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Full Screen- TITLE
- DEDICATION
- CERTIFICATE 1
- CERTIFICATE-2
- DECLARATION
- ACKNOWLEDGEMENT
- CONTENTS
- ABBREVIATIONS
- 1. INTRODUCTION
- 2. REVIEW OF LITERATURE
- Classification of Microbial Proteases
- Serine Proteases
- Thiol Proteases
- Acid (Carboxyl) Proteases
- Metallo Proteases
- Commercial Applications
- Extracellular Alkaline Protease Production by Bacteria
- Screening and Selection of Strains
- Methods of Production
- Bacterial Alkaline Protease Production by Submerged Fermentation
- Table 1.Bacteria in which the extracellular alkaline protease production by SmF has been studied
- Factors influencing alkaline proterase production by bacteria by submerged fermentation
- Growth phase
- Carbon source
- Nitrogen source
- Temperature
- pH
- Mineral salts
- Age of inoculum
- Size of inoculum
- Agitation
- Aeration
- Incubation period
- Two phase fermentation systems
- Fed batch fermentation
- Bacterial Alkaline Protease Production by Solid State Fermentation
- Bacillus amyloliquefaciens
- Bacillus licheniformis
- Pseudomonas sp.
- Purification and Characterization of Bacterial Alkaline Proteases
- Table 2. Bacterial sources from which the extracellular alkaline serine proteases have been isolated, purified and studied
- Molecular mass
- Isoelectric point
- Optimum pH and temperature for activity
- Effect of metal ions on activity
- pH and themostability
- Stability towards detergents
- Km value
- 3. SCREENING AND SELECTION OF STRAINS FOR ALKALINE PROTEASE PRODUCTION
- Section A - Screening and Selection of Strain for Alkaline Protease Production by Submerged Fermentation
- MATERIALS AND METHODS
- Bacterial strains
- Enzyme assay
- Selection of high yielding strains
- Identification of the highest yielding strains
- Monitoring the stability of the highest yielding strains
- RESULTS
- Selection of high yielding strains
- Table 3. Extracellular alkaline protease production by the top five high yielding strains and NCIM strains
- Identification of the highest yielding strains
- Table 4. Characters shown by Bacillus sp. K 25
- Stability of the highest yielding strains
- DISCUSSION
- Section B - Screening and Selection of Strain for Alkaline Protease Production by Solid State Fermentation
- MATERIALS AND METHODS
- Bacterial strains
- Selection of high yielding strains
- Step 1 -Preliminary SSF studies
- Step 2 -Detailed SSF studies
- identification of the highest yielding strain
- Monitoring the stability of the highest yielding strain
- RESULTS
- Selection of high yielding strains
- Preliminary SSF studies
- Table 5. Alkaline protease production by top five high yielding strains and NCIM strains in preliminary SSF studies
- Detailed SSF studies
- Table 6. Alkaline protease production by the high yielding strains in solid state fermentation systems with different moisture levels, incubated for different periods
- Identification of the highed yielding strain
- Stability of the highest yielding strain
- DISCUSSION
- 4. OPTIMIZATION OF CONDITIONS FOR THE PRODUCTION OF ALKALINE PROTEASES
- Section A - Optimization of Conditions for the Production of Alkaline Protease by Bacillus sp. K 25 by the Submerged Fermentation Method
- MATERIALS AND METHODS
- Growth phase
- Temperature of Incubation
- Carbon and nitrogen sources
- Salts
- Age of lnoculum
- Size of inoculum
- Agitation
- Incubation period
- RESULTS
- Effect of growth phase
- Fig. 1. Time course of growth and alkaline protease production by Bacillus sp. K 25
- Effect of temperature of incubation
- Fig. 2. Effect of temperature of incubation on alkaline protease production by Bacillus sp. K 25
- Effect of pH
- Fig. 3. Effect of initial pH of medium on alkaline protease production by Bacillus sp. K 25
- Effect of carbon and nitrogen sources
- Table 7. Effect of different carbon sources on alkaline protease production by Bacillus sp. K 25
- Table 8. Effect of various nitrogen sources on alkaline protease production by Bacillus sp. K 25
- Table 9. Effect of using starch and soyabean meal at different concentrations on alkaline protease production by Bacillus sp. K 25
- Effect of salts
- Table 10. Effect of using different concentrations of sodium chloride on alkaline protease production by Bacillus sp. K 25
- Table 11. Effect of different salts on alkaline protease production by Bacillus sp. K 25
- Table 12. Effect of different concentrations of calcium chloride on alkaline protease production by Bacillus sp. K 25
- Table 13. Effect of age of inoculum on alkaline protease production by Bacillus sp. K 25
- Effect of size of inoculum
- Table 14. Effect of inoculum size on alkaline protease production by Bacillus sp. K 25
- Effect of agitation
- Table 15. Effect of agitating the culture on alkaline protease production
- Effect of period of incubation
- Table 16. Effect of incubation period on alkaline protease accumulation in the culture of Bacillus sp. K 25
