利用响应面法在固态发酵中对IND12菌株进行新型纤维蛋白溶解酶的顺序筛选及产量提高

Novel Sequential Screening and Enhanced Production of Fibrinolytic Enzyme by sp. IND12 Using Response Surface Methodology in Solid-State Fermentation.

作者信息

Vijayaraghavan Ponnuswamy, Rajendran P, Prakash Vincent Samuel Gnana, Arun Arumugaperumal, Abdullah Al-Dhabi Naif, Valan Arasu Mariadhas, Young Kwon Oh, Kim Young Ock

机构信息

Centre for Marine Science and Technology, Manonmaniam Sundaranar University, Rajakkamangalam, Kanyakumari District, Tamil Nadu 629 502, India.

Kanyakumari Field Centre, Central Marine Fisheries Research Institute, Kanyakumari, Tamil Nadu 629702, India.

出版信息

Biomed Res Int. 2017;2017:3909657. doi: 10.1155/2017/3909657. Epub 2017 Jan 17.

DOI:10.1155/2017/3909657

PMID:28321408

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC5340989/

Abstract

Fibrinolytic enzymes have wide applications in clinical and waste treatment. Bacterial isolates were screened for fibrinolytic enzyme producing ability by skimmed milk agar plate using bromocresol green dye, fibrin plate method, zymography analysis, and goat blood clot lysis. After these sequential screenings, sp. IND12 was selected for fibrinolytic enzyme production. sp. IND12 effectively used cow dung for its growth and enzyme production (687 ± 6.5 U/g substrate). Further, the optimum bioprocess parameters were found out for maximum fibrinolytic enzyme production using cow dung as a low cost substrate under solid-state fermentation. Two-level full-factorial experiments revealed that moisture, pH, sucrose, peptone, and MgSO were the vital parameters with statistical significance ( < 0.001). Three factors (moisture, sucrose, and MgSO) were further studied through experiments of central composite rotational design and response surface methodology. Enzyme production of optimized medium showed 4143 ± 12.31 U/g material, which was more than fourfold the initial enzyme production (978 ± 36.4 U/g). The analysis of variance showed that the developed response surface model was highly significant ( < 0.001). The fibrinolytic enzyme digested goat blood clot (100%), chicken skin (83 ± 3.6%), egg white (100%), and bovine serum albumin (29 ± 4.9%).

摘要

纤溶酶在临床和废物处理中有着广泛的应用。通过使用溴甲酚绿染料的脱脂牛奶琼脂平板、纤维蛋白平板法、酶谱分析和山羊血凝块溶解试验，对细菌分离株进行纤溶酶产生能力的筛选。经过这些连续筛选后，选择了sp. IND12用于纤溶酶的生产。sp. IND12有效地利用牛粪进行生长和酶的生产（687±6.5 U/g底物）。此外，还确定了以牛粪为低成本底物在固态发酵条件下实现最大纤溶酶产量的最佳生物工艺参数。二级全因子实验表明，水分、pH值、蔗糖、蛋白胨和硫酸镁是具有统计学意义的关键参数（P<0.001）。通过中心复合旋转设计实验和响应面法进一步研究了三个因素（水分、蔗糖和硫酸镁）。优化培养基的酶产量为4143±12.31 U/g原料，比初始酶产量（978±36.4 U/g）高出四倍多。方差分析表明，所建立的响应面模型具有高度显著性（P<0.001）。该纤溶酶能消化山羊血凝块（100%）、鸡皮（83±3.6%）、蛋清（100%）和牛血清白蛋白（29±4.9%）。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/5443/5340989/bf43b3ae3ed0/BMRI2017-3909657.001.jpg

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利用响应面法在固态发酵中对IND12菌株进行新型纤维蛋白溶解酶的顺序筛选及产量提高

Novel Sequential Screening and Enhanced Production of Fibrinolytic Enzyme by sp. IND12 Using Response Surface Methodology in Solid-State Fermentation.

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