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酵母β-葡萄糖苷酶的纯化与特性分析

Purification and characterization of yeast beta-glucosidases.

作者信息

Fleming L W, Duerksen J D

出版信息

J Bacteriol. 1967 Jan;93(1):135-41. doi: 10.1128/jb.93.1.135-141.1967.

Abstract

Constitutive beta-glucosidases from Saccharomyces fragilis (Y-18) and S. dobzhanskii (Y-19) precipitated at the same concentration of ammonium sulfate. The partially purified enzymes had similar activation energies, molecular weights, affinities for certain natural and synthetic beta-glucosides, and optimal pH values for substrate hydrolysis, and they were stable over approximately the same pH range. The enzymes, however, could be clearly distinguished by other criteria. Affinities of the synthetic, sulfur-containing beta-glucosides for Y-18 enzyme were many times greater than for Y-19 enzyme. The latter enzyme was more resistant to heat. The two enzymes eluted from diethylaminoethyl cellulose at different concentrations of sodium chloride. In precipitin tests, homologous enzyme-antisera systems were highly specific. The beta-glucosidase synthesized by a hybrid, S. fragilis x S. dobzhanskii (Y-42), was unique. Characterization of this enzyme produced values which were intermediate to those for the enzymes from the parental yeast strains. Heat-inactivation slopes and Lineweaver-Burk plots for the Y-42 enzyme were anomalous. It is suggested that hydrolytic activity in Y-42 preparations is due to a spectrum of hybrid enzyme molecules composed of varying amounts of two distinct polypeptides. It is further suggested that these polypeptides may be identical to those synthesized by the parental Y-18 and Y-19 yeast strains.

摘要

脆壁酵母(Y - 18)和多布赞斯基酵母(Y - 19)的组成型β - 葡萄糖苷酶在相同浓度的硫酸铵中沉淀。部分纯化的酶具有相似的活化能、分子量、对某些天然和合成β - 葡萄糖苷的亲和力以及底物水解的最佳pH值,并且它们在大约相同的pH范围内稳定。然而,这些酶可以通过其他标准清楚地区分。合成的含硫β - 葡萄糖苷对Y - 18酶的亲和力比对Y - 19酶的亲和力大许多倍。后一种酶对热更具抗性。两种酶在不同浓度的氯化钠下从二乙氨基乙基纤维素上洗脱。在沉淀素试验中,同源酶 - 抗血清系统具有高度特异性。脆壁酵母x多布赞斯基酵母(Y - 42)杂交种合成的β - 葡萄糖苷酶是独特的。该酶的特性产生的值介于亲本酵母菌株的酶的值之间。Y - 42酶的热失活斜率和Lineweaver - Burk图是异常的。有人认为Y - 42制剂中的水解活性是由于一系列由不同量的两种不同多肽组成的杂交酶分子。进一步表明,这些多肽可能与亲本Y - 18和Y - 19酵母菌株合成的多肽相同。

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