DNA binding of Escherichia coli arginine repressor mutants altered in oligomeric state

The Escherichia coli arginine repressor (ArgR) controls expression of the arginine biosynthetic genes and acts as an accessory protein in Xer site-specific recombination at cer and related plasmid recombination sites. The hexameric wild-type protein shows L -arginine-dependent DNA binding. In this work, ArgR mutants that are defective in trimer–trimer interactions and bind DNA as trimers in an L -arginine-independent manner are isolated and characterized. Whereas the wild-type ArgR hexamer exhibits high-affinity binding to two repeated ARG boxes separated by 3 bp (each ARG box containing two identical dyad symmetrical 9 bp half-sites), the trimeric mutants bind to and footprint three adjacent half-sites of this 'idealized' substrate. Trimeric ArgR is impaired in its ability to repress the arginine biosynthetic genes and in Xer site-specific recombination. In the absence of L -arginine, residual wild-type ArgR-binding occurs as trimers. The binding of an N-terminal 77-amino-acid DNA-binding domain to idealized ARG boxes is also characterized.     

Mutational analysis of the arginine repressor of Escherichia coli

Arginine biosynthesis in Escherichia coli is negatively regulated by a hexameric repressor protein, encoded by the gene argR and the corepressor arginine. By hydroxylamine mutagenesis two types of argR mutants were isolated and mapped. The first type is transdominant. In heterodiploids, these mutant polypeptides reduce the activity of the wild-type repressor, presumably by forming heteropolymers. Four mutant repressor proteins were purified. Two of these map in the N-terminal half of the protein. Gel retardation experiments showed that they bind poorly to DNA, but they could be precipitated by l -arginine at the same concentration as the wild-type repressor. The other two mutant repressors map in the C-terminal half of the protein. They are poorly precipitated by L-arginine and they bind poorly to DNA. In addition, one of these mutants appears to exist as a dimer. The second type of argR mutant repressor consists of super-repressors. Such mutants behave as arginine auxotrophs as a result of hyper-repression of arginine biosynthetic enzymes. They map at many locations throughout the argR gene. Three arginine super-repressor proteins were purified, in comparison with the wild-type repressor, two of them were shown to have a higher DNA-binding affinity in the absence of bound arginine, while the third was shown to have a higher DNA-binding affinity when bound to arginine.     

The arginine repressor of Escherichia coli.

This review tells the story of the arginine repressor of Escherichia coli from the time of its discovery in the 1950s until the present. It describes how the research progressed through physiological, genetic, and biochemical phases and how the nature of the repressor and its interaction with its target sites were unraveled. The studies of the repression of arginine biosynthesis revealed unique features at every level of the investigations. In the early phase of the work they showed that the genes controlled by the arginine repressor were scattered over the linkage map and were not united, as in other cases, in a single operon. This led to the concept of the regulon as a physiological unit of regulation. It was also shown that different alleles of the arginine repressor could result in either inhibition of enzyme formation, as in E. coli K-12, or in stimulation of enzyme formation, as in E. coli B. Later it was shown that the arginine repressor is a hexamer, whereas other repressors of biosynthetic pathways are dimers. As a consequence the arginine repressor binds to two palindromic sites rather than to one. It was found that the arginine repressor not only acts in the repression of enzyme synthesis but also is required for the resolution of plasmid multimers to monomers, a completely unrelated function. Finally, the arginine repressor does not possess characteristic structural features seen in other prokaryotic repressors, such as a helix-turn-helix motif or an antiparallel beta-sheet motif. The unique features have sustained continuous interest in the arginine repressor and have made it a challenging subject of investigation.     

Quantitative analysis of binding of single-stranded DNA by Escherichia coli DnaB helicase and the DnaB x DnaC complex

DnaB helicase is responsible for unwinding duplex DNA during chromosomal DNA replication and is an essential component of the DNA replication apparatus in Escherichia coli. We have analyzed the mechanism of binding of single-stranded DNA (ssDNA) by the DnaB x DnaC complex and DnaB helicase. Binding of ssDNA to DnaB helicase was significantly modulated by nucleotide cofactors, and the modulation was distinctly different for its complex with DnaC. DnaB helicase bound ssDNA with a high affinity [Kd = (5.09 +/- 0.32) x 10(-8) M] only in the presence of ATPgammaS, a nonhydrolyzable analogue of ATP, but not other nucleotides. The binding was sensitive to ionic strength but not to changes in temperature in the range of 30-37 degrees C. On the other hand, ssDNA binding in the presence of ADP was weaker than that observed with ATPgammaS, and the binding was insensitive to ionic strength. DnaC protein hexamerizes to form a 1:1 complex with the DnaB hexamer and loads it onto the ssDNA by forming a DnaB6 x DnaC6 dodecameric complex. Our results demonstrate that the DnaB6 x DnaC6 complex bound ssDNA with a high affinity [Kd = (6.26 +/- 0.65) x 10(-8) M] in the presence of ATP, unlike the DnaB hexamer. In the presence of ATPgammaS or ADP, binding of ssDNA by the DnaB6 x DnaC6 complex was a lower-affinity process. In summary, our results suggest that in the presence of ATP in vivo, the DnaB6 x DnaC6 complex should be more efficient in binding DNA as well as in loading DnaB onto the ssDNA than DnaB helicase itself.     

