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.     

Overproduction and rapid purification of the biotin operon repressor from Escherichia coli

The Escherichia coli biotin operon repressor protein (BirA) has been overexpressed at the level of 0.5-1% of the total cellular protein from the plasmid pMBR10. Four lines of evidence demonstrated that authentic BirA protein was produced. First, birA plasmids complemented birA mutants for both the repressor and biotin holoenzyme synthetase activities of BirA. Second, biotin holoenzyme synthase activity was increased in strains containing the overproducing plasmids. Third, deletion of sequences flanking the birA gene did not alter production of the 35-kDa BirA protein, but insertion of oligonucleotide linkers within the birA coding region abolished it. Fourth, the 35-kDa protein copurified with the biotin binding activity normally associated with BirA. The birA protein has been purified to homogeneity in a three-step process involving chromatography on phosphocellulose and hydroxyapatite columns.     

Separation of recombination and SOS response in Escherichia coli RecA suggests LexA interaction sites

RecA plays a key role in homologous recombination, the induction of the DNA damage response through LexA cleavage and the activity of error-prone polymerase in Escherichia coli. RecA interacts with multiple partners to achieve this pleiotropic role, but the structural location and sequence determinants involved in these multiple interactions remain mostly unknown. Here, in a first application to prokaryotes, Evolutionary Trace (ET) analysis identifies clusters of evolutionarily important surface amino acids involved in RecA functions. Some of these clusters match the known ATP binding, DNA binding, and RecA-RecA homo-dimerization sites, but others are novel. Mutation analysis at these sites disrupted either recombination or LexA cleavage. This highlights distinct functional sites specific for recombination and DNA damage response induction. Finally, our analysis reveals a composite site for LexA binding and cleavage, which is formed only on the active RecA filament. These new sites can provide new drug targets to modulate one or more RecA functions, with the potential to address the problem of evolution of antibiotic resistance at its root.     

Isolation and characterization of noncleavable (Ind-) mutants of the LexA repressor of Escherichia coli K-12.

The LexA repressor of Escherichia coli represses a set of genes that are expressed in the response to DNA damage. After inducing treatments, the repressor is inactivated in vivo by a specific cleavage reaction which requires an activated form of RecA protein. In vitro, specific cleavage requires activated RecA at neutral pH and proceeds spontaneously at alkaline pH. We have isolated and characterized a set of lexA mutants that are deficient in in vivo RecA-mediated cleavage but retain significant repressor function. Forty-six independent mutants, generated by hydroxylamine and formic acid mutagenesis, were isolated by a screen involving the use of operon fusions. DNA sequence analysis identified 20 different mutations. In a recA mutant, all but four of the mutant proteins functioned as repressor as well as wild-type LexA. In a strain carrying a constitutively active recA allele, recA730, all the mutant proteins repressed a sulA::lacZ fusion more efficiently than the wild-type repressor, presumably because they were cleaved poorly or not at all by the activated RecA protein. These 20 mutations resulted in amino acid substitutions in 12 positions, most of which are conserved between LexA and four other cleavable proteins. All the mutations were located in the hinge region or C-terminal domain of the protein, portions of LexA previously implicated in the specific cleavage reactions. Furthermore, these mutations were clustered in three regions, around the cleavage site (Ala-84-Gly-85) and in blocks of conserved amino acids around two residues, Ser-119 and Lys-156, which are believed essential for the cleavage reactions. These three regions of the protein thus appear to play important roles in the cleavage reaction.     

The interaction of the trp repressor from Escherichia coli with the trp operator

We have examined the interaction of the trp repressor from Escherichia coli with a 20 base-pair synthetic operator. Nonspecific binding was relatively strong (Kd = 2 microM), but only weakly sensitive to the concentration of added salt [d log Kd)/(d log [Na]) = -1). 1H-NMR studies indicate that the structure of the repressor is not greatly altered on forming the complex, and that few if any of the lysine and arginine residues make direct contact with the DNA. However, the mobility of one of the two tyrosine residues is significantly decreased in the complex. The repressor makes close contact with the major grooves of the operator such that the base protons are broadened much more than expected on the basis of increased correlation time. There are large, differential changes in chemical shifts of the imino protons on forming the complex, as well as changes in the rate constants for exchange. The fraying of the ends is greatly diminished, consistent with a target size of about 20 base-pairs. The effects of the repressor on the NMR spectra and relaxation rate constants can be interpreted as a change in the conformation of the operator, possibly a kinking in the centre of the molecule.     

