"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.     

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.     

Genetic and biochemical characterization of the birA gene and its product: evidence for a direct role of biotin holoenzyme synthetase in repression of the biotin operon in Escherichia coli

Lesions at the birA locus of Escherichia coli produce, in varying degrees, derepression of the biotin operon and an increased minimum biotin growth requirement (Barker &; Campbell, 1980) as well as diminished biotin uptake and defective biotin holoenzyme synthetase activity (Campbell et al., 1972, 1980). In the accompanying paper, we showed that three birA mutants produce biotin holoenzyme synthetase with altered in vitro properties and that they carry lesions in the structural gene for this enzyme. The pleiotropic birA defect was attributed to structural interactions between a protein domain which includes the holoenzyme synthetase active site and a second protein domain, possibly part of the same polypeptide, which functions as the bio repressor.To determine if one or more genes reside at birA, we tested pairwise combinations of nine mutations with representative phenotypes for their ability to establish repression of bio expression. The mutations define a single complementation group. Instances of partial complementation appear to be intracistronic, suggesting that the birA product forms a multimer active as both biotin holoenzyme synthetase and repressor.DNA segments that include and express the birA gene have been cloned into multicopy plasmids. Plasmid-mediated expression of birA can produce a state of superrepression of the bio operon and a concomitant increase in holoenzyme synthetase specific activity. The complementation properties of derivative plasmids, with insertions of Tn5 or small deletions in the bacterial DNA segment, define a 1.6 × 10³ base region that includes the birA gene and a 0.9 × 10³ base segment essential to biotin holoenzyme synthetase and repressor function. The region is flanked by the thrT and tufB genes in a previously unassigned region of the bacterial DNA carried by λdrif^d18.A preparation of holoenzyme synthetase, purified nearly 10,000-fold, contains a protein that binds specifically to biotin operator DNA as determined by its ability to protect a TaqI endonuclease site that borders the imperfect inverted repeat where the bio repressor is presumed to bind. Biotinyl 5′-adenylate or biotin plus ATP are more effective corepressors than biotin alone, suggesting that biotinyl 5′-adenylate, a presumed intermediate in the holoenzyme synthetase reaction, is the true corepressor.     

Regulation of purine biosynthetic genes expression inSalmonella typhimurium IV Oc mutation site ofpurG and its function analysis

Salmonella typhimurium 5 phosphoribosylformylglycinamide (FGAR) amidotransferase encoded bypurG gene catalyzes the conversion of FGAR to formylglycinamide ribonucleotide (FGAM) in the presence of glu- tamine and ATP for thede novo purine nucleotide biosynthesis.purG gene is negatively regulated by a repressor-operator system. The O⁺ purG and O^c purG were cloned respectivelyin vivo. Restriction enzymes analysis of preliminary clones pLBG-1 (O⁺) and pLBG-2 (O^c) were carried out. The hybrid plasmids pLB1933 (O⁺) and pLB1927 (O^c) containing 5′ control region ofpurG were constructed and the DNA sequences were determined respectively, DNA sequences data showed that O^c mutation ofpurG occurred at the 3rd position of 16 bp PUR box in the 5′ control region (G→A). Gel retardation experiment indicated that the repressor bound well with O⁺ PUR box, but not with O^c PUR box. The result strongly supported the idea that PUR box is the binding region of repressor protein and the 3rd position base G of PUR box is essential for the binding function with repressor protein.     

Purification and characterization of MerR, the regulator of the broad-spectrum mercury resistance genes in Streptomyces lividans 1326

Streptomyces lividans 1326 carries inducible mercury resistance genes on the chromosome, which are arranged in two divergently transcribed operons. Expression of the genes is negatively regulated by the repressor MerR, which binds in the intercistronic region between the two operons. The merR gene was expressed in E. coli using a T7 RNA polymerase/promoter expression system, and MerR was purified to around 95% homogeneity by ammonium sulfate precipitation, gel filtration and affinity chromatography. Gel filtration showed that the native MerR is a dimer with a molecular mass of 31?kDa. Two DNA binding sites were identified in the intercistronic mer promoter region by footprinting experiments. No evidence for cooperativity in the binding of MerR to the adjacent operator sequences was observed in gel mobility shift assays. The dissociation constants (K_D) for binding of MerR were: binding site I, 8.5?×?10^?9?M; binding site II, 1.2?×?10^?8?M; and for the complete promoter/operator region 1?×?10^?8?M. The half-life of the MerR-DNA complex was 19.4?min and 18.8?min for binding site I and binding site II, respectively. The K_D value for binding of mercury(II)chloride to MerR, again determined by mobility shift assay, was 1.1?×?10^?7?M.     

