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嗜热栖热放线菌细胞提取物中纤维糊精和纤维二糖的磷酸解和水解裂解的动力学及相对重要性

Kinetics and relative importance of phosphorolytic and hydrolytic cleavage of cellodextrins and cellobiose in cell extracts of Clostridium thermocellum.

作者信息

Zhang Yi-Heng Percival, Lynd Lee R

机构信息

Thayer School of Engineering, Dartmouth College, Hanover, New Hampshire 03755, USA.

出版信息

Appl Environ Microbiol. 2004 Mar;70(3):1563-9. doi: 10.1128/AEM.70.3.1563-1569.2004.

Abstract

Rates of phosphorolytic cleavage of beta-glucan substrates were determined for cell extracts from Clostridium thermocellum ATCC 27405 and were compared to rates of hydrolytic cleavage. Reactions with cellopentaose and cellobiose were evaluated for both cellulose (Avicel)- and cellobiose-grown cultures, with more limited data also obtained for cellotetraose. To measure the reaction rate in the chain-shortening direction at elevated temperatures, an assay protocol was developed featuring discrete sampling at 60 degrees C followed by subsequent analysis of reaction products (glucose and glucose-1-phosphate) at 35 degrees C. Calculated rates of phosphorolytic cleavage for cell extract from Avicel-grown cells exceeded rates of hydrolytic cleavage by > or = 20-fold for both cellobiose and cellopentaose over a 10-fold range of beta-glucan concentrations (0.5 to 5 mM) and for cellotetraose at a single concentration (2 mM). Rates of phosphorolytic cleavage of beta-glucosidic bonds measured in cell extracts were similar to rates observed in growing cultures. Comparisons of V(max) values indicated that cellobiose- and cellodextrin-phosphorylating activities are synthesized during growth on both cellobiose and Avicel but are subject to some degree of metabolic control. The apparent K(m) for phosphorolytic cleavage was lower for cellopentaose (mean value for Avicel- and cellobiose-grown cells, 0.61 mM) than for cellobiose (mean value, 3.3 mM).

摘要

测定了嗜热栖热放线菌(Clostridium thermocellum)ATCC 27405细胞提取物中β-葡聚糖底物的磷酸解裂解速率,并与水解裂解速率进行了比较。对以微晶纤维素(Avicel)和纤维二糖培养的细胞培养物,评估了与纤维五糖和纤维二糖的反应,对于纤维四糖也获得了更有限的数据。为了在高温下测量链缩短方向的反应速率,开发了一种测定方案,其特点是在60℃进行离散取样,随后在35℃分析反应产物(葡萄糖和葡萄糖-1-磷酸)。在10倍的β-葡聚糖浓度范围(0.5至5 mM)内,对于纤维二糖和纤维五糖,以及在单一浓度(2 mM)下对于纤维四糖,来自以Avicel培养的细胞的细胞提取物的磷酸解裂解计算速率超过水解裂解速率≥20倍。在细胞提取物中测得的β-糖苷键磷酸解裂解速率与在生长培养物中观察到的速率相似。V(max)值的比较表明,纤维二糖和纤维糊精磷酸化活性在以纤维二糖和Avicel生长期间均有合成,但受到一定程度的代谢控制。纤维五糖磷酸解裂解的表观K(m)(以Avicel和纤维二糖培养的细胞的平均值,0.61 mM)低于纤维二糖(平均值,3.3 mM)。

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