Derepression of single-stranded DNA-binding protein genes on plasmids derepressed for conjugation, and complementation of an E. coli ssb- mutation by these genes

Pheromone effect of estradiol regulates the conjugative transfer of pCF10 carrying antibiotic resistance genes

Horizontal gene transfer (HGT) mediated by conjugative plasmids greatly contributes to bacteria evolution and the transmission of antibiotic resistance genes (ARGs). In addition to the selective pressure imposed by extensive antibiotic use, environmental chemical pollutants facilitate the dissemination of antibiotic resistance, consequently posing a serious threat to the ecological environment. Presently, the majority of studies focus on the effects of environmental compounds on R plasmid-mediated conjugation transfer, and pheromone-inducible conjugation has largely been neglected. In this study, we explored the pheromone effect and potential molecular mechanisms of estradiol in promoting the conjugative transfer of pCF10 plasmid in Enterococcus faecalis. Environmentally relevant concentrations of estradiol significantly increased the conjugative transfer of pCF10 with a maximum frequency of 3.2 × 10^-2, up to 3.5-fold change compared to that of control. Exposure to estradiol induced the activation of pheromone signaling cascade by increasing the expression of ccfA. Furthermore, estradiol might directly bind to the pheromone receptor PrgZ and promote pCF10 induction and finally enhance the conjugative transfer of pCF10. These findings cast valuable insights on the roles of estradiol and its homolog in increasing antibiotic resistance and the potential ecological risk.

Real-time visualisation of the intracellular dynamics of conjugative plasmid transfer

Conjugation is a contact-dependent mechanism for the transfer of plasmid DNA between bacterial cells, which contributes to the dissemination of antibiotic resistance. Here, we use live-cell microscopy to visualise the intracellular dynamics of conjugative transfer of F-plasmid in E. coli, in real time. We show that the transfer of plasmid in single-stranded form (ssDNA) and its subsequent conversion into double-stranded DNA (dsDNA) are fast and efficient processes that occur with specific timing and subcellular localisation. Notably, the ssDNA-to-dsDNA conversion determines the timing of plasmid-encoded protein production. The leading region that first enters the recipient cell carries single-stranded promoters that allow the early and transient synthesis of leading proteins immediately upon entry of the ssDNA plasmid. The subsequent conversion into dsDNA turns off leading gene expression, and activates the expression of other plasmid genes under the control of conventional double-stranded promoters. This molecular strategy allows for the timely production of factors sequentially involved in establishing, maintaining and disseminating the plasmid.

Plasmid Transfer by Conjugation in Gram-Negative Bacteria: From the Cellular to the Community Level

Bacterial conjugation, also referred to as bacterial sex, is a major horizontal gene transfer mechanism through which DNA is transferred from a donor to a recipient bacterium by direct contact. Conjugation is universally conserved among bacteria and occurs in a wide range of environments (soil, plant surfaces, water, sewage, biofilms, and host-associated bacterial communities). Within these habitats, conjugation drives the rapid evolution and adaptation of bacterial strains by mediating the propagation of various metabolic properties, including symbiotic lifestyle, virulence, biofilm formation, resistance to heavy metals, and, most importantly, resistance to antibiotics. These properties make conjugation a fundamentally important process, and it is thus the focus of extensive study. Here, we review the key steps of plasmid transfer by conjugation in Gram-negative bacteria, by following the life cycle of the F factor during its transfer from the donor to the recipient cell. We also discuss our current knowledge of the extent and impact of conjugation within an environmentally and clinically relevant bacterial habitat, bacterial biofilms.

Sequence of the R1 plasmid and comparison to F and R100

The R1 antibiotic resistance plasmid, originally discovered in a clinical Salmonella isolate in London, 1963, has served for decades as a key model for understanding conjugative plasmids. Despite its scientific importance, a complete sequence of this plasmid has never been reported. We present the complete genome sequence of R1 along with a brief review of the current knowledge concerning its various genetic systems and a comparison to the F and R100 plasmids. R1 is 97,566 nucleotides long and contains 120 genes. The plasmid consists of a backbone largely similar to that of F and R100, a Tn21-like transposon that is nearly identical to that of R100, and a unique 9-kb sequence that bears some resemblance to sequences found in certain Klebsiella oxytoca strains. These three regions of R1 are separated by copies of the insertion sequence IS1. Overall, the structure of R1 and comparison to F and R100 suggest a fairly stable shared conjugative plasmid backbone into which a variety of mobile elements have inserted to form an "accessory" genome, containing multiple antibiotic resistance genes, transposons, remnants of phage genes, and genes whose functions remain unknown.

