DNA-binding site of lac repressor probed by dimethylsulfate methylation of lac operator.

In order to compare the structures of the DNA-binding sites on variants of the lac repressor, we have studied the influence of these variants on the dimethylsulfate methylation of the lac operator. Since a bound protein changes the availability of specific purines in the operator to this chemical attack, comparisons of the methylation patterns will show similarities or differences in the protein DNA contacts. We compared lac repressor, induced lac repressor (repressor bound to the gratuitous inducer isopropyl-β-d-thiogalactoside), mutant repressors having increased operator affinities (X86, I12 and the X86-I12 double mutant) and repressor peptides (long headpiece, residues 1 to 59 and short headpiece. residues 1 to 51). All of these repressors and repressor peptides exhibit the same general pattern of protection and enhancement in the operator; however, the short headpiece pattern differs most from that of the repressor while the induced repressor and the long headpiece show intermediate patterns that are strikingly similar to each other. The mutant repressors do not show an isopropyl-β-d-thiogalactoside effect but otherwise are almost indistinguishable from wild-type repressor. These results demonstrate that all molecules bind to the operator using basically the same protein-DNA contacts; they imply that (1) most and possibly all repressor contacts to operator lie within amino acids 1 to 51, (2) inducer weakens many contacts rather than totally disrupting one or even a few and (3) the tight-binding mutants do not make additional contacts to the DNA.These results are consistent with a model in which the amino-terminal portions of two repressor monomers make the DNA contacts. We show that one can understand the affinity of binding as related to the accuracy of the register of the two amino-terminal portions along the DNA. Furthermore, the action of inducer and the behaviour of the tight binding mutants can be accomodated within a two-state model in which the strongly or weakly binding states correspond to structures in which the amino-terminal regions are rigidly or loosely held with respect to each other.     

"Second" and "third operator" of the lac operon: an investigation of their role in the regulatory mechanism.

The influence of the two operator-like regions lying within or near the lac regulatory region on the binding of lac repressor to lac operator has been investigated. λdlac phages deleted either for the “second operator” in the beginning of the Z gene or deleted for the “third operator” at the end of the I gene were constructed. In in vitro binding experiments it could be shown that the deletion of secondary repressor binding sites from the lac regulatory region does not significantly alter the stability of the repressor—operator complex. Measuring the rate constant of association of repressor with operator in the presence of a 150-fold excess of unspecific DNA, we observed a concentration-dependent effect of the unspecific DNA, although the ratio of operator to non-operator DNA was kept constant. A small effect of the secondary binding sites is seen on the rate of association of repressor with operator, indicating that the secondary binding sites might play a role in facilitating association of repressor with operator under _{in vivo} conditions.     

Induction of the lac promoter in the absence of DNA loops and the stoichiometry of induction

In vivo induction of the Escherichia coli lactose operon as a function of inducer concentration generates a sigmoidal curve, indicating a non-linear response. Suggested explanations for this dependence include a 2:1 inducer–repressor stoichiometry of induction, which is the currently accepted view. It is, however, known for decades that, in vitro, operator binding as a function of inducer concentration is not sigmoidal. This discrepancy between in vivo and in vitro data has so far not been resolved. We demonstrate that the in vivo non-linearity of induction is due to cooperative repression of the wild-type lac operon through DNA loop formation. In the absence of DNA loops, in vivo induction curves are hyperbolic. In the light of this result, we re-address the question of functional molecular inducer–repressor stoichiometry in induction of the lac operon.     

Sequence-specific interactions of the tight-binding I12-X86 lac repressor with non-operator DNA.

The tight-binding I12-X86 lac repressor binds to non-operator DNA in a sequence-specific fashion. Using the DNA of the E. coli I gene we have investigated these sequence-specific interactions and compared them to the operator binding of wild-type repressor. The specific, non-operator DNA interactions are sensitive to the inducer IPTG. One strong binding site in the I gene DNA was found to be one of two expected on the basis of their homology with the lac operator. The binding of I12-X86 repressor to this site was visualized using the footprinting technique, and found to be consistent with an operator-like binding configuration. The protection pattern extends into an adjacent sequence suggesting that two repressor tetramers are bound in tandem.     

Studied on gene control regions IX. The effect of hypoxanthine-substituted lac operators on the lac operator--lac repressor interaction.

