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( Dissanayaka M. S. Dissanayaka ),( Sembukuttige N. T. De Silva ),( D. P. S. T. G. Attanayaka ),( Mihidukulasuriya J. M. S. Kurera ),( Charakrawarthige A. N. Fernando ) 한국미생물생명공학회(구 한국산업미생물학회) 2019 한국미생물·생명공학회지 Vol.47 No.3
The present study reports the morphological and molecular characterization of the fungal strain, CMSS06 and evaluates its raw starch hydrolyzing ability in four different agricultural substrates (rice bran, banana peel, cassava tubers, and coconut water). The potential use of each agricultural substrate to replace the expensive fermentation media was evaluated with six different fermentation media: rice bran (RB), banana peel (BP), cassava starch (CS), cassava in coconut water (CSCW), cassava in modified coconut water (CMCW), and pure Coconut water (CW). The fungal strain CMSS06 was identified as Thielaviopsis ethacetica by the analysis of the ITS sequences. The T. ethacetica alpha amylase enzyme exhibited maximum alpha amylase activity at 72 h, pH 7.0, and 40℃ on soluble starch. This species resulted in the highest enzyme activity (mU/ml) of 26.06, 10.89, 58.82, 14.2, and 54.67 with the RB, BP, CS, CSCW, and CMCW fermentation media, respectively. The results indicate that CS can be used as a carbon substrate and CMCW can be used to accelerate the fermentation by T. ethacetica. The enzyme was partially purified by 40-60% ammonium sulphate fraction, and it showed total enzyme activity, total protein content, specific activity, purification fold, and a recovery of 2400 mU, 30 mg, 80 mU/mg, 2.7, and 71.1%, respectively. The molecular mass of the T. ethacetica alpha amylase was estimated on SDS-PAGE, and two bands around 50 kDa and 70 kDa were identified. The present study implies that T. ethacetica can produce alpha amylase, and it can be used to hydrolyze raw starch during the fermentation processes.
Dissanayaka, Dissanayaka M.S.,De Silva, Sembukuttige N.T.,Attanayaka, D.P.S.T.G.,Kurera, Mihidukulasuriya J.M.S.,Fernando, Charakrawarthige A.N. The Korean Society for Microbiology and Biotechnol 2019 한국미생물·생명공학회지 Vol.47 No.3
The present study reports the morphological and molecular characterization of the fungal strain, CMSS06 and evaluates its raw starch hydrolyzing ability in four different agricultural substrates (rice bran, banana peel, cassava tubers, and coconut water). The potential use of each agricultural substrate to replace the expensive fermentation media was evaluated with six different fermentation media: rice bran (RB), banana peel (BP), cassava starch (CS), cassava in coconut water (CSCW), cassava in modified coconut water (CMCW), and pure Coconut water (CW). The fungal strain CMSS06 was identified as Thielaviopsis ethacetica by the analysis of the ITS sequences. The T. ethacetica alpha amylase enzyme exhibited maximum alpha amylase activity at 72 h, pH 7.0, and $40^{\circ}C$ on soluble starch. This species resulted in the highest enzyme activity (mU/ml) of 26.06, 10.89, 58.82, 14.2, and 54.67 with the RB, BP, CS, CSCW, and CMCW fermentation media, respectively. The results indicate that CS can be used as a carbon substrate and CMCW can be used to accelerate the fermentation by T. ethacetica. The enzyme was partially purified by 40-60% ammonium sulphate fraction, and it showed total enzyme activity, total protein content, specific activity, purification fold, and a recovery of 2400 mU, 30 mg, 80 mU/mg, 2.7, and 71.1%, respectively. The molecular mass of the T. ethacetica alpha amylase was estimated on SDS-PAGE, and two bands around 50 kDa and 70 kDa were identified. The present study implies that T. ethacetica can produce alpha amylase, and it can be used to hydrolyze raw starch during the fermentation processes.
Functions and values of sulfated polysaccharides from seaweed
D. P. Nagahawatta,N. M. Liyanage,Thilina U. Jayawardena,Fengqi Yang,H. H. A. C. K. Jayawardena,M. J. M. S. Kurera,Fahe Wang,Xiaoting Fu,전유진 한국조류학회I 2023 ALGAE Vol.38 No.4
Sulfated polysaccharides (SPs) isolated from seaweed have emerged as remarkable bioactive compounds with a wide spectrum of biological activities and have substantial value in the scientific and industrial domains. The current study explores the diverse biological activities of SPs and their relationship with their structures. This aids in an in-depth examination of the multifaceted biological activities of SPs, including anticoagulant, anti-inflammatory, antiviral, antioxidant, and immunomodulatory properties, which underpin their potential health benefits. Furthermore, the current study explores the complicated properties of SPs, with their extraction methodologies and techniques for precise characterization. Elucidation of the commercial significance of SPs derived from brown, red, and green seaweed by highlighting their potential applications has emphasized their importance in human well-being. Further, this review emphasizes the challenges needed to overcome research and industrial innovations for SPs. Collaboration among researchers, industry stakeholders, and regulatory authorities can overcome these challenges and elevate the potential of SPs to revolutionize industries such as pharmaceuticals, cosmeceuticals, food, and biotechnology.