Demonstration of a specific Escherichia coli SecY-signal peptide interaction

Protein translocation in Escherichia coli is initiated by the interaction of a preprotein with the membrane translocase composed of a motor protein, SecA ATPase, and a membrane-embedded channel, the SecYEG complex. The extent to which the signal peptide region of the preprotein plays a role in SecYEG interactions is unclear, in part because studies in this area typically employ the entire preprotein. Using a synthetic signal peptide harboring a photoaffinity label in its hydrophobic core, we examined this interaction with SecYEG in a detergent micellar environment. The signal peptide was found to specifically bind SecY in a saturable manner and at levels comparable to those that stimulate SecA ATPase activity. Chemical and proteolytic cleavage of cross-linked SecY and analysis of the signal peptide adducts indicate that the binding was primarily to regions of the protein containing transmembrane domains seven and two. The signal peptide-SecY interaction was affected by the presence of SecA and nucleotides in a manner consistent with the transfer of signal peptide to SecY upon nucleotide hydrolysis at SecA.     

Nucleotide sequence and LexA regulation of the Escherichia coli recN gene.

The nucleotide sequence of a 2224 bp region of the Escherichia coli chromosome that carries the LexA regulated recN gene has been determined. A region of 1701 nucleotides encoding a polypeptide of 567 amino acids with a predicted molecular weight of 63,599 was identified as the most probable sequence for the recN structural gene. The proposed initiation codon is preceded by a reasonable Shine-Dalgarno sequence and a promoter region containing two 16 bp sequences, separated by 6 bp, that match the consensus sequence (SOS box) for binding LexA protein. DNA fragments containing this putative promoter region are shown to bind LexA in vitro and to have LexA-regulated promoter activity in vivo. The amino acid sequence of RecN predicted from the DNA contains a region that is homologous to highly conserved sequences found in several DNA repair enzymes and other proteins that bind ATP. A sequence of 9 amino acids was found to be homologous to a region of the RecA protein of E. coli postulated to have a role in DNA/nucleotide binding.     

In vivo interaction of Escherichia coli lac repressor N-terminal fragments with the lac operator

Escherichia coli lac repressor is a tetrameric protein composed of 360 amino acid subunits. Considerable attention has focused on its N-terminal region which is isolated by cleavage with proteases yielding N-terminal fragments of 51 to 59 amino acid residues. Because these short peptide fragments bind operator DNA, they have been extensively examined in nuclear magnetic resonance structural studies. Longer N-terminal peptide fragments that bind DNA cannot be obtained enzymatically. To extend structural studies and simultaneously verify proper folding in vivo, the DNA sequence encoding longer N-terminal fragments were cloned into a vector system with the coliphage T7 RNA polymerase/promoter. In addition to the wild-type lacI gene sequence, single amino acid substitutions were generated at positions 3 (Pro3----Tyr) and 61 (Ser61----Leu) as well as the double substitution in a 64 amino acid N-terminal fragment. These mutations were chosen because they increase the DNA binding affinity of the intact lac repressor by a factor of 10(2) to 10(4). The expression of these lac repressor fragments in the cell was verified by radioimmunoassays. Both wild-type and mutant lac repressor N termini bound operator DNA as judged by reduced beta-galactosidase synthesis and methylation protection in vivo. These observations also resolve a contradiction in the literature as to the location of the operator-specific, inducer-dependent DNA binding domain.     

SOS induction in Escherichia coli by single-stranded DNA of mutant filamentous phage: monitoring by cleavage of LexA repressor.

Infection of Escherichia coli in the presence of chloramphenicol with mutant filamentous phage that are defective in the initiation of minus-strand DNA synthesis induces the SOS response as monitored by cellular LexA levels. This observation demonstrates that single-stranded DNA serves as a primary signal for SOS induction in vivo.     

Characterization of a specific interaction between Escherichia coli thymidylate synthase and Escherichia coli thymidylate synthase mRNA.

