative evaluation of enzyme production by wild stain of B. licheniformis N-2 and the selected hyper-proteolytic mutants.

Inoculum preparation

Inocula were prepared by transferring a loopful of 24 h old wild type and selected mutant cultures in 50 mL of inoculum medium comprising of (g/L): glucose (5), soybean meal (10), K2HPO4 (5), MgSO4.7H2O (5), NaCl (0.5) and CaCl2.2H2O (0.5). The pH of the inoculum medium was adjusted at 10 before sterilization at 121º C for 15 min. The inoculated broths were incubated in water bath shaker (Eyela, Japan) at 140 rpm for 24 h at 37º C for the propagation of bacteria up to 108-10 cells/mL.

Cultivation of the growth medium

The growth medium contaning (g/L): glucose (10), soybean meal (10), K2HPO4 (5), MgSO4.7H2O (0.5), NaCl (0.5) and CaCl2.2H2O (0.5) was inoculated with 24 h old inoculum (2 %, v/v) of wild type as well as mutant cultures. The pH of the growth medium was adjusted at 10 with 1N HCl / NaOH before sterilization at 121º C for 15 min. The inoculated growth broths were incubated at 37º C for 24 h in water bath shaker (Eyela, Japan) with agitation speed of 140 rpm. After that the fermented broth was centrifuged at 9000 x g at 4º C for 10 min to get the clear enzyme solution.

Determination of kinetic parameters

Different kinetic parameters for biomass and enzyme yield were determined according to the methods described by Pirt (1975) and Okpokwasili and Nweke (2005). All these kinetic parameters viz. Yp/s, Yp/x, Yx/s, u (h-1), qs, Qs, qp and Qp were studied at pre-optimized culture conditions in batch fermentation process.

Total Viable count

Total viable count after proper dilution was determined according to the method illustrated by Eaten et al. (2005).

Estimation of dry cell biomass

The biomass contents were determined by measuring the dry weight from a known amount of sample centrifuged at 9000 x g for 10 min at 4º C and the cell pellet was washed three times with normal saline to remove the suspended particles. The washed sample was then dried at 105º C till the constant weight was obtained.

Analytical procedures

Determination of proteolytic activity

Alkaline protease activity was determined by using 1.0% (w/v) casein solution as a substrate in 0.05 M glycine-NaOH buffer at pH 11.0 (Yang and Huang, 1994). The substrate was treated with a known amount of enzyme solution for 15 min at 60º C. One proteolytic unit (PU) was defined as amount of the enzyme that released 1ug of tyrosine/mL/min under the assay conditions.

Estimation of extracellular protein contents

The total protein contents of the samples were determined by the method of Lowry using bovine serum albumin (BSA) as a reference standard (Lowry et al., 1951).

Estimation of Glucose contents

Glucose contents were determined according to the phenol-sulfuric acid method described by Dubois et al. (1956).

Application of alkaline protease as a dehairing agent

Dehairing property of alkaline protease was observed by a slightly modified method of Wang et al. (2007). Salted goat skin was obtained from local market, washed and cut into different small pieces (5x5cm2 sizes). These pieces were soaked in alkaline protease produced by mutant B. licheniformis UV-9 and incubated at 40º C in water bath shaker with agitation speed of 100 rpm for different time periods (3-15 h). After required period, the skin pieces were gently scrapped with fingers to remove the loose hairs because the mechanical treatment at the laboratory scale was not as vigorous as in industrial drums. The dehairing efficacy was assessed according to the depilated area of the skin at various time intervals and the quality of the dehaired skin was estimated according the physical appearance observed by naked eyes. The dehaired skin with high quality showed clear hair pore, clear grain structure and no collagen damage.

Chemicals and Statistical analysis

All the chemicals used in this study were of analytical grade. Each experiment was carried out independently in triplicates in 250 mL Erlenmeyer flasks and the standard deviation (SD) was calculated by using Microsoft Excel Program.

