Maria Augusta de Carvalho Silvello, Giovana Alves Gasparotto, Rosana Goldbeck
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引用次数: 0
摘要
本研究开发了一种用于微藻生物量水解的多酶制剂。利用富含碳水化合物的小球藻生物量研究了酶之间可能的协同作用。在最佳实验条件下,在10 g L−1的生物量负载下,0.05 g−1底物的α-淀粉酶(Term戊酯®)和0.2 g−1基质的淀粉葡萄糖苷酶获得了5.639±0.32 g L−2的最大还原糖产量。用纤维素酶基因修饰的酿酒酵母JAYET细胞从未富集的整个微藻水解产物中产生8.015 g L−1乙醇。利用开发的酶制剂,无需预处理即可将微藻生物质中富含碳水化合物的部分转化为第三代生物乙醇。
Enzymatic hydrolysis of carbohydrate-rich Chlorella vulgaris for third-generation bioethanol production by cellulase-recombinant yeast
This study developed a multienzyme preparation for the hydrolysis of microalgal biomass. Possible synergism between enzymes was investigated using carbohydrate-rich Chlorella vulgaris biomass. Under optimum experimental conditions, α-amylase (Termamyl®) at 0.05 g−1 substrate and amyloglucosidase at 0.2 g−1 substrate achieved a maximum reducing sugars yield of 5.639 ± 0.32 g L−1 at a biomass loading of 10 g L−1. Saccharomyces cerevisiae JAYET cells modified with cellulase genes produced 8.015 g L−1 ethanol from unenriched whole microalgal hydrolysate. With the developed enzyme preparation, no pretreatment was necessary to convert the carbohydrate-rich fraction of microalgal biomass into third-generation bioethanol.
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