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- Title
Purification and Characterization of Strong Simultaneous Enzyme Production of Protease and α-Amylase from an Extremophile- Bacillus sp. FW2 and Its Possibility in Food Waste Degradation.
- Authors
Pham, Van Hong Thi; Kim, Jaisoo; Shim, Jeahong; Chang, Soonwoong; Chung, Woojin
- Abstract
Microbial enzymes such as protease and amylase are valuable enzymes with various applications, widely investigated for their applications in degradation of organic waste, biofuel industries, agricultural, pharmaceuticals, chemistry, and biotechnology. In particular, extremophiles play an important role in biorefinery due to their novel metabolic products such as high value catalytic enzymes that are active even under harsh environmental conditions. Due to their potentials and very broad activities, this study isolated, investigated, and characterized the protease- and amylase-producing bacterial strain FW2 that was isolated from food waste. Strain FW2 belongs to the genus Bacillus and was found to be closest to Bacillus amyloliquefaciens DSM 7T with a similarity of 99.86%. This strain was able to degrade organic compounds at temperatures from −6 °C to 75 °C (but weak at 80 °C) under a wide pH range (4.5–12) and high-salinity conditions up to 35% NaCl. Maximum enzyme production was obtained at 1200 ± 23.4 U/mL for protease and 2400 ± 45.8 U/mL for amylase for 4 days at pH 7–7.5, 40–45 °C, and 0–10% NaCl. SDS-PAGE analysis showed that the molecular weights of purified protease were 28 kDa and 44 kDa, corresponding to alkaline protease (AprM) and neutral protease (NprM), respectively, and molecular weight of α-amylase was 55 kDa. Degradation food waste was determined after 15 days, observing a 69% of volume decrease. A potential commercial extremozyme-producing bacteria such as strain FW2 may be a promising contributor to waste degradation under extreme environmental conditions.
- Subjects
FOOD waste; AMYLASES; MICROBIAL enzymes; ORGANIC wastes; ALKALINE protease; ENZYMES; AMYLOLYSIS
- Publication
Fermentation (Basel), 2022, Vol 8, Issue 3, p12
- ISSN
2311-5637
- Publication type
Article
- DOI
10.3390/fermentation8010012