Control of arg gene expression in Salmonella typhimurium by the arginine repressor from Escherichia coli K-12

Summary The regulation of synthesis of arg enzymes in Salmonella typhimurium by the arginine repressor of Escherichia coli K-12 has been reevaluated using a strain of S. typhimurium in which the argR gene was rendered nonfunctional by inserting the translocatable tetracyclineresistance element Tn10 into the argR gene. In contrast to previous studies, the introduction of the argR ⁺ allelle of E. coli on an F-prime factor to the argR::Tn10 S. typhimurium strain reduced the synthesis of arg enzymes to essentially wild-type levels. The elevated levels of arg enzymes observed in other hybrid merodiploids may have been the consequence of the formation of hybrid repressor molecules. The readily scoreable phenotype of tetracycline resistance facilitated establishing linkage of cod and argR (0.6% cotransduction) by P22 phage-mediated transduction.     

Genetic studies of the lac repressor. XII. Amino acid replacements in the DNA binding domain of the Escherichia coli lac repressor

Out of the first 62 residues of the lac repressor, 38 positions have been substituted by at least one amino acid exchange. The total number of replacements in this region is 131. Data from several studies are considered.     

Binding of the arginine repressor of Escherichia coli K12 to its operator sites.

In the arginine regulon of Escherichia coli K12 each of the eight operator sites consists of two 18-base-pair-long palindromic sequences called ARG boxes. In the operator sites for the structural genes of the regulon the two ARG boxes are separated by three base-pairs, in the regulatory gene argR they are separated by two base-pairs. The hexameric arginine repressor, the product of argR, binds to the two ARG boxes in an operator in the presence of L-arginine. From the results of various kinds of in vitro footprinting experiments with the ARG boxes of argF and argR (DNase I protection, hydroxyl radical, ethylation and methylation interference, methylation protection) it can be concluded that: (1) the repressor binds simultaneously to two adjacent ARG boxes; (2) that it binds on one face of the double helix; and (3) that it forms contacts with the major and minor grooves of each ARG box, but not with the central three base-pairs. The repressor can bind also to a single ARG box, but its affinity is about 100-fold lower than for two ARG boxes. From gel retardation experiments with 3H-labeled repressor and 32P-labeled argF operator DNA, it is concluded that the retarded DNA-protein complex contains no more than one repressor molecule per operator site and that most likely one hexamer binds to two ARG boxes. The bound repressor was shown to induce bending of argF operator DNA. The bending angle calculated from the results of gel retardation experiments is about 70 degrees and the bending center was located within the region encompassing the ARG boxes. The main features that distinguish the arginine repressor from other repressors studied in E. coli are its hexameric nature and the simultaneous binding of one hexameric molecule to two palindromic ARG boxes that are close to each other.     

Structural characterization and corepressor binding of the Escherichia coli purine repressor.

The Escherichia coli purine repressor, PurR, binds to a 16-bp operator sequence and coregulates the genes for de novo synthesis of purine and pyrimidine nucleotides, formation of a one-carbon unit for biosynthesis, and deamination of cytosine. We have characterized the purified repressor. Chemical cross-linking indicates that PurR is dimeric. Each subunit has an N-terminal domain of 52 amino acids for DNA binding and a C-terminal 289-residue domain for corepressor binding. Each domain was isolated after cleavage by trypsin. Sites for dimer formation are present within the corepressor binding domain. The corepressors hypoxanthine and guanine bind cooperatively to distinct sites in each subunit. Competition experiments indicate that binding of one purine abolishes cooperativity and decreases the affinity and the binding of the second corepressor. Binding of each corepressor results in a conformation change in the corepressor binding domain that was detected by intrinsic fluorescence of three tryptophan residues. These experiments characterize PurR as a complex allosteric regulatory protein.     

