Temperature regulation of heat-labile enterotoxin (LT) synthesis in Escherichia coli is mediated by an interaction of H-NS protein with the LT A-subunit DNA.

Protein and mRNA levels of heat-labile enterotoxin (LT) of Escherichia coli are highest at 37 degrees C, and they decrease gradually as temperature is decreased. This temperature effect is eliminated in an Hns- mutant. Deletion of portions of DNA coding for the LT A subunit also results in an increase in LT expression at low temperatures, suggesting that the H-NS protein causes inhibition of transcription at low temperatures by interacting with the LT A-subunit DNA. The region that interacts with H-NS is referred to as the downstream regulatory element (DRE). Plasmids in an hns strain from which the DRE has been deleted still produce elevated levels of LT at 18 degrees C, suggesting that intact DRE is not required for transcription from the LT promoter.

A superrepressor mutant of the arginine repressor with a correctly predicted alteration of ligand binding specificity.

Arginine biosynthesis in Escherichia coli is negatively regulated by the hexameric repressor protein ArgR and the corepressor L-arginine. L-Arginine binds to ArgR in the C-terminal domain of the repressor. Binding to operator DNA occurs in the N-terminal domain. The molecular structures of both domains have recently been elucidated. The known stereochemistry of the arginine binding pocket was used for the rational design of a mutant ArgR with altered ligand specificity. Our prediction was that a replacement of Asp128 by asparagine would preferentially lead to the binding of L-citrulline, rather than L-arginine. The D128N mutant was constructed and was shown to fulfill our expectation by several experimental approaches. By isothermal titration calorimetry it was found to bind L-citrulline much more strongly than L-arginine, in contrast to wild-type ArgR. Exchange between the mutant trimers of the hexamer was inhibited by L-citrulline, as it is by L-arginine in the wild-type. The mutant protein was precipitated by L-citrulline but not by L-arginine, whereas the reverse is true for the wild-type protein. Demonstration of a corepressor action was, however, precluded by the superrepressor effect of the D128N mutation by itself. The mutant protein, in the absence of L-citrulline or L-arginine is as strong a repressor as the wild-type protein in the presence of L-arginine. We discuss two possible mechanisms, in terms of the known domain structures that could explain our observations.

Interactions of the RepA1 protein with its replicon targets: two opposing roles in control of plasmid replication.

By studying the interaction of derivatives of RepFIC miniplasmids, we were able to demonstrate that under certain conditions the RepA1 initiator protein inhibits plasmid replication. An analysis of cloned derivatives whose replication is inhibited by the RepA1 protein revealed the existence of two areas of the RepFIC genome that interact with RepA1 in the inhibition reaction. One of these areas, which occurs in the origin region, was explored by in vivo methylation protection footprinting studies. The protected area was 200 bp long and showed a definite periodicity of protected and hypersensitive sites, suggesting that RepA1 promotes a topological change in the RepFIC genome. The significance of our results is discussed in the context of plasmid replication control.

Multicopy single-stranded DNA of Escherichia coli enhances mutation and recombination frequencies by titrating MutS protein.

Multicopy single-stranded DNA (msDNA) molecules consist of single-stranded DNA covalently linked to RNA. In Escherichia coli, such molecules are encoded by genetic elements called retrons. The DNA moieties of msDNAs have characteristic stem-loop structures, and most of these structures contain mismatched base pairs. Previously, we showed that retrons encoding msDNAs with mismatched base pairs are mutagenic when present in multicopy plasmids. In this study we show that such msDNAs, in a similar manner to genetic defects in mismatch repair, increase the frequency of interspecies recombination in matings between Salmonella typhimurium and E. coli. To demonstrate interference with mismatch repair by msDNA, we show that the addition of a plasmid containing the gene for MutS protein suppresses the mutagenic and recombinogenic effects of msDNAs. We also show that in mutS mutants, msDNA does not increase the frequency of either mutations or interspecies recombination. We conclude from these findings that the mutagenic and recombinogenic effects of msDNAs are due to titrating out MutS protein.