Identification of bacterial plasmids based on mobility and plasmid population biology

Plasmids contain a backbone of core genes that remains relatively stable for long evolutionary periods, making sense to speak about plasmid species. The identification and characterization of the core genes of a plasmid species has a special relevance in the study of its epidemiology and modes of transmission. Besides, this knowledge will help to unveil the main routes that genes, for example antibiotic resistance (AbR) genes, use to travel from environmental reservoirs to human pathogens. Global dissemination of multiple antibiotic resistances and virulence traits by plasmids is an increasing threat for the treatment of many bacterial infectious diseases. To follow the dissemination of virulence and AbR genes, we need to identify the causative plasmids and follow their path from reservoirs to pathogens. In this review, we discuss how the existing diversity in plasmid genetic structures gives rise to a large diversity in propagation strategies. We would like to propose that, using an identification methodology based on plasmid mobility types, we can follow the propagation routes of most plasmids in Gammaproteobacteria, as well as their cargo genes, in complex ecosystems. Once the dissemination routes are known, designing antidissemination drugs and testing their efficacy will become feasible. We discuss in this review how the existing diversity in plasmid genetic structures gives rise to a large diversity in propagation strategies. We would like to propose that, by using an identification methodology based on plasmid mobility types, we can follow the propagation routes of most plasmids in ?-proteobacteria, as well as their cargo genes, in complex ecosystems.

Phylogenetic and functional analysis of the bacteriophage P1 single-stranded DNA-binding protein

Bacteriophage P1 encodes a single-stranded DNA-binding protein (SSB-P1), which shows 66% amino acid sequence identity to the SSB protein of the host bacterium Escherichia coli. A phylogenetic analysis indicated that the P1 ssb gene coexists with its E. coli counterpart as an independent unit and does not represent a recent acquisition of the phage. The P1 and E. coli SSB proteins are fully functionally interchangeable. SSB-P1 is nonessential for phage growth in an exponentially growing E. coli host, and it is sufficient to promote bacterial growth in the absence of the E. coli SSB protein. Expression studies showed that the P1 ssb gene is transcribed only, in an rpoS-independent fashion, during stationary-phase growth in E. coli. Mixed infection experiments demonstrated that a wild-type phage has a selective advantage over an ssb-null mutant when exposed to a bacterial host in the stationary phase. These results reconciled the observed evolutionary conservation with the seemingly redundant presence of ssb genes in many bacteriophages and conjugative plasmids.

Identification and characterization of the single-stranded DNA-binding protein of bacteriophage P1

The genome of bacteriophage P1 harbors a gene coding for a 162-amino-acid protein which shows 66% amino acid sequence identity to the Escherichia coli single-stranded DNA-binding protein (SSB). The expression of the P1 gene is tightly regulated by P1 immunity proteins. It is completely repressed during lysogenic growth and only weakly expressed during lytic growth, as assayed by an ssb-P1/lacZ fusion construct. When cloned on an intermediate-copy-number plasmid, the P1 gene is able to suppress the temperature-sensitive defect of an E. coli ssb mutant, indicating that the two proteins are functionally interchangeable. Many bacteriophages and conjugative plasmids do not rely on the SSB protein provided by their host organism but code for their own SSB proteins. However, the close relationship between SSB-P1 and the SSB protein of the P1 host, E. coli, raises questions about the functional significance of the phage protein.

The ultraviolet-sensitizing function of plasmid R391 interferes with a late step of postreplication repair in Escherichia coli

The conjugative plasmid R391 increases the UV radiation sensitivity of wild-type, uvrA, and lexA cells of Escherichia coli, but not recA strains. To investigate the UV-sensitizing function of R391, we examined the effect of R391 on the repair of DNA daughter-strand gaps and on the UV radiation sensitivities of various repair and/or recombination-deficient mutants. The presence of R391 did not significantly inhibit the repair of DNA daughter-strand gaps in uvrB cells. The presence of R391 increased the UV radiation sensitivity of uvrA, uvrA recF, uvrB, uvrB recF, uvrB recB, and uvrB ssb-113 cells to UV irradiation, but did not significantly increase the UV radiation sensitivity of uvrA ruvA and uvrA ruvC strains. Based on these results, we propose that the UV-sensitizing activity of R391 acts by inhibiting or interfering with the ruvABC-mediated postsynapsis step of recombinational repair.