RESULT AND DISCUSSION

Effect of different mutagens on survivability of B. licheniformis N-2

The mutation and screening of commercially viable microorganisms are important for the successful development of various strains required in the fermentation industry. Therefore, the parent strain B. licheniformis N-2 was treated with different mutagens like UV irradiation, NTG (N-methyl-N-nitro-N-nitrosoguinidine) and MMS (methyl methane sulphonate) to improve its productivity. In case of UV irradiation treatment, 32.80% survival rate was obtained after 15 min exposure which decreased gradually with the increase of exposure time and became 0% after exposure of 120 min (Table 1). Similarly, the culture of B. licheniformis N-2 was treated with NTG and MMS at concentrations of 1 mg/mL and 100 uL/mL, respectively. Survival rate of 0.12% was examined with NTG at 1 mg/mL concentration after an exposure of 120 min (Table 2).

The survival rate with MMS at 100ug/mL concentration for same exposure time was 0 % (Table 3). Similar trend of decrease in survivability with increase in exposure time has also been reported by some other investigators (Meraz et al., 2005; Dutta et al., 2006). UV irradiation and MMS mutagen were found more affective against B. licheniformis N-2 culture as compared to NTG. The desirable mutants of B. subtilis for enzyme production after MNNG treatment have been demonstrated in an earlier investigation (Cheng-gang et al., 2008). All these findings indicated that the survivability of parent strain depended on the nature of the microorganism, treatment period and the type of mutagens.

Selection of hyper-proteolytic mutant

From UV treated plates, 14 mutants of 60 and 90 min exposures were selected for screening on skim milk agar plates. Similarly, 11 and 14 mutants from NTG and MMS treatments, respectively were selected for visualizing the efficiency of their extracellular protease. Nine hyper-proteolytic mutants (3 from each mutagenic treatment) known as positive mutants were primarily selected on the basis of zone of clearance on skim milk agar plates (Table 4).

These mutants were further evaluated through shake flask enzyme production studies at preoptimized culture conditions over the parent strain of B. licheniformis N-2. Among these, the maximum alkaline protease production (1384 PU/mL) was observed for the mutant UV-9 followed by MMS-14 and UV-13, producing 1280 and 1260 PU/mL alkaline protease, respectively (Table 5). The results showed that the UV-9 was the most hyper-active mutant, giving approximately 1.4 fold more alkaline protease over the parent strain (991 PU/ mL) in similar culture conditions. Shikha et al. (2007) reported 1.44 fold increase in alkaline production over the parent strain of B. pantotheneticus. Dutta and Banerjee (2006) observed 2.5 fold increased in alkaline protease production by UV mutant Pseudomonas sp. JNGR242. Rao et al. (1998) reported that mutagenesis either by conventional methods or by recombinant-DNA technology played an important role in improving the yield of protease. It was also observed that the mutagenic treatment also affected the shapes and sizes of the mutants colonies. Almost half of the colonies showed flat growth pattern with smooth outline on skim milk agar plates while the remaining colonies showed small, dense and wrinkle growth. The smaller colony sizes suggested repression in growth of mutants. The difference in colony size could also be attributed to other mutations or structural defects in other enzymes, such as fatty acid synthetase as described by Zhang and Yoshiyuki, (1993). The results of present study illustrated that the dense and wrinkled mutant usually gave higher yield of protease as shown by zone of clearance Fig. 1. Nehete et al. (1985) reported similar observations that rough and wrinkled B. licheniformis mutants produced higher yield of alkaline protease.


The mutant UV-9 also showed enhanced alkaline protease productivity in term of yield coefficients (Table 5). The yield coefficients Yp/s (201 PU/g glucose consumed) and Yp/x (393 PU/g of cell biomass formed) of mutant UV-9 was found much improved as compared to the parent strain and the rest of mutants. These findings indicated that mutation by UV irradiations played an important role in strain improvement for commercial exploitation and the mutant UV-9 was selected as a best positive mutant for alkaline protease production after the intensive screening studies.