Structure of the oligomerization and L-arginine binding domain of the arginine repressor of Escherichia coli.

The structure of the oligomerization and L-arginine binding domain of the Escherichia coli arginine repressor (ArgR) has been determined using X-ray diffraction methods at 2.2 A resolution with bound arginine and at 2.8 A in the unliganded form. The oligomeric core is a 3-fold rotationally symmetric hexamer formed from six identical subunits corresponding to the 77 C-terminal residues (80 to 156) of ArgR. Each subunit has an alpha/beta fold containing a four-stranded antiparallel beta-sheet and two antiparallel alpha-helices. The hexamer is formed from two trimers, each with tightly packed hydrophobic cores. In the absence of arginine, the trimers stack back-to-back through a dyad-symmetric, sparsely packed hydrophobic interface. Six molecules of arginine bind at the trimer-trimer interface, each making ten hydrogen bonds to the protein including a direct ion pair that crosslinks the two protein trimers. Solution experiments with wild-type ArgR and oligomerization domain indicate that the hexameric form is greatly stabilized upon arginine binding. The crystal structures and solution experiments together suggest possible mechanisms of how arginine activates ArgR to bind to its DNA targets and provides a stereochemical basis for interpreting the results of mutagenesis and biochemical experiments with ArgR.

The DNA-binding domain of the hexameric arginine repressor.

The arginine repressor of Escherichia coli is a classical feedback regulator, signalling the availability of L-arginine inside the cell. It differs from most other bacterial repressors in functioning as a hexamer, but structural details have been lacking and its shares no clear sequence homologies with other transcriptional regulators. Analysis of the amino acid residue sequence and proteolytic cleavage pattern of the repressor was used to identify a region predicted to house the DNA-binding function. When this protein fragment is overexpressed from a clone of the corresponding gene fragment, it represses ornithine transcarbamylase levels in vivo, and binds to the operator DNA in vitro, both in an arginine-independent manner. Sedimentation equilibrium and gel filtration indicate that the purified protein fragment is a monomer in solution. The results thus define the domain organization of the repressor at low resolution, suggesting that the N and C-terminal portions of the polypeptide chain are separated by a structural and functional border that decouples hexamerization and arginine binding from DNA binding.

D-serine deaminase is a stringent selective marker in genetic crosses.

The presence of the locus for D-serine deaminase (dsd) renders bacteria resistant to growth inhibition by D-serine and enables them to grow with D-serine as the sole nitrogen source. The two properties permit stringent selection in genetic crosses and make the D-serine deaminase gene an excellent marker, especially in the construction of strains for which the use of antibiotic resistance genes as selective markers is not allowed.

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.

Multicopy single-stranded DNAs with mismatched base pairs are mutagenic in Escherichia coli.

Retrons are genetic elements that encode multicopy single-stranded DNAs called msDNAs. They are clonally distributed in Escherichia coli and retrons in different clones produce DNAs with different nucleotide sequences. msDNAs consist of an RNA molecule covalently linked to a single-stranded DNA molecule. The latter contains an inverted repeat, resulting in a stem-loop structure. In two retrons, Ec83 and Ec78, the DNA is cleaved off from the RNA. All known retrons except Ec78, have one or more mismatched base pairs in the stem-loop structure. We found that two retrons, Ec86 and Ec83, when present in high copy numbers are mutagenic. The ratios of mutation frequencies observed in Lac- indicator strains were similar to the ratios observed for a mutant defective in mismatch repair. It is known that some proteins required for mismatch repair bind to mismatched base pairs prior to carrying out repair. The similarity in the mutation frequency ratios suggested that the mutagenesis caused by msDNAs of retrons Ec86 and Ec83 might be due to sequestration of a mismatch repair protein by msDNA. Strong support for this interpretation was obtained from the finding that the msDNA produced by retron Ec78 is not mutagenic.

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.