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.     

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.     

Conformational and thermodynamic hallmarks of DNA operator site specificity in the copper sensitive operon repressor from Streptomyces lividans

Metal ion homeostasis in bacteria relies on metalloregulatory proteins to upregulate metal resistance genes and enable the organism to preclude metal toxicity. The copper sensitive operon repressor (CsoR) family is widely distributed in bacteria and controls the expression of copper efflux systems. CsoR operator sites consist of G-tract containing pseudopalindromes of which the mechanism of operator binding is poorly understood. Here, we use a structurally characterized CsoR from Streptomyces lividans (CsoR^Sl) together with three specific operator targets to reveal the salient features pertaining to the mechanism of DNA binding. We reveal that CsoR^Sl binds to its operator site through a 2-fold axis of symmetry centred on a conserved 5′-TAC/GTA-3′ inverted repeat. Operator recognition is stringently dependent not only on electropositive residues but also on a conserved polar glutamine residue. Thermodynamic and circular dichroic signatures of the CsoR^Sl–DNA interaction suggest selectivity towards the A-DNA-like topology of the G-tracts at the operator site. Such properties are enhanced on protein binding thus enabling the symmetrical binding of two CsoR^Sl tetramers. Finally, differential binding modes may exist in operator sites having more than one 5′-TAC/GTA-3′ inverted repeat with implications in vivo for a mechanism of modular control.     

Tight-binding repressors of the lactose operon

Sixteen mutants which produce lactose repressors with enhanced operator affinities have been isolated. By deletion mapping, six of seven mutations mapped fall into a restricted region of the i gene which also is the location of some anomalous i^s (super-repressor) and some weak i^?d mutations (Pfahl et al., 1974). In vivo and in vitro characterization of nine of the “tight-binding” repressors indicates that: (1) they cause 1.5- to 6-fold decreases in basal β-galactosidase specific activities relative to the parental Q wild-type repressor, and have up to 30-fold increases in operator affinity in vitro. (2) With a few exceptions, the tight-binding repressors show the same relative decreases in basal β-galactosidase specific activities for a wide range of operator types (o⁺ and o^c). (3) With two exceptions, the tight-binding repressors show normal or nearly normal affinities for the inducer, isopropyl-β-d-thiogalactoside, although the concentrations of inducer needed to release various repressors from the o⁺ operator vary greatly.     

lac repressor-operator interaction. Analysis of the X86 repressor mutant

In vitro measurements show that the X86 repressor, which has an increased affinity for the lac operator as compared to wild-type repressor, also has an increased affinity for non-operator sites on Escherichia coli DNA. The rate constant of association of repressor and operator is decreased by E. coli DNA fivefold more for X86 repressor than for wild-type repressor. Low inducer concentrations increase the rate of association of X86 repressor and operator in the presence of E. coli DNA. In a partial equilibrium situation where part of the X86 repressor is bound to the operator, and part to either non-operator sites on E. coli DNA or to an O^c operator, the formation of complexes between X86 repressor and wild-type operator is favored by low inducer concentrations. Repression of the lac enzymes increases drastically in the X86 mutant in the absence of DNA synthesis in vivo. A new explanation for the in vivo characteristics of the X86 mutant is suggested.     