Escherichia coli lac repressor is elongated with its operator DNA binding domains located at both ends

From small-angle X-ray scattering experiments on solutions of Escherichia coli lac repressor and repressor tryptic core, we conclude that the domains of repressor that bind to operator DNA lie at the ends of an elongated molecule. The addition of the inducer, isopropyl-β-d-thiogalactoside, to either repressor or core does not produce a measurable structural change, since the radius of gyration of repressor is 40.3 ± 1.9 Å without and 42.2 ± 1.7 Å with isopropyl-β-d-thiogalactoside; the core radius of gyration is 35.4 ± 1.1 Å without ligand and 36.3 ± 1.1 Å with isopropyl-β-d-thiogalactoside. In the context of data from single crystals of repressor and core, the measured radii of gyration are shown to be consistent with a core (or repressor) molecule of dimensional anisotropy 1: (1.5 to 2.0): (3.0 to 4.0). The 5 Å difference in radius of gyration between native and core repressor is interpreted to mean that the amino terminal 59 residues (headpieces) lie at the ends of an elongated repressor molecule. This structure implies that the repressor may have DNA binding sites, consisting of two adjacent headpieces, on each end of the molecule and this binds to the DNA with its long axis perpendicular to the DNA.     

An analysis of the binding of repressor protein ModE to modABCD (molybdate transport) operator/promoter DNA of Escherichia coli.

Expression of the modABCD operon in Escherichia coli, which codes for a molybdate-specific transporter, is repressed by ModE in vivo in a molybdate-dependent fashion. In vitro DNase I-footprinting experiments identified three distinct regions of protection by ModE-molybdate on the modA operator/promoter DNA, GTTATATT (-15 to -8; region 1), GCCTACAT (-4 to +4; region 2), and GTTACAT (+8 to +14; region 3). Within the three regions of the protected DNA, a pentamer sequence, TAYAT (Y = C or T), can be identified. DNA-electrophoretic mobility experiments showed that the protected regions 1 and 2 are essential for binding of ModE-molybdate to DNA, whereas the protected region 3 increases the affinity of the DNA to the repressor. The stoichiometry of this interaction was found to be two ModE-molybdate per modA operator DNA. ModE-molybdate at 5 nM completely protected the modABCD operator/promoter DNA from DNase I-catalyzed hydrolysis, whereas ModE alone failed to protect the DNA even at 100 nM. The apparent K(d) for the interaction between the modA operator DNA and ModE-molybdate was 0.3 nM, and the K(d) increased to 8 nM in the absence of molybdate. Among the various oxyanions tested, only tungstate replaced molybdate in the repression of modA by ModE, but the affinity of ModE-tungstate for modABCD operator DNA was 6 times lower than with ModE-molybdate. A mutant ModE(T125I) protein, which repressed modA-lac even in the absence of molybdate, protected the same region of modA operator DNA in the absence of molybdate. The apparent K(d) for the interaction between modA operator DNA and ModE(T125I) was 3 nM in the presence of molybdate and 4 nM without molybdate. The binding of molybdate to ModE resulted in a decrease in fluorescence emission, indicating a conformational change of the protein upon molybdate binding. The fluorescence emission spectra of mutant ModE proteins, ModE(T125I) and ModE(Q216*), were unaffected by molybdate. The molybdate-independent mutant ModE proteins apparently mimic in its conformation the native ModE-molybdate complex, which binds to a DNA sequence motif of TATAT-7bp-TAYAT.     

Differential binding of allolactose anomers to the lactose repressor of Escherichia coli.

Preferential binding of the β-anomer of allolactose to the lactose repressor of Escherichia coli was demonstrated by two methods: (1) by repeated washing of ammonium sulfate precipitates of the allolactose-repressor complex and (2) by competitive inhibition of allolactose binding by isopropyl-β-d-thiogalacto-side. Quantitation showed that one β-allolactose binds per isopropyl-β-d-thiogalactoside binding site. A control system is postulated.     

Mutational analysis of the thermostable arginine repressor from Bacillus stearothermophilus: dissecting residues involved in DNA binding properties.

Recently the crystal structure of the DNA-unbound form of the full-length hexameric Bacillus stearothermophilus arginine repressor (ArgR) has been resolved, providing a possible explanation for the mechanism of arginine-mediated repressor-operator DNA recognition. In this study we tested some of these functional predictions by performing site-directed mutagenesis of distinct amino acid residues located in two regions, the N-terminal DNA-binding domain and the C-terminal oligomerization domain of ArgR. A total of 15 mutants were probed for their capacity to repress the expression of the reporter argC - lacZ gene fusion in Escherichia coli cells. Substitutions of highly conserved amino acid residues in the alpha2 and alpha3 helices, located in the winged helix-turn-helix DNA-binding motif, reduced repression. Loss of DNA-binding capacity was confirmed in vitro for the Ser42Pro mutant which showed the most pronounced effect in vivo. In E. coli, the wild-type B. stearothermophilus ArgR molecule behaves as a super-repressor, since recombinant E. coli host cells bearing B. stearothermophilusargR on a multicopy vector did not grow in selective minimal medium devoid of arginine and grew, albeit weakly, when l -arginine was supplied. All mutants affected in the DNA-binding domain lost this super-repressor behaviour. Replacements of conserved leucine residues at positions 87 and/or 94 in the C-terminal domain by other hydrophobic amino acid residues proved neutral or caused either derepression or stronger super-repression. Substitution of Leu87 by phenylalanine was found to increase the DNA-binding affinity and the protein solubility in the context of a double Leu87Phe/Leu94Val mutant. Structural modifications occasioned by the various amino acid substitutions were confirmed by circular dichroism analysis and structure modelling.     

