Comparison of function of immobilized and free Bacillus licheniformis cells in production of alkaline protease
Subject Areas : Applied MicrobiologyMohammad Mashhadi-Karim 1 , Mehrdad Azin 2 , Seyyed Latif Mousavi Gargari 3 , Meysam Sarshar 4
1 - Department of Biotechnology, Iranian Research Organization for Science & Technology, Tehran, Iran
2 - Department of Biotechnology, Iranian Research Organization for Science & Technology, Tehran, Iran
3 - Department of Biotechnology, Faculty of Science, Shahed University, Tehran, Iran
4 - Molecular Biology Research Center, Baqiatallah University of Medical Sciences, Tehran, Iran
Keywords: Calcium alginate, Bacillus licheniformis, Alkaline protease, Cell immobilization,
Abstract :
Abstract Background and Objective: Proteases are an important group of industrial enzymes, which are widely used in different industries such as detergent, leather tanning, pharmaceutical, and food industries. The aim of this study was to immobilize Bacillus licheniformis cells in calcium alginate beads and study of its effects on the amount of alkaline protease production. Effects of several different conditions on stability of the beads were also examined. Material and Methods: Bacillus licheniformis cells were immobilized in calcium alginate beads and were used for production of alkaline protease. The amount of enzyme production was compared in immobilized and free-cell fermentation. Effect of stuffing rate (%) on the enzyme production was studied. Optimum pH and temperature of enzyme activity were also determined. Furthermore, effects of pH, curing time and treating the beads by glutaraldehyde on stability of the beads were examined. Results: In this study the amount of production and productivity of protease in immobilized cells state showed an increase of 74% and 54% in comparison to free cells state, respectively. The highest amount of the production of the enzyme was obtained in stuffing rate of 5% (v/v). Optimum pH and temperature of the enzyme activity were determined 8 and 65oC, respectively. The highest stability of the beads was observed at curing time of 1 hour at pH of 7.4. Treating the beads by glutaraldehyde was detrimental to their stability. Conclusion: Use of immobilized cells of Bacillus licheniformis in calcium alginate beads on the one hand, can increase productivity of the alkaline protease in comparison to free cells method, and on the other hand, reduces the cost of the enzyme production because of eliminating the need of preparation of inoculum for the new batches.
1. Deepti A, Pankaj P, Tushar B, Shridhar P. Production of alkaline protease by Penicillum sp. under SSF conditions and its application to soy protein hydrolysis. Process Biochem, 2004; 39(8): 977-981.
2. Wu TY, Mohammad AW, Jahim JMd, Anuar N. Investigations on protease production by a wild-type Aspergillus terreus strain using diluted retentate of pre-filtered palm oil mill effluent (POME) as substrate. Enzyme Microb Tech, 2006; 39(6): 1223–1229.
3. Gupta R, Beg QK, Khan S, Chauhan B. An overview on fermentation, downstream processing and properties of microbial alkaline proteases. Appl Microbiol Biotechnol, 2002; 60(4): 381-395.
4. Jellouli K, Bougatef A, Manni L, Agrebi R, Siala R,Younes I, Nasri M. Molecular and biochemical characterization of an extracellular serine-protease from Vibrio metschnikovii J1. J Ind Microbiol Biotechnol, 2009; 36(7): 939–948.
5. Bhaskar N, Sudeepa ES, Rashmi HN, Selvi AT. Partial purification and characterization of protease of Bacillus proteolyticus-CFR3001 isolated from fish processing waste and its antibacterial activities. Bioresour Technol, 2007; 98(14): 2758–2764.
6. Sareen R, Mishra P. Purification and characterization of organic solvent stable protease from Bacillus licheniformis RSP-09–37. Appl Microbiol Biotechnol, 2008; 79(3):399–405.
7. Singh J, Batra N, Sobti RC. Serine alkaline protease from a newly isolated Bacillus sp. SSR1. Process Biochem, 2001; 36(8-9): 781-785.
8. Genckal H. Studies on Alkaline Protease Production from Bacillus sp. A Dissertation Submitted to the Graduate School in Partial Fulfillment of the Requirements for the Degree of MASTER OF SCIENCE, İzmir Institute of Technology, 2004.
9. Beshay U. Production of alkaline protease by Teredinobacter turnirae cells immobilized in calcium alginate beads. Afr J Biotechnol, 2003; 2(3):60-65.
10. Adinarayana K, Jyothi B, Ellaiah P. Production of alkaline protease with immobilized cells of Bacillus subtilis PE-11 in various matrices by entrapment technique. AAPS PharmSci Tech, 2005; 6(3): 391–397.
11. Potumarthi R, Subhakar Ch, Pavani A, Jetty A. Evaluation of various parameters of calcium-alginate immobilization method for enhanced alkaline protease production by Bacillus licheniformis NCIM-2042 using statistical methods. Bioresour Technol, 2007; 99(6): 1776–1786.
12. Jetty A, Gangagni rao A, Sarva rao B, Madhavi G, Ramakrishna SV. Comparative studies of air lift and fluidized bed reactors for streptomycin production by immobilized cells of Streptomyces bikiniensis ATCC 11062. Chem Biochem Eng, 2005; 19: 179–184.
13. Yukio Kawaguti H, Ferrari Buzzato M, Castilho Orsi D, Tiemi Suzuki G, Harumi Sato H. Effect of the additives polyethylenimine and glutaraldehyde on the immobilization of Erwinia sp. D12 cells in calcium alginate for isomaltulose production. Process Biochem, 2006; 41(9): 2035–2040.
14. Shrinvas D, Naik GR. Characterization of alkaline thermostable keratinolytic protease from thermoalkalophilic Bacillus halodurans JB 99 exhibiting dehairing activity. Inter Biodeterior Biodegrad, 2011; 65(1):29-35.
15. Kunitz M. Crystalline soybean Trypsin Inhibitor, II. General properties. J Gen Physiol, 1947; 30(4): 291-310.
