Characterization of the F plasmid TraJ protein synthesized in F' and Hfr strains of Escherichia coli K-12

Characterisation of plasmid-mediated rmtB-1 in Enterobacteriaceae clinical isolates from São Paulo, Brazil

OBJECTIVES The emergence of 16S rRNA methyltranferases (16 RMTAses) has jeopardised the clinical use of aminoglycosides. RmtB is one of the most frequently reported in Gram-negatives worldwide. In this study, we aimed to estimate the frequency of 16S RMTAses encoding genes in Enterobacteriaceae isolated in a three-month period from a tertiary Brazilian hospital. METHODS All Gram-negatives classified as resistant to amikacin, gentamicin, and tobramycin by agar screening were selected for analysis. The presence of 16SRMTases encoding genes was verified by polymerase chain reaction (PCR). Antimicrobial susceptible profile was determined by broth microdilution. The genetic relationship among these isolates was accessed by pulsed field gel electrophoresis (PFGE) and multilocus sequence typing (MLST). Selected RmtB-producing isolates were characterised by whole genome sequencing (WGS) analysis. RESULTS Twenty-two of 1,052 (2.1%) Enterobacteriaceae were detected as producers of RmtB-1 [Klebsiella pneumoniae (n = 21) and Proteus mirabilis (n = 1)]. _blaKPC-2 was identified among 20 RmtB-1-producing K. pneumoniae isolates that exhibited an identical PFGE and MLST (ST258) patterns. Two K. pneumoniae isolates, the A64216 (not harboring bla_KPC-2), A64477 (harboring bla_KPC-2) and one P. mirabilis isolate (A64421) were selected for WGS. rmtB-1 and bla_KPC-2 genes were carried by distinct plasmids. While a plasmid belonging to the IncFIIk group harbored rmtB-1 in K. pneumoniae, this gene was carried by a non-typable plasmid in P. mirabilis. In the three analysed plasmids, rmtB-1 was inserted on a transposon, downstream a Tn2. CONCLUSION Our findings suggested that the rmtB-1 was harbored by plasmids distinct from those previously reported in Bolivia and China. It suggests that multiple mobilization events might have occurred in South America.

The FinO repressor of bacterial conjugation contains two RNA binding regions

Conjugative transfer of F-like plasmids in Escherichia coli is repressed by a plasmid-encoded protein, FinO. FinO blocks the translation of TraJ, a positive activator of transcription of genes required for conjugation. FinO binds a traJ antisense RNA, FinP, thereby protecting it from degradation, and catalyzes FinP-traJ mRNA hybridization. Interactions between these two RNAs are predicted to block the traJ ribosomal binding site. In this paper, we use limited proteolysis, circular dichroism spectroscopy, and an electrophoretic mobility shift assay to map the regions within FinO that are required for interactions with RNA. Our results show that FinO is largely helical, binds to its highest affinity binding site within FinP as a monomer, and contains two distinct RNA binding regions, one of which is localized between residues 26 and 61, and a second which is localized between residues 62 and 186.

Regulatory mechanisms in expression of the traY-I operon of sex factor plasmid R100: involvement of traJ and traY gene products

BACKGROUND

The plasmid R100 encodes tra genes essential for conjugal DNA transfer in Escherichia coli. Genetic evidence suggests that the traJ gene encodes a positive regulator for the traY-I operon, which includes almost all the tra genes located downstream of traJ. The molecular mechanism of regulation by TraJ, however, is not yet understood. traY is the most proximal gene in the traY-I operon. TraY promotes DNA transfer by binding to a site, sbyA, near the origin of transfer. TraY is suggested to have another role in regulation of the traY-I operon, since it binds to two other sites, named sbyB and sbyC, located in the region preceding traY-I.

RESULTS

Using a traY-lacZ fusion gene, we showed that the traY-I operon was expressed only in the presence of traJ. The TraJ-dependent expression of traY-I required the E. coli arcA gene, which encodes a host factor required for conjugation. TraJ-dependent transcription occurred from a promoter (named pY) located upstream of traY-I. The isolated TraJ protein was found to bind to a dyad symmetry sequence, named sbj (specific binding site of TraJ), which existed in the intergenic region between traJ and traY-I. We also demonstrated that TraY repressed the TraJ-dependent expression of traY-I at the TraY binding sites, sbyB and sbyC, which overlapped with pY.