Explanation for different types of regulation of arginine biosynthesis in Escherichia coli B and Escherichia coli K12 caused by a difference between their arginine repressors.

In Escherichia coli K12, formation of the enzymes of arginine biosynthesis are controlled by arginine, with complete repression during growth with added arginine, severe repression (about 95%) during growth without added arginine and complete derepression during arginine-limited growth. In E. coli B, the degree of repression is not correlated with arginine concentrations. Under all conditions of growth enzyme formation is repressed, with repression being somewhat less in a medium with arginine than in a medium without arginine. These differences in repressibility between the two strains have been shown previously to be due to the presence of different alleles of argR, the gene for the arginine repressor. Here we have compared the binding of the two repressors to the operator sites of argF (ARG boxes). In DNase I footprinting and gel retardation experiments with argF ARG boxes we have shown that the arginine repressor of E. coli K12 bound to arginine (ArgRK-arg) has a greater affinity than the arginine repressor of E. coli B bound to arginine (ArgRB-arg), whereas free ArgRB (ArgRBf) has a much stronger affinity than free ArgRK (ArgRKf). The stronger binding of ArgRBf can explain the repression seen in E. coli B during arginine-limited growth and indicates that ArgRBf, but not ArgRKf, is able to repress enzyme synthesis under physiological conditions. The weaker repression of E. coli B than of E. coli K12 seen in the presence of arginine can be explained by the lower affinity of ArgRB-arg for operator sites as compared to ArgRK-arg. Another contributing cause for the weaker repression is the reduction of ArgRBf concentration due to autoregulation of the gene for the repressor. Thus the combined effects of repression by ArgRBf, but not ArgRKf, with the weaker repression by ArgRB-arg as compared to ArgRK-arg, convert the arginine dependent regulation in E. coli K12 to arginine independent regulation in E. coli B.

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.

Isolation and properties of the RepA1 protein of the IncFII replicon, RepFIC.

The initiator protein RepA1 of the IncFII replicon RepFIC derived from the enterotoxin plasmid EntP307 has been cloned under the control of the lambda PL promoter. This has enabled us to overproduce this protein and study its properties. Here we show that RepA1 is a soluble basic protein with an experimentally determined molecular weight of 40,000. Deletion analysis indicates that the overproduced protein originates from the open reading frame which we previously designated as coding for RepA1. We have also shown that the replication function of the replicon RepFIC depends on the intact RepA1 coding frame.

Mapping of the msDNA operon in the chromosome of Escherichia coli B.

An msDNA operon, consisting of genes for msDNA and a reverse transcriptase, is present in Escherichia coliB and absent from E. coliK12. We have found that the msDNA operon is located on a DNA fragment, longer than 15kb, that is absent from E. coliK12. Using conjugation, P1 transduction, and nucleic acid hybridization between E. coliB and E. coliK12 strains, we have located the position of the msDNA operon on the E. coliB chromosome at a site that corresponds to minute 19 on the genetic map and to position 900 on the physical map of the E. coliK12 chromosome.

Distribution of msDNAs among serotypes of enteropathogenic Escherichia coli strains.

A genetic element, called a retron, is present in certain Escherichia coli strains. It consists of genes for the production of a covalently linked DNA-RNA compound and a reverse transcriptase. The presence of a retron can be detected by testing for a satellite DNA band by polyacrylamide gel electrophoresis. This DNA band consists of the DNA portion of the DNA-RNA compound and is called msDNA (multicopy single-stranded DNA). In a survey of intestinal E. coli isolates we detected msDNAs in classical enteropathogenic (EPEC) strains and in strains with aggregative adherence to tissue-culture cells (AA), but not in enteroinvasive (EIEC) and enterotoxigenic (ETEC) strains. Among 76 EPEC strains belonging to 14 different serotypes, msDNA was found to be present in 7 serotypes. In total, five different types of msDNA were found, although within each serotype, the msDNAs were the same. These results suggest that different retrons are clonally inherited.

Expression of the cloned gene for enterotoxin STb of Escherichia coli.