Evidence for leucine zipper motif in lactose repressor protein

Amino acid sequence homology between the carboxyl-terminal segment of the lac repressor and eukaryotic proteins containing the leucine zipper motif with associated basic DNA binding region (bZIP) has been identified. Based on the sequence comparisons, site-specific mutations have been generated at two sites predicted to participate in oligomer formation based on the three-leucine heptad repeat at positions 342, 349, and 356. Leu342----Ala, Leu349----Ala, and Leu349----Pro have been isolated and their oligomeric state and ligand binding properties evaluated. These mutant proteins do not form tetramers but exist as stable dimers with inducer binding comparable with the wild-type protein. Apparent operator affinities for lac repressor proteins with mutations in the proposed bZIP domain were significantly lower than the corresponding wild-type values. For these dimeric mutant proteins, the monomer-dimer equilibrium is linked to the apparent operator binding constant. The values for the monomer-monomer binding constant and for the intrinsic operator binding constant for the dimer cannot be resolved from measurements of the observed Kd for operator DNA. Further studies on these proteins are in progress.     

Response to copper stress in Streptomyces lividans extends beyond genes under direct control of a copper-sensitive operon repressor protein (CsoR)

A copper-sensitive operon repressor protein (CsoR) has been identified in Streptomyces lividans (CsoR^Sl) and found to regulate copper homeostasis with attomolar affinity for Cu(I). Solution studies reveal apo- and Cu^I-CsoR^Sl to be a tetramer assembly, and a 1.7-Å resolution crystal structure of apo-CsoR^Sl reveals that a significant conformational change is necessary to enable Cu(I) binding. In silico prediction of the CsoR regulon was confirmed in vitro (EMSA) and in vivo (RNA-seq), which highlighted that next to the csoR gene itself, the regulon consists of two Cu(I) efflux systems involving a CopZ-like copper metallochaperone protein and a CopA P₁-type ATPase. Although deletion of csoR has only minor effects on S. lividans development when grown under high copper concentrations, mutations of the Cu(I) ligands decrease tolerance to copper as a result of the Cu(I)-CsoR mutants failing to disengage from the DNA targets, thus inhibiting the derepression of the regulon. RNA-seq experiments carried out on samples incubated with exogenous copper and a ΔcsoR strain showed that the set of genes responding to copper stress is much wider than anticipated and largely extends beyond genes targeted by CsoR. This suggests more control levels are operating and directing other regulons in copper homeostasis beside the CsoR regulon.     

Regulation of purine biosynthetic genes expression in Salmonella typhimurium Ⅳ Oc mutation site of purG and its function analysis

Salmonella typhimurium 5 phosphoribosylformylglycinamide (FGAR) amidotransferase encoded bypurG gene catalyzes the conversion of FGAR to formylglycinamide ribonucleotide (FGAM) in the presence of glu- tamine and ATP for thede novo purine nucleotide biosynthesis.purG gene is negatively regulated by a repressor-operator system. The O⁺ purG and O^c purG were cloned respectivelyin vivo. Restriction enzymes analysis of preliminary clones pLBG-1 (O⁺) and pLBG-2 (O^c) were carried out. The hybrid plasmids pLB1933 (O⁺) and pLB1927 (O^c) containing 5′ control region ofpurG were constructed and the DNA sequences were determined respectively, DNA sequences data showed that O^c mutation ofpurG occurred at the 3rd position of 16 bp PUR box in the 5′ control region (G→A). Gel retardation experiment indicated that the repressor bound well with O⁺ PUR box, but not with O^c PUR box. The result strongly supported the idea that PUR box is the binding region of repressor protein and the 3rd position base G of PUR box is essential for the binding function with repressor protein. Project supported by the National Natural Science Foundation of China.     

Cooperative and Anticooperative Effects in Binding of the First and Second Plasmid OsymOperators to a LacI Tetramer: Evidence for Contributions of Non-operator DNA Binding by Wrapping and Looping

