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大肠杆菌外膜中的λ受体作为麦芽糊精和淀粉多糖的结合蛋白。

Lambda receptor in the outer membrane of Escherichia coli as a binding protein for maltodextrins and starch polysaccharides.

作者信息

Ferenci T, Schwentorat M, Ullrich S, Vilmart J

出版信息

J Bacteriol. 1980 May;142(2):521-6. doi: 10.1128/jb.142.2.521-526.1980.

DOI:10.1128/jb.142.2.521-526.1980
PMID:6445892
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC294017/
Abstract

The starch polysaccharides amylose and amylopectin are not utilized by Escherichia coli, but are bound by the bacteria. The following evidence supports the view that the outer membrane lambda receptor protein, a component of the maltose/ maltodextrin transport system is responsible for the binding. (i) Amylose and amylopectin both inhibit the transport of maltose into E. coli. (ii) Both polysaccharides prevent binding of non-utilizable maltodextrins by the intact bacterium, a process previously shown to be dependent on components of the maltose transport system (T. Ferenci, Eur. J. Biochem., in press). (iii) A fluorescent amylopectin derivative, O-(fluoresceinyl thiocarbamoyl)-amylopectin, has been synthesized and shown to bind to E. coli in a reversible, saturable manner. Binding of O-(fluoresceinyl thiocarbamoyl)-amylopectin is absent in mutants lacking the lambda receptor, but mutations in any of the other components of the maltose transport system do not affect binding as long as lambda receptor is present. (iv) Using the inhibition of lambda receptor-dependent O-(fluoresceinyl thiocarbamoyl)-amylopectin binding as an assay, the affinities of the lambda receptor for maltodextrins and other sugars have been estimated. The affinity for dextrins increases with increasing degree of polymerization (K(d) for maltose, 14 mM; for maltotetraose, 0.3 mM; for maltodecaose, 0.075 mM). Maltose and some other di- and trisaccharides are inhibitory to amylopectin binding, but only at concentrations above 1 mM.

摘要

淀粉多糖直链淀粉和支链淀粉不能被大肠杆菌利用,但会被细菌结合。以下证据支持这样一种观点,即外膜λ受体蛋白(麦芽糖/麦芽糊精转运系统的一个组成部分)负责这种结合。(i)直链淀粉和支链淀粉都抑制麦芽糖向大肠杆菌的转运。(ii)这两种多糖都能阻止完整细菌对不可利用的麦芽糊精的结合,此前已证明该过程依赖于麦芽糖转运系统的组分(T. 费伦奇,《欧洲生物化学杂志》,即将发表)。(iii)一种荧光支链淀粉衍生物,O -(荧光素基硫代氨基甲酰基)-支链淀粉,已被合成,并显示以可逆、饱和的方式与大肠杆菌结合。在缺乏λ受体的突变体中不存在O -(荧光素基硫代氨基甲酰基)-支链淀粉的结合,但只要λ受体存在,麦芽糖转运系统其他任何组分的突变都不会影响结合。(iv)利用对λ受体依赖性O -(荧光素基硫代氨基甲酰基)-支链淀粉结合的抑制作为一种测定方法,已估算出λ受体对麦芽糊精和其他糖类的亲和力。对糊精的亲和力随着聚合度的增加而增加(麦芽糖的K(d)为14 mM;麦芽四糖为0.3 mM;麦芽十糖为0.075 mM)。麦芽糖和其他一些二糖及三糖对支链淀粉的结合有抑制作用,但仅在浓度高于1 mM时。

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