The single-stranded-DNA-binding proteins (SSB) of Proteus mirabilis and Serratia marcescens

The single-stranded-DNA-binding (SSB) proteins from Proteus mirabilis and Serratia marcescens were purified from overproducing Escherichia coli strains, which were devoid of their own ssb gene. The strains harboured an endA insertion mutation and a xonA mutation resulting in the absence of endonuclease I and exonuclease I activities from the preparations. The amino acid sequences of the SSB of all three species are nearly identical in the N-terminal parts of the proteins that contain the DNA-binding domain, but differ in the C-terminal parts. Both proteins have an apparent binding-site size of 65 and 35 nucleotides at high and low salt concentrations, respectively. The association-rate constant for binding to poly(dT) is 3.2 x 10(8) M-1 s-1 for P. mirabilis SSB (PmiSSB) and 3.4 x 10(8) M-1 s-1 for S. marcescens SSB (SmaSSB). These binding parameters are very similar to those of E. coli SSB (EcoSSB). The structural similarity of the proteins is also documented by the finding that they can exchange subunits among each other to form mixed tetramers. The transcriptional regulation of the ssb and uvrA genes from P. mirabilis and S. marcescens in SOS-induced E. coli cells was studied using lacZ fusions. While the uvrA genes were inducible, there was no induction of the ssb genes transcribed divergently from the uvrA genes. Apparently, regions with nucleotide sequence similarity to the E. coli SOS-box preceding the ssb genes of P. mirabilis and S. marcescens had no gross effect on the transcription. Studies on growth of the cells and recovery from ultraviolet damage indicate that the heterologous SSB proteins support DNA replication and recombinational DNA repair of E. coli with the same efficiency as the E. coli SSB protein. Interactions with other E. coli proteins involved in these processes either do not occur, or are not impeded.

The appearance of the UmuD'C protein complex in Escherichia coli switches repair from homologous recombination to SOS mutagenesis

The process of SOS mutagenesis in Escherichia coli requires (i) the replisome enzymes, (ii) RecA protein, and (iii) the formation of the UmuD'C protein complex which appears to help the replisome to resume DNA synthesis across a lesion. We found that the UmuD'C complex is an antagonist of RecA-mediated recombination. Homologous recombination in an Hfr x F- cross decreased as a function of the UmuD'C cell concentration; this effect was challenged by increasing RecA concentration. Recombination of a u.v.-damaged F-lac with the lac gene of an F- recipient was reduced by increasing the UmuD'C concentration while lac mutagenesis increased, showing an inverse relationship between recombination and SOS mutagenesis. We explain our data with the following model. The kinetics of appearance of the UmuD'C complex after DNA damage is slow, reaching a maximum after an hour. Within that period, excision and recombinational repair have had time to occur. When the UmuD'C concentration relative to the number of residual RecA filaments, not resolved by recombinational repair, becomes high enough, UmuD'C proteins provide a processive factor for the replisome to help replication bypass and repel the standing RecA filament. Thus, at a high enough concentration, the UmuD'C complex will switch repair from recombination to SOS mutagenesis.

The replication initiator operon of promiscuous plasmid RK2 encodes a gene that complements an Escherichia coli mutant defective in single-stranded DNA-binding protein

The amino acid sequence of the 13-kDa polypeptide (P116) encoded by the first gene of the trfA operon of IncP plasmid RK2 shows significant similarity to several known single-stranded DNA-binding proteins. We found that unregulated expression of this gene from its natural promoter (trfAp) or induced expression from a strong heterologous promoter (trcp) was sufficient to complement the temperature-sensitive growth phenotype of an Escherichia coli ssb-1 mutant. The RK2 ssb gene is the first example of a plasmid single-stranded DNA-binding protein-encoding gene that is coregulated with replication functions, indicating a possible role in plasmid replication.

