Statistically designed bioprocess for enhanced production of alkaline protease in bacillus cereus HP_RZ17

Alkaline protease is one of the bulk enzymes having wide commercial demand for various applications. It is commercially produced by a submerged fermentation process employing various bacteria, Bacillus sp. being the most widely used species. Statistical optimization of the process for the production...

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Main Authors: Jadhav, H. P., Sayyed, R. Z., Shaikh, S. S., Bhamre, H. M., Sunita, Kumari, El Enshasy, H. A.
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Published: National Institute of Science Communication and Information Resources 2020
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Online Access:http://eprints.utm.my/id/eprint/93176/
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spelling my.utm.931762021-11-19T03:24:04Z http://eprints.utm.my/id/eprint/93176/ Statistically designed bioprocess for enhanced production of alkaline protease in bacillus cereus HP_RZ17 Jadhav, H. P. Sayyed, R. Z. Shaikh, S. S. Bhamre, H. M. Sunita, Kumari El Enshasy, H. A. Q Science (General) TP Chemical technology Alkaline protease is one of the bulk enzymes having wide commercial demand for various applications. It is commercially produced by a submerged fermentation process employing various bacteria, Bacillus sp. being the most widely used species. Statistical optimization of the process for the production of alkaline proteases from rhizospheric bacteria and its application in the biocontrol of plant pathogens has not been explored fully and needs to be studied for the development of efficient bioprocess. We report the enhanced production of alkaline protease in the minimal salt medium (MSM) optimized using statistical approaches such as Plackett Burman Design (PBD) and Response Surface Methodology (RSM). In the first step; PBD, among the total eight variables, three variables namely, yeast extract (p<0.05), fructose (p<0.05) and pH (p<0.05) influenced the production of alkaline protease by Bacillus cereus HP_RZ17. These three variables were further analyzed in the second step i.e. Central Composite Design (CCD) of RSM. The optimum yield of alkaline protease by B. cereus HP_RZ17 (130.72 UmL-1) was obtained under the optimal conditions such as yeast extract (0.899% w/v), fructose (0.873% w/v), and pH (11.25) of production media. The statistically optimized values of variables used for the scale-up of the process at 5 L capacity bioreactor enhanced the alkaline protease yield (132.48 UmL-1) by 1.09 fold visà-vis un-optimized protocol (121.96 UmL-1) in B. cereus HP_RZ17. National Institute of Science Communication and Information Resources 2020-06 Article PeerReviewed Jadhav, H. P. and Sayyed, R. Z. and Shaikh, S. S. and Bhamre, H. M. and Sunita, Kumari and El Enshasy, H. A. (2020) Statistically designed bioprocess for enhanced production of alkaline protease in bacillus cereus HP_RZ17. Journal of Scientific and Industrial Research, 79 (6). pp. 491-498. ISSN 0022-4456
institution Universiti Teknologi Malaysia
building UTM Library
collection Institutional Repository
continent Asia
country Malaysia
content_provider Universiti Teknologi Malaysia
content_source UTM Institutional Repository
url_provider http://eprints.utm.my/
topic Q Science (General)
TP Chemical technology
spellingShingle Q Science (General)
TP Chemical technology
Jadhav, H. P.
Sayyed, R. Z.
Shaikh, S. S.
Bhamre, H. M.
Sunita, Kumari
El Enshasy, H. A.
Statistically designed bioprocess for enhanced production of alkaline protease in bacillus cereus HP_RZ17
description Alkaline protease is one of the bulk enzymes having wide commercial demand for various applications. It is commercially produced by a submerged fermentation process employing various bacteria, Bacillus sp. being the most widely used species. Statistical optimization of the process for the production of alkaline proteases from rhizospheric bacteria and its application in the biocontrol of plant pathogens has not been explored fully and needs to be studied for the development of efficient bioprocess. We report the enhanced production of alkaline protease in the minimal salt medium (MSM) optimized using statistical approaches such as Plackett Burman Design (PBD) and Response Surface Methodology (RSM). In the first step; PBD, among the total eight variables, three variables namely, yeast extract (p<0.05), fructose (p<0.05) and pH (p<0.05) influenced the production of alkaline protease by Bacillus cereus HP_RZ17. These three variables were further analyzed in the second step i.e. Central Composite Design (CCD) of RSM. The optimum yield of alkaline protease by B. cereus HP_RZ17 (130.72 UmL-1) was obtained under the optimal conditions such as yeast extract (0.899% w/v), fructose (0.873% w/v), and pH (11.25) of production media. The statistically optimized values of variables used for the scale-up of the process at 5 L capacity bioreactor enhanced the alkaline protease yield (132.48 UmL-1) by 1.09 fold visà-vis un-optimized protocol (121.96 UmL-1) in B. cereus HP_RZ17.
format Article
author Jadhav, H. P.
Sayyed, R. Z.
Shaikh, S. S.
Bhamre, H. M.
Sunita, Kumari
El Enshasy, H. A.
author_facet Jadhav, H. P.
Sayyed, R. Z.
Shaikh, S. S.
Bhamre, H. M.
Sunita, Kumari
El Enshasy, H. A.
author_sort Jadhav, H. P.
title Statistically designed bioprocess for enhanced production of alkaline protease in bacillus cereus HP_RZ17
title_short Statistically designed bioprocess for enhanced production of alkaline protease in bacillus cereus HP_RZ17
title_full Statistically designed bioprocess for enhanced production of alkaline protease in bacillus cereus HP_RZ17
title_fullStr Statistically designed bioprocess for enhanced production of alkaline protease in bacillus cereus HP_RZ17
title_full_unstemmed Statistically designed bioprocess for enhanced production of alkaline protease in bacillus cereus HP_RZ17
title_sort statistically designed bioprocess for enhanced production of alkaline protease in bacillus cereus hp_rz17
publisher National Institute of Science Communication and Information Resources
publishDate 2020
url http://eprints.utm.my/id/eprint/93176/
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