Comparative analysis of glucose consumption by parent strain and UV-9 in submerged batch fermentation process

The cost of the enzyme is a major obstacle for its production and application at commercial scale. Therefore, the microorganisms with high yield of protease and less consumption of metabolizable sugar are a vital choice for the enzyme production at commercial scale.

To analyze the glucose consumption and protease production, batch fermentation was carried out in shake flasks cultures and the samples were collected up to 48 h with a constant interval of 4 h.

Maximum yield of alkaline protease (1384 PU/mL) was obtained by the mutant UV-9 after 24 h even when 3.14 g/L glucose remained in the medium (Fig. 2). The wild type strain utilized glucose faster than the mutant and consumed almost complete glucose (9.98 g/L) and gave maximum yield of alkaline protease (991 PU/mL) after 24 h of incubation. These findings indicated that UV-9 mutant produced 1.4 fold more alkaline protease over the parent strain at 24 h of incubation. However, the similar pattern of reduction in enzyme production was observed in both UV-9 mutant and wild type B. licheniformis N-2 after 24 h incubation. Higher cell biomass (3.84 g/L) was observed in case of wild type than mutant UV-9 that might be due to rapid consumption of glucose. The consumption rate of glucose by UV-9 mutant was observed very slow and 2.65 g/L still remained in the growth medium after 48 h of fermentation, indicating that UV-9 mutant might be insensitive to catabolite repression. Sunitha et al. (1999) reported similar pattern of glucose consumption for alkaline protease biosynthesis by a mutant strain of Thermoactinomyces sp. E 79. Bierbaum et al. (1994) also used UV-mutation approach for B. licheniformis to improve the yield of alkaline protease and make the microorganism insensitive to catabolite repression.


During kinetic studies, the values of substrates consumption rates (qs and Qs) were found higher in case of parent strain, indicating more consumption of substrate for its growth as compared to the mutant UV-9 (Table 6). On the other hand, the values of product formation parameters (qp and Qp) were found higher in case of mutant UV-9. These results revealed that the higher productivity rate of UV-9 with less substrate consumption could make the process of alkaline protease production economically more feasible for the mutant UV-9 over the parent strain.

Application of alkaline protease as a dehairing agent

The enzymatic dehairing on industrial scale is generally accompanied by the use of small amount of lime to improve the dehairing efficacy and to reduce the cost of the dehairing process (Thanikaivelan et al., 2004). The utilization of lime has a lot of environmental hazards. Therefore, the dehairing employing solely protease is more environmental friendly and can be easily controlled due to single component treatment.

Complete removal of hairs has been achieved through an enzyme without chemical assistance (Thangam et al., 2001; Dayanandan et al., 2003; Macedo et al., 2005). The alkaline protease produced by UV-9 was used as a dehairing agent by applying it on the different pieces of goat skin to exploit its commercial significance. A complete dehairing of skin with clean hair pore and clean grain structure was observed after 12 h of treatment (Fig. 3).


The skin structure was found intact, indicating that the enzyme did not apparently destroy or modify the skin collagen structure. A further increase in treatment period up to 15 h created some small holes in the skin. These results suggested that identification of proper treatment or soaking period was very much essential to control the process of dehairing which alternatively affected the quality of leather and leather products. Similar findings about dehairing have also been reported with alkaline protease produced by a mutant strain of B. pumilus BA06 (Wang et al., 2007).

CONCLUSION

The cost of the enzyme in a bioprocess can be reduced by introducing hyper-productive strain after suitable mutagenic treatments. Different mutagenic treatments i.e., UV irradiation, MMS and NTG were employed on a parent strain to improve the yield of alkaline protease. All these treatments affected the morphological and physiological characteristics of mutants, for substrate consumption and product formation rates. However, the UV irradiated mutant UV-9 was selected as a hyper-proteolytic mutant after extensive screening study. The mutant UV-9 showed a significant i.e., 1.4 fold increase in productivity over the parent strain B. licheniformis N-2. Therefore, utilization of mutant UV-9 would be economically sensible for the large production of alkaline protease. The alkaline protease produced by Bacillus mutant UV-9 was also studied for its dehairing application against goat skin pieces for different soaking periods. The removal of hairs was found efficient and the quality of dehaired skin was found satisfactory after 12 h of treatment. These properties suggested that alkaline protease produced by mutant UV-9 had a promising potential for dehairing and could be used as an ideal dehairing agent in tanning industries.