The interaction oflacoperator DNA withlacrepressor (LacI) is a classic example of a genetic regulatory switch. To dissect the role of stoichiometry, subunit association, and effects of DNA length in positioning this switch, we have determined binding isotherms for the interaction of LacI with a high affinity (O^sym) operator on linearized plasmid (2500 bp) DNA over a wide range of macromolecular concentrations (10⁻¹⁴to 10⁻⁸M). Binding data were analyzed using a thermodynamic model involving four equilibria: dissociation of tetramers (T) into dimers (D), and binding of operator-containing plasmid DNA (O) to dimers and tetramers to form three distinct complexes, DO, TO, and TO₂. Over the range of con- centrations of repressor, operator, and salt (0.075 M K⁺to 0.40 M K⁺) investigated, we find no evidence for any significant thermodynamic effect of LacI dimers. Instead, all isotherms can be interpreted in terms of just two equilibria, involving only T and the TO and TO₂complexes. As a reference binding equilibrium, which we propose must approximate the DO binding interaction, we compare the plasmid O^symresults with our extensive studies of the binding of a 40 bp O^symDNA fragment to LacI. On this basis, we obtain a lower bound on the LacI dimer – tetramer equilibrium constant and values of the equilibrium constants for formation of TO and TO₂complexes.At a salt concentration of 0.40 M, the O^symplasmid binding data are consistent with a model with two independent and identical binding sites for operator per LacI tetramer, in which the binding to a site on the tetramer is only slightly more favorable than the reference binding interaction. Increasingly large deviations from the independent-site model are observed as the salt concentration is reduced; binding of a second operator to form TO₂becomes strongly disfavored relative to formation of TO at low salt concentrations (0.075 to 0.125 M). In addition, binding of both the first and second plasmid operator DNA molecules to the tetramer becomes increasingly more favorable than the reference binding interaction as [K⁺] is reduced from 0.40 M to 0.125 M. At 0.075 M K⁺, however, the strength of binding of the second plasmid operator DNA to the LacI tetramer is dramatically reduced; this interaction is much less favorable than binding the first plasmid operator DNA, and becomes much less favorable than the reference binding interaction. We propose that these differences arise from changes in the nature of the TO and TO₂complexes with decreasing salt concentration. At low salt concentration, we suggest the hypothesis that flanking non-operator sequences bind non-specifically (coulombically) by local wrapping, and that distant regions of non-operator DNA occupy the second operator-binding site by looping. We propose that wrapping stabilizes both 1:1 and 2:1 complexes at low salt concentration, and that looping stabilizes the 1:1 complex but competitively destabilizes the 2:1 TO₂complex at low salt concentration. These effects must play a role in adjusting the stability and structure of the LacI-lac operator repression complex as the cytoplasmic [K⁺] varies in response to changes in extracellular osmolarity.     

Specific induction of catabolism and its relation to repression of biosynthesis in arginine metabolism of Saccharomyces cerevisiae.

Experimental results are presented in support of the model previously proposed for specific induction of the synthesis of enzymes for arginine catabolism in Saccharomyces cerevisiae (Wiame, 1971a,b), and its connection with end-product repression of arginine biosynthetic enzymes. The data support the occurrence of negative regulation of metabolism in a eukaryote.Operator regions, one for arginase and another for ornithine transaminase, are identified. The operator mutations are fully constitutive. A mutation compatible with the occurrence of a catabolic represser, CARGR, leads to partial pleiotropic constitutivity.The connection between the induction process and the repression of biosynthetic enzymes is due to a common receptor of metabolic signals, an ambivalent repressor ARGR endowed with the property of a usual repressor for anabolic enzymes and playing the role of inducer at the level of CARGR; this cascade process simulates a positive control. argR^? mutations, by producing defective ARGR, “turn on” anabolic enzyme synthesis and “turn off” the synthesis of catabolic enzymes (Fig. 2). The dual role of ARGR is confirmed by the isolation of a mutation argRII^d which, in contrast to the defective properties caused by usual argR^? mutations, causes a dominant hyperactivity toward induction of a catabolic enzyme, but retains recessive hypoactivity toward repression of an anabolic enzyme. Such an ambivalent repressor is a function necessary for mutual, balanced exclusion between opposite metabolisms.Many operator constitutive mutations for arginase, cargA⁺O^?, change the level of enzyme to a similar value, thus defining a genetic function. One of these mutations, cargA⁺O^h, in addition to having unusual genetic behaviour, leads to production of twice as much arginase as cargA⁺O^?. This suggests the existence of another genetic region near the structural gene for this enzyme and an additional regulatory function to be analyzed in a separate paper (Dubois &; Wiame, 1978).