Hypoxanthine was substituted for guanine at specific sites in the lac operator DNA by a combination of chemical and enzymatic procedures. The stability of these modified lac operators with wild-type (SQ) and tight binding (QX86) lac repressors was measured. Effects were variable. At some sites insertion of hypoxanthine significantly reduced the stability of the complex whereas at other sites substitution with hypoxanthine did not alter the repressor—operator interaction. In addition, insertion of this analog at two sites increased the stability of the complexes. These changes were used to partially map regions of the lac operator that are in contact with lac represser. The results suggest that lac repressor recognizes the guanine 2-amino group at specific sites in the minor groove of lac operator.     

Interaction of mutant lambda repressors with operator and non-operator DNA

We have described a set of mutations that alter side-chains on the operator binding surface of lambda repressor. In this paper, we study the interactions of 12 purified mutant repressors with operator and non-operator DNA. The mutant proteins have operator affinities that are reduced from tenfold to greater than 10,000-fold compared to wild-type. Nine of the mutants have affinities for non-operator DNA that are similar to wild-type, two mutants show decreased non-specific binding, and one mutant has increased affinity for non-operator DNA. We discuss these findings in terms of the structural and energetic contributions of side-chain--DNA interactions, and show that certain contacts between the repressor and the operator backbone contribute both energy and specificity to the interaction.     

Recognition sequences of repressor and polymerase in the operators of bacteriophage lambda

Nucleotide sequences in two wild-type and six mutant operators in the DNA of phage λ are compared. Strikingly similar 17 base pair units are found which we identify as the repressor binding sites. Each operator contains multiple repressor binding sites separated by A-T rich spacers. Elements of 2 fold rotational symmetry are present in each of the sites. Superimposed on each operator is an E. coli RNA polymerase recognition site (promoter). Similarities in the sequences of the two λ promoters, a lac promoter, and an E. coli RNA polymerase recognition site in SV40 DNA are noted.     

Repressor--operator interaction in the lac operon. II. Observations at the tyrosines and tryptophans

This paper shows that ¹⁹F-nuelear magnetic resonance spectroscopy on 3-fluoro-tyrosine and 5-fluorotryptophan-substituted wild-type lactose operon repressors from Escherichia coli can be used to examine the interactions with lac operator DNA.A survey of inducer and salt concentration effects on the repressor-operator complex is presented. The data lead us to a scheme for the interactions between the repressor, operator and inducer, in both binary and ternary complexes, that accommodate the results published by others.The complex between the tetrameric repressor and one 36 base-pair operator DNA fragment results in the simultaneous broadening of the resonances from all four N-terminal DNA binding domains. The actual contacts made by these binding domains are similar but probably not identical.The binding of the inducer molecule to the tetrameric repressor results in an allosteric change that can be monitored by the increased intensity of the resonances from individual tyrosine residues in the N-terminal binding domain. This increased N-terminal tyrosine resonance intensity in the complex is transmitted to repressor subunits that have not yet bound an inducer molecule.     

lac Repressor-operator interaction. IX. The binding of lac repressor to operators containing Oc mutations

Representative members of the six classes of operator constitutive (O^c) point mutations, which have been mapped and well characterized in vivo, were crossed into λφ80 lac phages. The phage DNAs containing the O^c mutations were used to measure the affinity of the lac repressor (R) for each O^c operator by determining the half-lives of the different RO^c complexes in vitro. The results provide evidence that: (a) the higher the constitutive level of β-galactosidase in vivo, as the result of an O^c mutation, the lower the affinity of the lac repressor for that O^c operator, with a maximum difference of two orders of magnitude in affinity of the repressor for the highest O^c tested as compared to the wild type O⁺ operator; (b) the six classes of O^c operators appear to be twofold degenerate, in that two members of each class, which were previously distinguished by mapping, have the same affinity for the lac repressor; (c) an inducer and an anti-inducer have the same effect on the RO^c complexes as on the RO⁺ complexes; (d) the relationship between induction ratios in vivo and the binding constant of the repressor for each O^c mutation in vitro does not follow the mass action equation but rather a more complex dependency, which is discussed.These results suggest a functional symmetry in the lac operator.     