ACKNOWLEDGEMENTS

The authors would like to thank to the Ministry of Science and Technology, Islamabad, Pakistan for providing financial assistance under the PSDP-project of allocation No. 31 to complete this research work.

Received: January 05, 2009; Revised: April 22, 2009; Accepted: January 25, 2010.

  • Eaten, A. D., Clesceri, L. S., Rice, E. W. and Greenberg, A. E. (2005), Microbiological examination. In: Standard methods for the examination of water and wastewater. 21st edition. Published by American Public Health Association. 1015 Fifteenth Street, NW Washington, DC 200013710. pp 9-34 to 9-71.
  • Balasubramanian, S. and Pugalenthi, V. (2000), A comparative study of the determination of sulphide in tannery waste water by ion selective electrode (ISE) and iodometry. Water Res., 34, 4201-4206.
  • Bierbaum, G., Karutz, M., Botz, D. W. and Wandey, C. (1994), Production of protease with Bacillus licheniformis mutants insensitive to repression of exoenzyme biosynthesis. Appl. Microbiol. Biotechnol., 40, 611-617.
  • Cheng-gang, C. A. I., Bing-gang, L. O. U. and Xiaodong, Z. (2008). Keratinase production and keratin degradation by a mutant train of Bacillus subtilis. J. Zhejiang Uni. Sci. B., 9, 60-67.
  • Dayanandan, A., Kanagaraj, J., Sounderraj, L., Govindaraju, R., Rajkumar G. S., 2003. Application of an alkaline protease in leather processing: an ecofriendly approach. J. Clean prod., 11:533-536.
  • Dubois, M., Gilles, K. A., Hamilton, J. K., Rebers, P. A. and Smith F. (1956), Colorimetric method for determination of sugars and related substances. Anal. Chem., 28, 350-356.
  • Dutta, J. R. and Banerjee, R. (2006), Isolation and characterization of a newly isolated Pseudomonas mutant for protease production. Braz. arch. biol. technol., 49, 37-47.
  • Dutta, J. R., Nanda, R. K. and Banerjee, R. (2006), Strain improvement for tannase production from coculture of Aspergillus foetidus and Rhizopus oryzae. Biores. Technol, 97, 795-801.
  • Gupta, R., Beg, Q. K. and Lorenz, P. (2002), Bacterial alkaline protease: molecular approaches and industrial applications. Appl. Microbiol. Biotechnol, 59, 15-32.
  • Huang, Q., Peng, Y., Li, X., Way, H. and Zhang, Y. (2003). Purification and characterization of an extracellular alkaline serine protease with dehairing function for Bacillus pumilus. Curr. Microbiol., 46, 169-173.
  • Lowry, O. H., Roserbrough, N. J., Farr, A. L. and Randall, R. (1951), Protein measurement with Folin Phenol Reagent, J. Biological Chem., 193, 265-275.
  • Macedo, A. J., Da-silva, W. O., Gava, R., Driemeier, D. D., Henriques, J. A. and Termignoni, C. (2005). Novel keratinase from Bacillus subtilis S14 exhibiting remarkable dehairing capabilities. Appl. Environ. Microbiol, 71, 594-596.
  • Meraz, I. M., Choudhury T. and Hoq, M. M. (2006), Optimization of mutation conditions of Bacillus sp. to increase the yield of alkaline protease. J. Human Life Sci., 4, 43-50.
  • Nadeem, M, Qazi, J. I., Baig, S. J. and Syed, Q. A. (2007), Studies on commercially important alkaline protease from Bacillus licheniformis N-2 isolated from decaying organic soil. Turk J. Biochem., 32, 171-177.
