Galactoside-proton Symport in a LacYUN Mutant of Escherichia Coli Investigated by Analysis of Transport Progress Curves

Overview

Journal Biochem J

Specialty Biochemistry

Date 1987 Mar 1

PMID 3036093

Citations 2

Authors

M G Page

Affiliations

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Abstract

The kinetics of galactoside-proton symport catalysed by a wild-type strain and one carrying a mutation, previously reported to cause uncoupling of the symport reaction, have been examined. The mutation does not affect the stoichiometry during the initial period of uptake, when the internal concentration of galactoside is low, but it does result in much greater competition from the galactoside as it is accumulated. Simple methods for the analysis of the uptake progress curves have been developed and used to estimate the initial rate of uptake and affinity for internal galactoside. The maximum rate of uptake is decreased by a factor of 2 at most whereas the affinity for internal galactoside is increased up to 50-fold by the mutation. The pH-dependence of the galactoside efflux reaction is changed in a manner which suggests that the defect is in the interaction between proton-binding and galactoside-binding sites rather than in the structure of either site.

Citing Articles

Use of progress curves to estimate the co-substrate-to-substrate flow ratio of a symport mechanism. Application to the isoleucine-Na+ symport of mouse ascites-tumour cells and to the lactose-proton symport.

Eddy A, Hopkins P, Johnson E Biochem J. 1988; 251(1):111-4.

PMID: 2839154 PMC: 1148970. DOI: 10.1042/bj2510111.

Dependence on pH of substrate binding to a mutant lactose carrier, lacYun, in Escherichia coli. A model for H+/lactose symport.

Yamato I, Anraku Y Biochem J. 1989; 258(2):389-96.

PMID: 2539805 PMC: 1138374. DOI: 10.1042/bj2580389.

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