CONCLUSIONS

TraJ is a protein which binds to the sbj site in the region upstream of the promoter pY and positively regulates expression of the traY-I operon in the presence of the E. coli arcA gene. Since sbj is located 93bp upstream of pY in the intergenic region between traJ and traY-I, TraJ presumably contacts with a transcription apparatus to promote transcription from pY. TraY, which is known to activate the initiation of conjugal DNA transfer, has a new role in the transcriptional autoregulation of traY-I expression. At levels which are sufficient to initiate conjugal DNA transfer, TraY represses traY-I transcription in the presence of TraJ.

Accumulation of the F plasmid TraJ protein in cpx mutants of Escherichia coli

We report here studies of the cellular control of F plasmid TraJ protein levels, focusing on the effects of chromosomal cpx mutations. The principal conclusion from our results is that the cpx mutations impair accumulation of the TraJ protein, thereby reducing tra gene expression. We measured TraJ activity in vivo by expression of a traY'-'lacZ fusion gene and TraJ protein by immuno-overlay blot. In strains with normal TraJ levels, traY expression and donor-related functions were reduced in cells carrying any of four cpxA mutations. In the strain background used to isolate cpx mutants, these reductions were especially evident in cells grown to high density, when traY expression and donor activity both increased in cpx+ cells. In each of the four cpxA mutants tested, TraJ levels were lower than in the otherwise isogenic cpxA+ strain. In cells grown to high density, the differences ranged from 4-fold in the cpxA6 strain to > 10-fold in the cpxA2, cpxA5, and cpxA9 strains. The cpxA2 mutation had little or no effect on traY expression or on donor-related functions when TraJ was present in excess of its limiting level in F' or Hfr cells or on a mutant traY promoter whose expression in vivo was independent of TraJ.

Levels of chromosomally encoded Umu proteins and requirements for in vivo UmuD cleavage

Most of the inducible mutagenesis observed in Escherichia coli after treatment with many DNA damaging agents is dependent upon the products of the umuD,C operon. RecA-mediated proteolytic processing of UmuD yields a carboxyl-terminal fragment (UmuD') that is active for mutagenesis. Processing of UmuD is therefore a critical step in the fixation of mutations. In this paper we have analyzed the requirements for UmuD processing in vivo. Standard immuno-detection assays, coupled with a sensitive chemiluminescence detection assay, have been utilized to probe levels of chromosomally encoded Umu proteins from whole-cell E. coli extracts. We found that the derepression of additional SOS gene products, other than RecA, was not required for UmuD processing. Moreover, efficient cleavage of UmuD was observed only in the presence of elevated levels of activated RecA, suggesting that efficient processing would occur only under conditions of severe DNA damage. Detection of chromosomally encoded Umu proteins has allowed us, for the first time, to measure directly the cellular steady-state levels of these proteins under various SOS inducing conditions. UmuD was present at approximately 180 copies per uninduced cell and was measured at approximately 2400 copies per cell in strains that lacked a functional repressor. Induced levels of UmuC were approximately 12-fold lower than UmuD with approximately 200 molecules per cell. These levels of cellular UmuC protein suggest that it functions through specific protein-DNA or protein-protein interactions, possibly as a lesion recognition protein or by interacting with DNA polymerase III.

Regulation of the F plasmid traY promoter in Escherichia coli K12 as a function of sequence context

TraJ and SfrA are, respectively, plasmid and host (Escherichia coli)-encoded proteins normally required for F plasmid traY promoter function. Beginning with plasmids in which a traY-lacZ fusion gene, designated phi (traY'-'lacZ)hyb, and lacY are expressed from the F plasmid traY promoter, we isolated mutants in which lac gene expression was SfrA or TraJ-independent. A total of 45 of 50 SfrA-independent isolates obtained after 2-aminopurine mutagenesis proved to have chromosomal mutations, whereas four out of four isolates obtained without mutagenesis had plasmid mutations. All of 17 isolates selected for TraJ-independent expression after mutagenesis had plasmid mutations. By restriction endonuclease digestions, 25 of 26 SfrA-independent and TraJ-independent plasmid mutations were insertions. Four of the former and three of the latter were examined further. By sequence analysis, all seven proved to be IS1 or IS2 insertions defining five insertion sites between base-pairs -49 and -82 with respect to the major traY transcription initiation site. In two cases, the same insertion allele was obtained from the two selection schemes. All three of the mutants selected for TraJ-independent gene expression manifested SfrA-independent expression as well, and levels of beta-galactosidase in different plasmid mutant strains lacking TraJ and SfrA were indistinguishable. By primer extension analysis, transcription initiation sites for traY mRNA synthesis were unaltered by the mutations. Replacing the tra sequence upstream from base-pair -78, without genetic selection, increased beta-galactosidase activity in the absence of TraJ and SfrA greater than tenfold. Activity increased two- to threefold more in a traJ+ sfrA mutant strain, and fivefold more in a traJ+ sfrA+ strain. Activity was unaltered in an sfrA+ strain without TraJ. By primer extension analysis, the traY promoter was utilized under all conditions. The data indicate that regulation of traY promoter activity is strongly dependent on sequence context.