  • Nadeem, M., Baig, S. J., Syed, Q. A. and Qazi, J. I. (2006), Microbial production of alkaline proteases by locally isolated Bacillus subtilis PCSIR-5. Pak. J. Zool, 38, 109-114.
  • Nehete, P. N., Shah, V. D., and Kothari, R. M. (1985), Profile of alkaline protease production as a function of composition of the slant, age, transfer and isolate number and physiological state of cultures. Biotechnol. Lett., 7, 413-418.
  • Okpokwasili, G. C. and Nweke, C. O. (2005), Microbial growth substrate utilization kinetics. African J. Biotechnol., 5, 305-317.
  • Pirt, S. J. (1975), Principles of Microbes and cell cultivation. In: Parameters of growth and analysis of growth data. Blackwell Scientific Publications, 85 Marylebone High Street London, pp. 4-14.
  • Puri, S., Beg, Q. K. and Gupta R. (2002). Optimization of alkaline protease production from Bacillus species by response surface methodology. Curr. Microbiol, 44, 286-290.
  • Pvanakrishnan, R. and Dhar, S. C. (1986), Recent advances in the depletion of hides and skins. Leather Sci., 33, 177-191.
  • Rao, M. B., Tanksale, A. M., Ghatge, M. S. and Deshpande, V. V. (1998), Molecular and biotechnological aspects of microbial proteases. Microbiol. Molecul. Biology, 62, 597-634.
  • Shikha, S. A. and Darmwal, N. S. (2007), Improved production of alkaline protease from a mutant of alkalophilic Bacillus pantotheneticus using molasses as a substrate. Biores. Technol., 98, 881-885.
  • Sunitha, K., Park, Y. S., Oh, T. K. and Lee, J. K. (1999), Synthesis of alkaline protease by catabolite repression-resistant Thermoactinomyces sp. E79 mutant. Biotechnol. Lett., 21, 155-158.
  • Thangam, E. B., Nagarajan, T., Suseela, R. G. and Chandrababu, N. K. (2001), Application of alkaline protease isolated from Alcaligenes faecalis for enzymatic unhairing in tanneries. J. Ind. Leather., 37, 215-222.
  • Thanikaivelan, P., Rao J. R,, Nair, B. U. and Ramasami, T. (2004), Progress and recent trends in biotechnological methods for leather processing. Trends Biotechnol., 22, 181-188.
  • Wang, H. Y., Liu, D. M., Liu Y., Cheng, C. F., Ma, Q. Y., Huang, Q. and Zhang, Y. Z. (2007), Screening and mutagenesis of a novel Bacillus pumilus strain producing alkaline protease for dehairing. Letters Appl. Microbiol, 44, 1-6.
  • Yang, S. S. and Huang, C. I. (1994). Proteases production by Amylolytic fungi in solid state fermentation. J. Chinese Agri. Chem. Soc., 32, 589-601.
  • Zhang, X. B. and Yoshiyuki, O. (1993), Anticlastogenic and bio-antimutagenic activity of cultured broth of Saccharomyces cerevisiae 28 on mutagens. Mutation Res., 300, 201-206.
  • *
    Author for correspondence:
  • Publication Dates

    • Publication in this collection
      03 Nov 2010
    • Date of issue
      Oct 2010

    History

    • Received
      05 Jan 2009
    • Reviewed
      22 Apr 2009
    • Accepted
      25 Jan 2010
    Instituto de Tecnologia do Paraná - Tecpar Rua Prof. Algacyr Munhoz Mader, 3775 - CIC, 81350-010 Curitiba PR Brazil, Tel.: +55 41 3316-3052/3054, Fax: +55 41 3346-2872 - Curitiba - PR - Brazil
    E-mail: babt@tecpar.br