Purification of Lac repressor protein using polymer displacement and immobilization of the protein

Lac repressor protein was purified from E. coli BMH8117 harboring plasmid pWB1000 and E. coli K₁₂BMH 71-18 strains. Displacement of the protein with poly(ethyleneimine) (PEI) from phosphocellulose cation exchange column was shown to be an effective elution strategy. It resulted in better recoveries and sharper elution profiles than traditional salt elution without effecting the purity of the protein. The elution is assumed to proceed via displacement of bound protein by PEI when the polymer binds to the ion exchanger. The minor impurities in the protein solution were finally removed by chromatography on immobilized metal affinity column. The repressor protein undergoes distinct conformational changes upon addition of specific inducer isopropyl--D-thiogalactoside (IPTG), which is evidenced by changes in ultraviolet absorption spectrum. The protein was immobilized covalently to the Sepharose matrix. The intact biological activity of the protein after immobilization was shown by binding of genomic DNA and lac operator plasmid DNA from E. coli to the immobilized lac repressor.     

Heterogeneity of the two tryptophanyl residues in the lac repressor of Escherichia coli.

The wild-type lac repressor of Escherichia coli is a tetrameric protein which contains two tryptophanyl residues per subunit at positions 190 and 209. Solute perturbation studies of the tryptophan fluorescence of the repressor were performed using a polar but uncharged quencher, acrylamide, to prevent possible bias caused by ionic quenchers. The results indicate that the two tryptophan residues have different accessibilities to the quencher. In addition, contrary to a previous report, the accessibility of these tryptophan residues is not altered by isopropyl-β-d-thiogalactoside (IPTG) binding to the repressor. Similar studies with mutant lac repressor containing only a single tryptophan either at positions 190 or 209 suggest that tryptophan 209 is located in a region which is perturbed by inducer binding. That the two tryptophanyl residues have heterogeneous environments was further confirmed by nanosecond fluorescence spectroscopy which showed the wild-type lac repressor exhibiting two excited-state lifetimes, τ₁ = 5.3 ns and τ₂ = 10 ns. In the presence of 10^?3m IPTG, only a single lifetime of 6 ns was observed for the wild-type repressor suggesting that the inducer perturbs the tryptophan residue with the longer lifetime but not the one with the shorter lifetime. This is in accord with the observation that the mutant repressor containing only tryptophan 190 (the Tyr-209 repressor) has a single lifetime of 4.5 ns which is not altered by IPTG binding. The surprising finding that the mutant repressor which contains only tryptophan 209 (the Tyr-190 repressor) shows two excited-state lifetimes has been interpreted to indicate that the repressor either does not exhibit fourfold symmetry in its subunit arrangement or is present in two different conformational states.     

Complexes of Escherichia coli lac-repressor with non-operator DNA revealed by electron microscopy: two repressor molecules can share the same segment of DNA.

Complexes of Escherichia coli lac-repressor with non-operator DNA have been visualized in the electron microscope using high-resolution metal shadowing and negative staining. Under conditions of a high ratio of repressor to DNA, all the DNA molecules are covered by repressor molecules and the resulting complexes appear as flattened ribbons with a width of approximately 200 Å. The overall dimensions of these complexes and their substructure indicate that it is very likely that repressor molecules are tightly packed on both “sides” of the DNA helix. Thus two repressor molecules can share the same segment of non-operator DNA by binding to opposite sides of the DNA helix.     

The possible roles of residues 79 and 80 of the Trp repressor from Escherichia coli K-12 in trp operator recognition

We constructed mutants of the Trp repressor from Escherichia coli K-12 with all possible single amino acid exchanges at positions 79 and 80 (residues 1 and 2 of the recognition helix). We tested these mutants in vivo by measuring the repression of synthesis of β-galactosidase with symmetric variants of α- and β-centered trp operators, which replace the lac operator in a synthetic lac system. The Trp repressor carrying a substitution of isoleucine 79 by lysine, showed a marked specificity change with respect to base pair 7 of the α-centered trp operator. Gel retardation experiments confirmed this result. Trp repressor mutant IR79 specifically recognizes a trp operator variant with substitutions in positions 7 and 8. Another mutant, with glycine in position 79, exhibited loss of contact at base pair 7. We speculate that the side chain of Ile79 interacts with the AT base pairs 7 and 8 of the α-centered trp operator, possibly with the methyl groups of thymines. Replacement of thymine in position 7 or 8 by uracil confirms the involvement of the methyl group of thymine 8 in repressor binding. Several Trp repressor mutants in position 80 (i.e. AI80, AL80, AM80 and AP80) broaden the specificity of the Trp repressor for α-centered trp operator variants with exchanges in positions 3, 4 and 5.     