Characterization of the oriT region of the IncFV plasmid pED208

DNA sequence analysis of a 2.2kb EcoRI-HindIII fragment from pED208, the derepressed form of the IncFV plasmid Folac, revealed sequences highly homologous to the oriT region, traM, and traJ genes of other IncF plasmids. The TraM protein was purified and immunoblots of fractionated cells containing pED208 or Folac showed that TraM was predominantly in the cytoplasm. Using DNA retardation assays and the DNase I footprinting technique, the TraM protein was found to bind to three large motifs in the oriT region: (I) an inverted repeat, (II) two direct repeats, and (III) the traM promoter region. These three footprint regions contained a Hinfl-like sequence (GANTC) that appeared 16 times, spaced 11-12 bp (or multiples thereof) apart, suggesting that TraM protein binds in a complex manner over this entire region.

Regulation of the F plasmid traY promoter in Escherichia coli by host and plasmid factors

F plasmid DNA transfer (tra) gene expression in Escherichia coli is regulated by chromosome- and F-encoded gene products. To study the relationship among these regulatory factors, we constructed low-copy plasmids containing a phi(traY'-'lacZ)hyb gene that couples beta-galactosidase and Lac permease synthesis to the F plasmid traY promoter. Wild-type transformants maintained high levels of beta-galactosidase over a broad range of culture densities. Primer extension analysis of tra mRNA from F'lac and phi(traY'-'lacZ)hyb strains indicated very similar, though not identical, transcription initiation sites. Moreover, phi(traY'-'lacZ)hyb gene expression required both TraJ and SfrA, as does tra gene expression in F+ strains. beta-Galactosidase activity was reduced approximately 30-fold in the absence of TraJ, which could be supplied in cis or in trans. In a two-plasmid system in which TraJ was supplied in trans by a lac-traJ operon fusion, phi(traY'-'lacZ)hyb expression was a linear, saturable function of traJ expression. Enzyme activity was reduced approximately tenfold in sfrA mutants. That reduction could not be attributed to an effect on the TraJ level. Several other cellular or environmental variables had only a modest effect on phi(traY'-'lacZ)hyb expression. Hyperexpression was observed at high cell density (twofold) and in anaerobic cultures (1.2- to 1.5-fold). In contrast, expression was reduced twofold in integration host factor mutants.

The single-stranded DNA-binding protein of Escherichia coli

The single-stranded DNA-binding protein (SSB) of Escherichia coli is involved in all aspects of DNA metabolism: replication, repair, and recombination. In solution, the protein exists as a homotetramer of 18,843-kilodalton subunits. As it binds tightly and cooperatively to single-stranded DNA, it has become a prototypic model protein for studying protein-nucleic acid interactions. The sequences of the gene and protein are known, and the functional domains of subunit interaction, DNA binding, and protein-protein interactions have been probed by structure-function analyses of various mutations. The ssb gene has three promoters, one of which is inducible because it lies only two nucleotides from the LexA-binding site of the adjacent uvrA gene. Induction of the SOS response, however, does not lead to significant increases in SSB levels. The binding protein has several functions in DNA replication, including enhancement of helix destabilization by DNA helicases, prevention of reannealing of the single strands and protection from nuclease digestion, organization and stabilization of replication origins, primosome assembly, priming specificity, enhancement of replication fidelity, enhancement of polymerase processivity, and promotion of polymerase binding to the template. E. coli SSB is required for methyl-directed mismatch repair, induction of the SOS response, and recombinational repair. During recombination, SSB interacts with the RecBCD enzyme to find Chi sites, promotes binding of RecA protein, and promotes strand uptake.