Previous studies have shown that human TS mRNA translation is controlled by a negative autoregulatory mechanism. In this study, an RNA electrophoretic gel mobility shift assay confirmed a direct interaction between Escherichia coli (E.coli) TS protein and its own E.coli TS mRNA. Two cis-acting sequences in the E.coli TS mRNA protein-coding region were identified, with one site corresponding to nucleotides 207-460 and the second site corresponding to nucleotides 461-807. Each of these mRNA sequences bind TS with a relative affinity similar to that of the full-length E.coli TS mRNA sequence (IC50 = 1 nM). A third binding site was identified, corresponding to nucleotides 808-1015, although its relative affinity for TS (IC50 = 5.1 nM) was lower than that of the other two cis-acting elements. E.coli TS proteins with mutations in amino acids located within the nucleotide-binding region retained the ability to bind RNA while proteins with mutations at either the nucleotide active site cysteine (C146S) or at amino acids located within the folate-binding region were unable to bind TS mRNA. These studies suggest that the regions on E.coli TS defined by the folate-binding site and/or critical cysteine sulfhydryl groups may represent important RNA binding domains. Further evidence is presented which demonstrates that the direct interaction with TS results in in vitro repression of E.coli TS mRNA translation.     

In vitro interaction of the Escherichia coli cyclic AMP receptor protein with the lactose repressor

Sedimentation equilibrium studies show that the Escherichia coli cyclic AMP receptor protein (CAP) and lactose repressor associate to form a 2:1 complex in vitro. This is, to our knowledge, the first demonstration of a direct interaction of these proteins in the absence of DNA. No 1:1 complex was detected over a wide range of CAP concentrations, suggesting that binding is highly cooperative. Complex formation is stimulated by cAMP, with a net uptake of 1 equivalent of cAMP per molecule of CAP bound. Substitution of the dimeric lacI-18 mutant repressor for tetrameric wild-type repressor completely eliminates detectable binding. We therefore propose that CAP binds the cleft between dimeric units in the repressor tetramer. CAP-lac repressor interactions may play important roles in regulatory events that take place at overlapping CAP and repressor binding sites in the lactose promoter.     

Expression, purification, crystallization, and NMR studies of the helicase interaction domain of Escherichia coli DnaG primase

In Escherichia coli, the DnaG primase is the RNA polymerase that synthesizes RNA primers at replication forks. It is composed of three domains, a small N-terminal zinc-binding domain, a larger central domain responsible for RNA synthesis, and a C-terminal domain comprising residues 434-581 [DnaG(434-581)] that interact with the hexameric DnaB helicase. Presumably because of this interaction, it had not been possible previously to express the C-terminal domain in a stably transformed E. coli strain. This problem was overcome by expression of DnaG(434-581) under control of tandem bacteriophage lambda-promoters, and the protein was purified in yields of 4-6 mg/L of culture and studied by NMR. A TOCSY spectrum of a 2mM solution of the protein at pH 7.0, indicated that its structured core comprises residues 444-579. This was consistent with sequence conservation among most-closely related primases. Linewidths in a NOESY spectrum of a 0.5mM sample in 10mM phosphate, pH 6.05, 0.1M NaCl, recorded at 36 degrees C, indicated the protein to be monomeric. Crystals of selenomethionine-substituted DnaG(434-581) obtained by the hanging-drop vapor-diffusion method were body-centered tetragonal, space group I4(1)22, with unit cell parameters a=b=142.2A, c=192.1A, and diffracted beyond 2.7A resolution with synchrotron radiation.     

Crystallization of the met repressor from Escherichia coli

The met repressor from Escherichia coli has been crystallized in space group P21, with unit cell dimensions a = 35.6 A, b = 62.6 A, c = 44.5 A, beta = 102.4 degrees and one aporepressor dimer per asymmetric unit. Preliminary X-ray diffraction photographs show measurable intensities to beyond 1.5 A resolution, and the crystal form is ideally suited to high-resolution crystallographic analysis (1 A = 0.1 nm).     

Interaction of the LexA repressor and the uvrC regulatory region

We have studied the in vitro interaction of the LexA repressor protein and the uvrC regulatory region. We find that there is specific binding to two regions, the region we have defined as lexA1 and the lexA2-lexA3 region. Our findings support the possibility of an inducible regulation for this complex operon.     

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.