PsiB, and anti-SOS protein, is transiently expressed by the F sex factor during its transmission to an Escherichia coli K-12 recipient

PsiB, an anti-SOS protein, shown previously to prevent activation of RecA protein, was purified from the crude extract of PsiB overproducing cells. PsiB is probably a tetrameric protein, whose subunit has a sequence-deduced molecular mass of 15741 daltons. Using an immuno-assay with anti-PsiB antibodies, we have monitored PsiB cell concentrations produced by F and R6-5 plasmids: the latter type produces a detectable level of PsiB protein while the former does not. The discrepancy can be assigned to a Tn10 out-going promoter located upstream of psiB. When we inserted a Tn10 promoter upstream of F psiB, the F PsiB protein concentration reached the level of R6-5 PsiB. We describe here the physiological role that PsiB protein may have in the cell and how it causes an anti-SOS function. We observed that PsiB protein was transiently expressed by a wild-type F sex factor during its transmission to an Escherichia coli K-12 recipient. In an F+ x F- cross, PsiB concentration increased at least 10-fold in F- recipient bacteria after 90 minutes and declined thereafter; the psiB gene may be repressed when F plasmid replicates vegetatively. PsiB protein may be induced zygotically so as to protect F single-stranded DNA transferred upon conjugation. PsiB protein, when overproduced, may interfere with RecA protein at chromosomal single-stranded DNA sites generated by discontinuous DNA replication, thus causing an SOS inhibitory phenotype.

Zygotic induction of plasmid ssb and psiB genes following conjugative transfer of Incl1 plasmid Collb-P9

The Incl1 conjugative plasmid Collb-P9 carries a psiB gene that prevents induction of the SOS response in host bacteria. This locus is located 2.5 kb downstream of the ssb (single-stranded DNA-binding protein) gene in the leading region. This portion of Collb is strikingly similar to part of the leading region of the otherwise distinct F plasmid. Expression of psiB and ssb is increased when the host cell is exposed to an SOS-inducing treatment or the Collb transfer system is derepressed. Moreover, expression of both genes on a derepressed plasmid is strongly enhanced in conjugatively infected recipient cells. Carriage of the psiB gene by Collb is shown to prevent a low level of SOS induction following conjugation. Plasmid ssb and psiB genes may function to promote installation of the replicon in the new cell.

The single-stranded-DNA-binding protein encoded by the Escherichia coli F factor can complement a deletion of the chromosomal ssb gene

Genes encoding single-stranded-DNA-binding proteins (SSBs) are carried by a variety of large self-transmissible plasmids, and it previously has been shown that these plasmid-borne genes can complement conditional lethal alleles of the ssb gene on the Escherichia coli chromosome for cellular viability. We have tested one of the plasmid-borne ssb genes, the ssf gene from the E. coli F factor, for its ability to complement total deletion of the chromosomal ssb gene for viability. We have found that ssf can complement the ssb deletion, but only when it is present on a high-copy-number plasmid. Cells that are totally dependent on the F-factor-encoded SSB for viability manifest growth properties indicative of problems in DNA replication.

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.

Protein transfer into the recipient cell during bacterial conjugation: studies with F and RP4

Transfer of donor cell proteins to the recipient bacterium was examined in F- and RP4-mediated conjugation. Transfer of a 120 kD polypeptide, identified as the larger product of the plasmid DNA primase gene, was readily detected during RP4-promoted conjugation. The protein was transmitted to the cytoplasm of the recipient, presumably complexed to the transferred ssDNA. F DNA was transferred without detectable association with any cytoplasmic tra protein or with the ssDNA-binding protein encoded by the plasmid. However, a 92 kD protein, possibly F TraD product, was transmitted to the membrane fraction of the recipient cell.

The ssb gene of plasmid ColIb-P9

The IncI1 plasmid ColIb-P9 was found to carry a single-stranded DNA-binding (SSB) protein gene (ssb) that maps about 11 kilobase pairs from the origin of transfer in the region transferred early during bacterial conjugation. The cloned gene was able to suppress the UV and temperature sensitivity of an ssb-1 strain of Escherichia coli K-12. The nucleotide sequence of the ColIb ssb gene was determined, giving a predicted molecular weight of 19,110 for the SSB protein. Sequence data show that ColIb ssb is very similar to the ssb gene on plasmid F, which is also known to map in the leader region. High-level expression of ssb on ColIb required derepression of the transfer (tra) genes and the activity of the positive regulatory system controlling these genes, suggesting that the SSB protein contributes to the conjugative processing of DNA. A mutant of ColIbdrd-1 carrying a Tn903-derived insertion in ssb was constructed, but it was unaffected in the ability to generate plasmid transconjugants and it was maintained apparently stably in donor cells both following mating and during vegetative growth. Hence, no biological role of ColIb SSB protein was detected. However, unlike the parental plasmid, such ColIb ssb mutants conferred a marked Psi+ (plasmid-mediated SOS inhibition) phenotype on recA441 and recA730 strains, implying a functional relationship between SSB and Psi proteins.