The Cpx proteins of Escherichia coli K-12: evidence that cpxA, ecfB, ssd, and eup mutations all identify the same gene

An existing cpxA(Ts) mutant was resistant to amikacin at levels that inhibited completely the growth of a cpxA+ and a cpxA deletion strain and failed to grow as efficiently on exogenous proline. These properties are similar to those of mutants altered in a gene mapped to the cpxA locus and variously designated as ecfB, ssd, and eup. The amikacin resistance phenotype of the cpxA mutant was inseparable by recombination from the cpxA mutant phenotype (inability to grow at 41 degrees C without exogenous isoleucine and valine) and was recessive to the cpxA+ allele of a recombinant plasmid. Using methods that ensured independent mutations in the cpxA region of the chromosome, we isolated six new amikacin-resistant mutants following nitrosoguanidine mutagenesis. Three-factor crosses mapped the mutations to the cpxA locus. When transferred by P1 transduction to a cpxB11 Hfr strain, each of the mutations conferred the Tra- and Ilv- phenotypes characteristic of earlier cpxA mutants. Two of the new mutations led to a significantly impaired ability to utilize exogenous proline, and four led to partial resistance to colicin A. Two of the new cpxA alleles were recessive to the cpxA+ allele, and four were dominant, albeit to different degrees. On the basis of these data, we argue that cpxA, ecfB, eup, and ssd are all the same gene. We discuss the cellular function of the cpxA gene product in that light.

Structure and function of conjugative pili: inducible synthesis of functional F pili by Escherichia coli K-12 containing a lac-tra operon fusion

In vivo and in vitro recombination methods were used to construct the recombinant plasmid pTG801, in which the F-plasmid DNA transfer (tra) genes required for the formation of functional F pili were placed under the lac transcriptional control sequences of pUC19. The 20 kilobases of cloned F DNA includes genes traA through the 5'-terminal part of traG; the plasmid lacks the positive regulatory gene traJ and all of the known tra genes required for the DNA transfer stage of conjugation. pTG801 transformants were sensitive to the donor-specific bacteriophages Q beta and f1, as measured by the formation of infectious centers. They were relatively insensitive to bacteriophage R17, as expected from the absence of traD. In the presence of a lacIq allele, sensitivity of pTG801 transformants to f1 and Q beta depended on the concentration of inducer (isopropyl-beta-D-thiogalactopyranoside [IPTG]). Viewed by electron microscopy, pTG801 transformants elaborated 7- to 10-nm-diameter filaments that could be laterally decorated with RNA bacteriophage particles, consistent with the formation of F pili. In stationary-phase cultures, these filaments formed massive aggregates and could be seen to adhere lengthwise to the cell surface; few pili accumulated in the medium as single filaments.

The cpx proteins of Escherichia coli K12. Structure of the cpxA polypeptide as an inner membrane component

Gene cpxA of Escherichia coli K12 encodes the 52,000 Mr CpxA polypeptide. The complete cpxA nucleotide sequence, reported here, predicted that CpxA contains two extended, hydrophobic segments in its amino-terminal half and could therefore be a membrane protein. Using a lac-cpxA operon fusion plasmid to overproduce CpxA and an immunochemical assay to detect the polypeptide, we show that CpxA fractionated with the bacterial inner membrane during differential and isopycnic sedimentation. Moreover, the protein could be solubilized by extraction of crude membranes with non-ionic detergents but not with KCl or NaOH, indicating that Cpx is an intrinsic membrane component. Analysis of TnphoA insertions in cpxA indicated that the region between the hydrophobic segments of CpxA is periplasmic, whereas the region carboxy-terminal to the second such segment is cytoplasmic. Based on these structural data, we propose that CpxA functions as a trans-membrane sensory protein. The DNA sequence data also indicate that cpxA is the 3' gene of an operon.

The product of the F plasmid transfer operon gene, traF, is a periplasmic protein

The products of clones carrying the F plasmid transfer operon gene, traF, were analyzed. Proteins expressed in maxicells were labeled with [35S]methionine and examined by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and autoradiography. Clones carrying the wild-type traF gene expressed two polypeptide products that were not products of clones containing the traF13 amber mutation. These migrated with apparent molecular weights (Ma) of 27,000 and 25,000. A pulse-chase experiment suggested that the larger product was a precursor of the smaller one. In the presence of ethanol, the Ma-27,000 polypeptide accumulated and the Ma-25,000 product was not expressed. These results indicated that the traF protein undergoes proteolytic processing associated with export. Cell fractionation experiments further indicated that the greatest concentration of the mature (Ma 25,000) TraF protein was located in the periplasm. The DNA sequence of traF and the position of the transition mutation in traF13 DNA were also determined. Sequence analysis suggested that traF would be expressed as a 247-amino-acid, Mr-28,006 polypeptide. The 19 amino acids at the amino terminus of this polypeptide appear to constitute a typical membrane leader peptide, while the remainder of the molecule (Mr 25,942) is predicted to be primarily hydrophilic in character.

Integration host factor and conjugative transfer of the antibiotic resistance plasmid R100

Transfer of plasmid R100-1 was reduced 100-fold in the absence of integration host factor.