Júlia Baruque, Adriano Carniel, J. C. S. Sales, B. Ribeiro, Rodrigo P. do Nascimento, Ivaldo Itabaiana
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Among the variables studied were temperature at 40 °C, ionic strength of 50 mM, and 72 h of immobilization, with 15 m·L −1 of proteins generated biocatalysts with high immobilization efficiencies (87% for ACC-Celluclast biocatalyst and 95% for ACC-ThI1412 biocatalyst), high retention of activity, and specific activities in the support for CMCase (DNS method), FPase (filter paper method) and β-glucosidase (p-nitrophenyl-β-D-glucopyranoside method). Presenting a lower protein concentration (0.32 m·L−1) than the commercial Celluclast® 1.5 L preparation (45 m·L−1), the ACC-ThI1412-derived immobilized biocatalyst showed thermal stability at temperatures higher than 60 °C, maintaining more than 90% of the residual activities of FPase, CMCase, and β-glucosidase. In contrast, the commercial-free enzyme presented a maximum catalytic activity at only 40 °C. 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引用次数: 0
摘要
纤维素酶是一类具有重要工业意义的酶,具有多种战略用途。然而,酶生产的高成本,加上水解过程所需蛋白质的不稳定性和复杂性,仍然限制了它们在几种方案中的使用。因此,酶固定化可能是克服这些问题的重要工具。本研究旨在评价商业混酵素Celluclast®1.5 L与野生菌株哈兹木霉I14-12混酵素在Accurel®MP1000中的固定化效果。研究的变量包括温度为40℃,离子强度为50 mM,固定72 h,产生15 m·L−1的生物催化剂,其固定化效率高(ACC-Celluclast生物催化剂为87%,ACC-ThI1412生物催化剂为95%),保留活性高,支持CMCase (DNS法),FPase(滤纸法)和β-葡萄糖苷酶(对硝基苯-β- d -葡萄糖苷法)的比活性高。accc - thi1412衍生的固定化生物催化剂的蛋白浓度(0.32 m·L−1)低于商业化的1.5 L Celluclast®制剂(45 m·L−1),在高于60°C的温度下表现出热稳定性,保持了90%以上的FPase、CMCase和β-葡萄糖苷酶的残留活性。相比之下,商业化酶仅在40°C时表现出最大的催化活性。此外,提取物中不同组分酶的分子量差异导致了蛋白质在载体上不同的疏水和倒伏相互作用,从而产生了一种强大的、有竞争力的生物催化剂。
Immobilization of Cellulolytic Enzymes in Accurel® MP1000
Cellulases are a class of enzymes of great industrial interest that present several strategic applications. However, the high cost of enzyme production, coupled with the instabilities and complexities of proteins required for hydrolytic processes, still limits their use in several protocols. Therefore, enzyme immobilization may be an essential tool to overcome these issues. The present work aimed to evaluate the immobilization of cellulolytic enzymes of the commercial enzyme cocktail Celluclast® 1.5 L in comparison to the cellulolytic enzyme cocktail produced from the wild strain Trichoderma harzianum I14-12 in Accurel® MP1000. Among the variables studied were temperature at 40 °C, ionic strength of 50 mM, and 72 h of immobilization, with 15 m·L −1 of proteins generated biocatalysts with high immobilization efficiencies (87% for ACC-Celluclast biocatalyst and 95% for ACC-ThI1412 biocatalyst), high retention of activity, and specific activities in the support for CMCase (DNS method), FPase (filter paper method) and β-glucosidase (p-nitrophenyl-β-D-glucopyranoside method). Presenting a lower protein concentration (0.32 m·L−1) than the commercial Celluclast® 1.5 L preparation (45 m·L−1), the ACC-ThI1412-derived immobilized biocatalyst showed thermal stability at temperatures higher than 60 °C, maintaining more than 90% of the residual activities of FPase, CMCase, and β-glucosidase. In contrast, the commercial-free enzyme presented a maximum catalytic activity at only 40 °C. Moreover, the difference in molecular weight between the component enzymes of the extract was responsible for different hydrophobic and lodging interactions of proteins on the support, generating a robust and competitive biocatalyst.