isopropyl-thiogalactoside and methyl-methanethiosulfonate

The lactose repressor protein has been modified with three sulfhydryl-specific reagents which form mixed disulfide adducts. Methyl methanethiosulfonate (MMTS) and 5,5'-dithiobis(2-nitrobenzoic acid) (DTNB) completely reacted with all three cysteine residues, whereas only partial reaction was observed with didansylcystine. Cysteines-107 and -140 reacted stoichiometrically with MMTS and DTNB, while Cys-281 was modified only at higher molar ratios. Didansylcystine reacted primarily with cysteines-107 and -140. Affinity of MMTS-modified repressor for 40 base pair operator DNA was decreased 30-fold compared to unmodified repressor, and this decrease correlated with modification of cysteine-281. DTNB-modified repressor bound operator DNA with a 50-fold weaker affinity than unmodified repressor. Modification of the lac repressor with didanylcystine decreased operator binding only 4-fold, and nonspecific DNA binding increased 3-fold compared to unmodified repressor. No change in the inducer equilibrium binding constant was observed following modification with any of these reagents. In contrast, inducer association and dissociation rate constants were decreased approximately 50-fold for repressor completely modified with MMTS or DTNB, while didansylcystine had minimal effect on inducer binding kinetics. Correlation between modification of Cys-281 and the observed decrease in rate constants indicates that this region of the protein regulates the accessibility of the sugar binding site. The parallel between the increase in the Kd for repressor binding to operator, the altered rate constant for inducer binding, and modification of cysteine-281 suggests that this region of the protein is crucially involved in the function of the repressor protein.

Topics: Cysteine; Cystine; Dansyl Compounds; Disulfides; Dithionitrobenzoic Acid; Escherichia coli; Isopropyl Thiogalactoside; Kinetics; Methyl Methanesulfonate; Nitrobenzoates; Operator Regions, Genetic; Protein Binding; Repressor Proteins; Transcription Factors

A monomeric mutant lactose repressor protein (T-41), containing serine at position 282 in place of tyrosine [Schmitz, A., Schmeissner, U., Miller, J. H., & Lu, P. (1976) J. Biol. Chem. 251, 3359-3366], has been purified by a series of chromatographic and precipitation methods. The molecular weight of the mutant as determined by gel filtration was approximately 40,000. The inducer equilibrium binding constant for the mutant was comparable to that of the tetrameric wild-type repressor at pH 7.5, whereas operator DNA binding was not detectable. In contrast to wild-type repressor, equilibrium and kinetic rate constants for inducer binding to the monomer were largely independent of pH; thus, the quaternary structure of the wild-type repressor is required for the pH-associated effects on inducer binding. Although ultraviolet absorbance difference spectra indicated that inducer binding to T-41 protein elicited different changes in the environment of aromatic residues from those generated in wild-type repressor, the shift in the fluorescence emission maximum in response to inducer binding was similar for T-41 and wild-type repressors. Similarity in 1-anilinonaphthalene-8-sulfonic acid binding to monomer and tetramer suggests that this fluorophore does not bind at subunit interfaces. Modification of Cys-281 with methyl methanethiosulfonate was observed at low molar ratios of reagent per T-41 monomer (4-fold). This result is in contrast to data observed for tetrameric wild-type repressor which requires high molar ratios for this cysteine to react. We conclude that Cys-281, adjacent to the site of the T-41 mutation, is located on the surface of the monomer in this region crucial for subunit interaction.

Topics: Antibodies, Monoclonal; Escherichia coli; Genes, Bacterial; Isopropyl Thiogalactoside; Kinetics; Methyl Methanesulfonate; Molecular Weight; Mutation; Repressor Proteins; Transcription Factors