This study involved the construction of hybrid plasmids to produce heat-stable enterotoxin type II of Escherichia coli (STb). The translation of the open reading frame for the STb gene estA was demonstrated in several ways. Studies using in vivo labeling with [35S]cysteine demonstrated a radiolabeled protein band on sodium dodecyl sulfate-polyacrylamide gel electrophoresis of the expected molecular weight of 5,000 for toxin STb. Insertion of translational or transcriptional termination signals into the BglII site of the estA gene blocked the expression of estA. The estA gene was cloned into high-expression vector pKC30 downstream from the strong pL promoter. Northern (RNA) blotting assays revealed a 10- to 20-fold increase in mRNA produced by strain C600F(pKC30STb) over other STb-producing strains, compared with little or no increase in enterotoxin activity demonstrated by bioassay. The estA gene, with its own promoter and Shine-Delgarno region and a portion of the sequence for the signal peptide deleted, was also inserted under the control of the tac promoter. Even after induction of the tac promoter by addition of isopropyl-beta-D-thiogalactopyranoside, no biologic enterotoxin activity could be identified. Neutralizing antibodies to STb were produced in rabbits by using either a purified OmpF-STb-beta-galactosidase fusion protein or a 19-amino-acid synthetic STb peptide coupled to keyhole limpet hemocyanin.

Reverse transcriptase in bacteria.

Reverse transcriptase, discovered in 1970 in retroviruses, has until recently been found only in eukaryotic organisms. Recently it was shown to occur in two groups of bacteria: myxobacteria and Escherichia coli. The gene for reverse transcriptase is part of a chromosomal genetic element that codes for the production of a branched DNA-RNA compound. In this compound a single-stranded DNA is connected to RNA at a specific G residue by a 2'-5' phosphodiester linkage. The precursor for the DNA-RNA compound is a folded messenger RNA, in which the specific G residue is the initiation point for reverse transcription. In the final DNA-RNA compound, the portion of the RNA transcribed by reverse transcriptase is eliminated by RNase H. The DNA-RNA compound is present in several hundred copies per cell. Its biological function is unknown at present.

Properties and incompatibility behavior of miniplasmids derived from the bireplicon plasmid pCG86.

Many plasmids belonging to the F incompatibility groups contain more than one basic replicon. The chimeric plasmid pCG86 is an example of such a multireplicon plasmid. The two basic replicons of pCG86, RepFIIA/FIC and RepFIB have been cloned and re-ligated, the copy numbers of the clones have been determined, and the incompatibility behavior of plasmids containing the ligated replicons and the individual replicons has been studied. The bireplicon plasmids are not expected to be incompatible as recipients with monoreplicon RepFIB or RepFIIA/RepFIC plasmids, since when one replicon is challenged by an incoming replicon, the other should be able to handle the plasmid's replication. In our studies, we found that challenge with either monoreplicon plasmid resulted in incompatibility. This incompatibility was increased in bireplicon plasmids in which RepFIB was duplicated. We conclude that in the bireplicon plasmids, challenging the replication control of one replicon by an incompatible plasmid can interfere with the replication originating from the second replicon.

Reverse transcriptase-dependent synthesis of a covalently linked, branched DNA-RNA compound in E. coli B.

We have found a branched DNA-RNA compound in E. coli B, that is similar in its secondary structure, but not its nucleotide sequence, to the previously described branched DNA-RNA compounds in myxobacteria. This compound is not produced in E. coli K12. We have cloned a 3.5 kb chromosomal segment of E. coli B, which, when transferred into E. coli K12, leads to the production of the DNA-RNA compound. We describe the isolation of the DNA-RNA compound, the determination of its nucleotide sequence, and the nucleotide sequence of the genes required for its formation. The sequence contains the coding regions for the DNA component, the RNA component, and an open reading frame encoding a reverse transcriptase. This reverse transcriptase is shown to be required for the formation of the DNA-RNA compound in vivo and in vitro.