Mechanism of DNA binding by the DnaB helicase of Escherichia coli: analysis of the roles of domain gamma in DNA binding.

We have analyzed the mechanism of single-stranded DNA (ssDNA) binding mediated by the C-terminal domain gamma of the DnaB helicase of Escherichia coli. Sequence analysis of this domain indicated a specific basic region, "RSRARR", and a leucine zipper motif that are likely involved in ssDNA binding. We have carried out deletion as well as in vitro mutagenesis of specific amino acid residues in this region in order to determine their function(s) in DNA binding. The functions of the RSRARR domain in DNA binding were analyzed by site-directed mutagenesis. DnaBMut1, with mutations R(328)A and R(329)A, had a significant decrease in the DNA dependence of ATPase activity and lost its DNA helicase activity completely, indicating the important roles of these residues in DNA binding and helicase activities. DnaBMut2, with mutations R(324)A and R(326)A, had significantly attenuated DNA binding as well as DNA-dependent ATPase and DNA helicase activities, indicating that these residues also play a role in DNA binding and helicase activities. The role(s) of the leucine zipper dimerization motif was (were) determined by deletion analysis. The DnaB Delta 1 mutant with a 55 amino acid C-terminal deletion, which left the leucine zipper and basic DNA binding regions intact, retained DNA binding as well as DNA helicase activities. However, the DnaB Delta 2 mutant with a 113 amino acid C-terminal deletion that included the leucine zipper dimerization motif, but not the RSRARR sequence, lost DNA binding, DNA helicase activities, and hexamer formation. The major findings of this study are (i) the leucine zipper dimerization domain, I(361)-L(389), is absolutely required for (a) dimerization and (b) ssDNA binding; (ii) the base-rich RSRARR sequence is required for DNA binding; (iii) three regions of domain gamma (gamma I, gamma II, and gamma III) differentially regulate the ATPase activity; (iv) there are likely three ssDNA binding sites per hexamer; and (v) a working model of DNA unwinding by the DnaB hexamer is proposed.     

Salt dependence of DNA binding by Thermus aquaticus and Escherichia coli DNA polymerases

DNA binding properties of the Type 1 DNA polymerases from Thermus aquaticus (Taq, Klentaq) and Escherichia coli (Klenow) have been examined as a function of [KCl] and [MgCl(2)]. Full-length Taq and its Klentaq "large fragment" behave similarly in all assays. The two different species of polymerases bind DNA with sub-micromolar affinities in very different salt concentration ranges. Consequently, at similar [KCl] the binding of Klenow is approximately 3 kcal/mol (150x) tighter than that of Taq/Klentaq to the same DNA. Linkage analysis reveals a net release of 2-3 ions upon DNA binding of Taq/Klentaq and 4-5 ions upon binding of Klenow. DNA binding of Taq at a higher temperature (60 degrees C) slightly decreases the ion release. Linkage analysis of binding versus [MgCl(2)] reports the ultimate release of approximately 1 Mg(2+) ion upon complex formation. However, the MgCl(2) dependence for Klenow, but not Klentaq, shows two distinct phases. In 10 mm EDTA, both polymerase species still bind DNA, but their binding affinity is significantly diminished, Klenow more than Klentaq. In summary, the two polymerase species, when binding to identical DNA, differ substantially in their sensitivity to the salt concentration range, bind with very different affinities when compared under similar conditions, release different numbers of ions upon binding, and differ in their interactions with divalent cations.     

Nucleotide sequence binding specificity of the LexA repressor of Escherichia coli K-12.

The specificity of LexA protein binding was investigated by quantifying the repressibility of several mutant recA and lexA operator-promoter regions fused to the Escherichia coli galactokinase (galK) gene. The results of this analysis indicate that two sets of four nucleotides, one set at each end of the operator (terminal-nucleotide contacts), are most critical for repressor binding. In addition, our results suggest that the repressor-operator interaction is symmetric in nature, in that mutations at symmetrically equivalent positions in the recA operator have comparable effects on repressibility. The symmetry of this interaction justified reevaluation of the consensus sequence by half-site comparison, which yielded the half-site consensus (5')CTGTATAT. Although the first four positions of this sequence were most important, the last four were well conserved among binding sites and appeared to modulate repressor affinity. The role of the terminal-nucleotide contacts and the mechanism by which the internal sequences affected repressor binding are discussed.