PsiB polypeptide prevents activation of RecA protein in Escherichia coli

We further characterize a novel plasmid function preventing SOS induction called Psi (Plasmid SOS Inhibition). We show that Psi function is expressed by psiB, a gene located at coordinate 54.9 of plasmid R6-5 and near oriT, the origin of conjugal transfer. Deletions and amber mutations of the psiB gene permitted us to demonstrate that PsiB polypeptide (apparent molecular weight, 12 kDa) is responsible for Psi function. PsiB protein prevents recA730-promoted mutagenesis and intra-chromosomal recombination but not recombination following conjugation. Overproduction of PsiB protein sensitizes the host cell to UV irradiation. We propose that PsiB polypeptide has an anti-SOS action by inhibiting activation of RecA protein, thus preventing the occurrence of LexA-controlled functions.

The F factor of Escherichia coli carries a locus of stable plasmid inheritance stm, similar to the parB locus of plasmid RI

We found that a 1.4 kb fragment of the F factor of Escherichia coli (coordinates 62.8-64.2) considerably increased the stable inheritance of different plasmids which carried it. The fragment has a 589 bp DNA sequence (coordinates 63.3-63.9) with extensive homology to the parB locus of plasmid RI and, probably like the parB region, ensures the presence of plasmids in bacterial populations by killing those cells which have lost the plasmid.

Nucleotide sequence and transcriptional analysis of a third function (Flm) involved in F-plasmid maintenance

The leading region of the conjugative F plasmid encodes for a function, Flm, capable of extending the maintenance of normally unstable plasmids. Nucleotide sequencing and functional studies of flm locus have shown that it consists of at least two genes, flmA and flmB, which are physically and functionally homologous to hok and sok of parB in plasmid R1. The 52-amino acid flmA-coded polypeptide is almost identical to the hok product which has been shown to be a membrane-associated lethal protein [Gerdes et al., EMBO J. 5 (1986) 2023-2029]. Gene flmB codes for a 100 nucleotide, non-translated, complementary RNA which overlaps the 5' leader sequence of the flmA RNA. The flmA RNA also encodes an open reading frame (ORF70) which overlaps the flmA-coding sequence and may be a third gene involved in the Flm function. S1 analysis and functional studies suggest that the antisense flmB RNA binds to the flmA RNA and suppresses the expression of the lethal product, presumably by blocking coupled translation of ORF70 and flmA. Secondary structure analysis predicts that the flmA RNA is extremely stable compared to the regulatory flmB RNA. We suggest that when these RNA species are retained by cells which have lost the F plasmid, the more stable flmA RNA will eventually be translated thus leading to cell death. This phenomenon provides a third mechanism, additional to ParFIA and Ccd functions, to ensure maintenance of the F plasmid in a growing bacterial population.

Effects of various single-stranded-DNA-binding proteins on reactions promoted by RecA protein

To relate the roles of Escherichia coli SSB in recombination in vivo and in vitro, we have studied the mutant proteins SSB-1 and SSB-113, the variant SSBc produced by chymotryptic cleavage, the partially homologous variant F SSB (encoded by the E. coli sex factor), and the protein encoded by gene 32 of bacteriophage T4. All of these, with the exception of SSB-1, augmented both the initial rate of homologous pairing and strand exchange promoted by RecA protein. From these and related observations, we conclude that SSB stimulates the initial formation of joint molecules by nonspecifically promoting the binding of RecA protein to single-stranded DNA; that SSB plays no role in synapsis of the RecA nucleoprotein filament with duplex DNA; that stimulation of strand exchange by SSB is similarly nonspecific; and that all members of the class of proteins represented by SSB, F SSB, and gene 32 protein may play equivalent roles in making single-stranded DNA more accessible to RecA protein.