- DISCUSSION
- Section B - Optimization of Conditions for the Production of Alkaline Protease by Bacillus pumilus K 242 by the Solid State Fermentation Method
- MATERIALS AND METHODS
- Solid substrate
- Particle size
- Moisture level, Temperature of incubation and Incubation period
- pH moistening solution
- Supplementation with carbon sources
- Supplementation with nitrogen sources
- Supplementation with sodium chloride
- Age of inoculum
- Size of inoculum
- Medium volume: Flask volume
- RESULTS
- Effect of different solid substrates
- Table 17. Alkaline protease production by Bacillus pumilus K 242 by SSF, using different commercially available substrates
- Effect of size of particles of wheat bran
- Table 18. Effect of using wheat bran of different particle size on alkaline protease production by Bacillus pumilus K 242
- Effect of moisture level, temperature of incubation and incubation period
- Table 19. Effect of moisture level, temperature of incubation and incubation period on alkaline protease production by Bacillus pumilus K 242
- Effect of pH of moistening solution
- Fig. 4. Effect of pH of moistening solution on alkaline protease production by Bacillus pumilus K 242
- Effect of extra carbon sources
- Table 20. Effect of supplementation of wheat bran medium with different carbon sources on alkaline protease production by Bacillus pumilus K 242
- Effect of extra nitrogen sources
- Table 21. Effect of supplementation of solid substrate medium with different nitrogen sources on alkaline protease production by Bacillus pumilus K 242
- Effect of sodium chloride
- Table 22. Effect of incorporating sodium chloride at different concentrations into the moistening solution, on alkaline protease production by BaciIIus pumilus K 242
- Effect of age of lnoculurn
- Table 23. Effect of age of inoculum on alkaline protease production by Bacilus pumilus K 242
- Effect of size of inoculurn
- Table 24. Effect of inoculum size on alkaline protease production by Bacillus pumilus K 242
- Effect of the ratio, medium volume: flask volume
- Table 25. Effect of varying the ratio medium volume: flask volume on alkaline protease production by Bacillus pumilus K 242
- DISCUSSION
- 5. PURIFICATION OF ALKALINE PROTEASES
- Section A - Purification of Alkaline Protease from the Culture Supernatant of Bacillus sp. K 25
- MATERIALS AND METHODS
- RESULTS
- Fig. 5. Elution profile of alkaline protease of Basillus sp. K 25 from CM cellulose column
- Table 26. Purification of extracellular alkaline protease of Bacillus sp. K 25
- Fig. 6. Elution profile of alkaline protease of Bacillus sp. K 25 from Sephadex G- 100 column
- Plate 1. Native polyacrylamide gel electrophoresis of purified alkaline protease of Bacillus sp. K25
- DISCUSSION
- Section B - Purification of Alkaline Protease from the Bacterial Bran Extract of Bacillus pumilus K 242
- MATERIALS AND METHODS
- RESULTS
- Fig. 7. Elution profile of proteases of Bacillus pumilus K 242 from DEAE Sephadex A-50 column
- Fig. 8. Elution profile of alkaline protease of Bacillus pumilus K 242 from Sephadex G- 100 column
- Plate 2. Native polyacrylamide gel electrophoresis of purified alkaline protease of Bacillus pumilus K 242
- Table 27. Purification of extracellular alkaline protease from the bacterial bran extract of Bacillus pumilus K 242
- DISCUSSION
- 6. CHARACTERIZATION OF ALKALINE PROTEASES
- MATERIALS AND METHODS
- Effect of pH on activity
- Effect of temperature on activity
- Effect of inhibitors on activity
- Effect of metal ions on activity
- Effect of pH on stability
- Effect of temperature on stability
- RESULTS
- Effect of pH on activity
- Fig. 9a. Effect of pH on caseinolysis by protease K 25
- Fig. 9b. Effect of pH on caseinolysis by protease K 242
- Effect of temperature on activity
- Fig. 10. Effect of temperature on caseinolysis by protease K 25 andprotease K 242
- Effect of inhibitors
- Table 28. Effects of inhibitors on the activity of proteases K 25and protease K 242
- Effect of metal ions on activity
- Table 29. Effect of metal ions on the activity of proteases K 25 and K 242
- pH stability
- Fig. 11. Effect of pH on the stability of protease K 25 and protease K 242
- Thermostability
- Fig. 12. Effect of temperature on the stability of protease K 25 andprotease K 242
- DISCUSSION
- 7. STUDIES ON SUITABILITY OF PROTEASES OF BACILLUS SP. K 25 AND BACILLUS PUMILUS K 242 AS DETERGENT ENZYMES
- MATERIALS AND METHODS
- Stability in presence of commercial detergents
- Ability of proteases to act on insoluble substrate in presence of commercial detergents
- RESULTS
- Table 30. Stability of proteases of BaciIIus sp. K 25, Bacillus pumiIus K 242 andBadus licheniformis NCIM 2042 in commercial detergents
- Table 31. Activity of proteases of Bacillus sp. K 25, Bacilus pumilus K 242and Bacillus licheniformis NCIM 2042 on blue case in-PAG in presence of different commercial detergents
- DISCUSSION
- 8. SUMMARY AND CONCLUSION
- BIBLIOGRAPHY