The loopometer: a quantitative in vivo assay for DNA-looping proteins

Proteins that can bring together separate DNA sites, either on the same or on different DNA molecules, are critical for a variety of DNA-based processes. However, there are no general and technically simple assays to detect proteins capable of DNA looping in vivo nor to quantitate their in vivo looping efficiency. Here, we develop a quantitative in vivo assay for DNA-looping proteins in Escherichia coli that requires only basic DNA cloning techniques and a LacZ assay. The assay is based on loop assistance, where two binding sites for the candidate looping protein are inserted internally to a pair of operators for the E. coli LacI repressor. DNA looping between the sites shortens the effective distance between the lac operators, increasing LacI looping and strengthening its repression of a lacZ reporter gene. Analysis based on a general model for loop assistance enables quantitation of the strength of looping conferred by the protein and its binding sites. We use this ‘loopometer’ assay to measure DNA looping for a variety of bacterial and phage proteins.     

Mechanism of promoter repression by Lac repressor–DNA loops

The Escherichia coli lactose (lac) operon encodes the first genetic switch to be discovered, and lac remains a paradigm for studying negative and positive control of gene expression. Negative control is believed to involve competition of RNA polymerase and Lac repressor for overlapping binding sites. Contributions to the local Lac repressor concentration come from free repressor and repressor delivered to the operator from remote auxiliary operators by DNA looping. Long-standing questions persist concerning the actual role of DNA looping in the mechanism of promoter repression. Here, we use experiments in living bacteria to resolve four of these questions. We show that the distance dependence of repression enhancement is comparable for upstream and downstream auxiliary operators, confirming the hypothesis that repressor concentration increase is the principal mechanism of repression loops. We find that as few as four turns of DNA can be constrained in a stable loop by Lac repressor. We show that RNA polymerase is not trapped at repressed promoters. Finally, we show that constraining a promoter in a tight DNA loop is sufficient for repression even when promoter and operator do not overlap.     

Binding of E.coli lac repressor to non-operator DNA*

It is shown by melting profile analysis of lac repressor-DNA complexes that repressor binds tightly and preferentially (relative to single-stranded DNA) to double-stranded non-operator DNA. This binding stabilizes the DNA against melting and the repressor against thermal denaturation. Analysis of the extent of stabilization and the rate of dissociation of repressor from non-operator DNA as a function of sodium ion concentration shows, in confirmation of other studies,(3,4) that the binding constant (K(RD)) is very ionic strength dependent; K(RD) increases from approximately 10(6) M(-1) at approximately 0.1 M Na(+) to values in excess of 10(10) M(-1) at 0.002 M Na(+). Repressor bound to non-operator DNA is not further stabilized against thermal denaturation by inducer binding, indicating that the inducer and DNA binding sites probably represent separately stabilized local conformations. Transfer melting experiments are used to measure the rate of dissociation of repressor from operator DNA. These experiments show that most of the ionic strength dependence of the binding constant is in the dissociation process; the estimated dissociation rate constant decreases from greater than 10(-1) sec(-1) at [Na(+)] >/= 0.02 M to less than 10(-4) sec(-1) at [Na(+)] 相似文献   

Restriction and modification enzymes detect no allosteric changes in DNA with bound lac repressor or RNA polymerase

A 203 base-pair fragment containing the lac operator/promoter region of Escherichia coli was inserted into the EcoRI site of the plasmid vector pKC7. Rates of restriction endonuclease cleavage of the flanking EcoRI sites and of several other restriction sites on the DNA molecule were then compared in the presence and absence of bound RNA polymerase or lac repressor. The rates were identical whether or not protein had been bound, even for sites as close as 40 base-pairs from a protein binding site. No difference was detected using supercoiled, nicked circular, or linear DNA substrates. No apparent change in the rates of methylation of EcoRI sites by EcoRI methylase was produced by binding the regulatory proteins.