Evasion of type I and type II DNA restriction systems by IncI1 plasmid CoIIb-P9 during transfer by bacterial conjugation

Conjugation's Toolkit: the Roles of Nonstructural Proteins in Bacterial Sex

Bacterial conjugation, a form of horizontal gene transfer, relies on a type 4 secretion system (T4SS) and a set of nonstructural genes that are closely linked. These nonstructural genes aid in the mobile lifestyle of conjugative elements but are not part of the T4SS apparatus for conjugative transfer, such as the membrane pore and relaxosome, or the plasmid maintenance and replication machineries. While these nonstructural genes are not essential for conjugation, they assist in core conjugative functions and mitigate the cellular burden on the host. This review compiles and categorizes known functions of nonstructural genes by the stage of conjugation they modulate: dormancy, transfer, and new host establishment. Themes include establishing a commensalistic relationship with the host, manipulating the host for efficient T4SS assembly and function and assisting in conjugative evasion of recipient cell immune functions. These genes, taken in a broad ecological context, play important roles in ensuring proper propagation of the conjugation system in a natural environment.

Delineation of a lactococcal conjugation system reveals a restriction-modification evasion system

Plasmid pUC11B is a 49.3-kb plasmid harboured by the fermented meat isolate Lactococcus lactis subsp. lactis UC11. Among other features, pUC11B encodes a pMRC01-like conjugation system and tetracycline-resistance. In this study, we demonstrate that this plasmid can be conjugated at high frequencies to recipient strains. Mutational analysis of the 22 genes encompassing the presumed pUC11B conjugation cluster revealed the presence of several genes with essential conjugation functions, as well as a gene, trsR, encoding a putative transcriptional repressor of this conjugation cluster. Furthermore, plasmid pUC11B encodes an anti-restriction protein, TrsAR, which facilitates higher conjugation frequencies when pUC11B is transferred into recipient strains containing Type II or Type III RM systems. These findings demonstrate how RM mechanisms can be circumvented when they act as a biological barrier for conjugation events.

Genetic editing of multi-resistance plasmids in Escherichia coli isolated from meat during transfer

Resistance plasmids mediate the rapid spread of antimicrobial resistance, which poses a threat to veterinary and human healthcare. This study addresses the question whether resistance plasmids from Escherichia coli isolated from foodstuffs always transfer unchanged to recipient E. coli cells, or that genetic editing can occur. Strains containing between one and five different plasmids were co-incubated with a standard recipient strain. Plasmids isolated from transconjugant strains were sequenced using short and long read technologies and compared to the original plasmids from the donor strains. After one hour of co-incubation only a single plasmid was transferred from donor to recipient strains. If the donor possessed several plasmids, longer co-incubation resulted in multiple plasmids being transferred. Transferred plasmids showed mutations, mostly in mobile genetic elements, in the conjugative transfer gene pilV and in genes involved in plasmid maintenance. In one transconjugant, a resistance cluster encoding tetracycline resistance was acquired by the IncI1 plasmid from the IncX1 plasmid that was also present in the donor strain, but that was not transferred. A single plasmid transferred twelve times back and forth between E. coli strains resulted in a fully conserved plasmid with no mutations, apart from repetitive rearrangements of pilV from and back to its original conformation in the donor strain. The overall outcome suggests that some genetic mutations and rearrangements can occur during plasmid transfer. The possibility of such mutations should be taken into consideration in epidemiological research aimed at attribution of resistance to specific sources.

Genome Modification in Enterococcus faecalis OG1RF Assessed by Bisulfite Sequencing and Single-Molecule Real-Time Sequencing

Enterococcus faecalis is a Gram-positive bacterium that natively colonizes the human gastrointestinal tract and opportunistically causes life-threatening infections. Multidrug-resistant (MDR) E. faecalis strains have emerged, reducing treatment options for these infections. MDR E. faecalis strains have large genomes containing mobile genetic elements (MGEs) that harbor genes for antibiotic resistance and virulence determinants. Bacteria commonly possess genome defense mechanisms to block MGE acquisition, and we hypothesize that these mechanisms have been compromised in MDR E. faecalis. In restriction-modification (R-M) defense, the bacterial genome is methylated at cytosine (C) or adenine (A) residues by a methyltransferase (MTase), such that nonself DNA can be distinguished from self DNA. A cognate restriction endonuclease digests improperly modified nonself DNA. Little is known about R-M in E. faecalis. Here, we use genome resequencing to identify DNA modifications occurring in the oral isolate OG1RF. OG1RF has one of the smallest E. faecalis genomes sequenced to date and possesses few MGEs. Single-molecule real-time (SMRT) and bisulfite sequencing revealed that OG1RF has global 5-methylcytosine (m5C) methylation at 5'-GCWGC-3' motifs. A type II R-M system confers the m5C modification, and disruption of this system impacts OG1RF electrotransformability and conjugative transfer of an antibiotic resistance plasmid. A second DNA MTase was poorly expressed under laboratory conditions but conferred global N(4)-methylcytosine (m4C) methylation at 5'-CCGG-3' motifs when expressed in Escherichia coli. Based on our results, we conclude that R-M can act as a barrier to MGE acquisition and likely influences antibiotic resistance gene dissemination in the E. faecalis species.

IMPORTANCE

The horizontal transfer of antibiotic resistance genes among bacteria is a critical public health concern. Enterococcus faecalis is an opportunistic pathogen that causes life-threatening infections in humans. Multidrug resistance acquired by horizontal gene transfer limits treatment options for these infections. In this study, we used innovative DNA sequencing methodologies to investigate how a model strain of E. faecalis discriminates its own DNA from foreign DNA, i.e., self versus nonself discrimination. We also assess the role of an E. faecalis genome modification system in modulating conjugative transfer of an antibiotic resistance plasmid. These results are significant because they demonstrate that differential genome modification impacts horizontal gene transfer frequencies in E. faecalis.

The EcoKI type I restriction-modification system in Escherichia coli affects but is not an absolute barrier for conjugation

The rapid evolution of bacteria is crucial to their survival and is caused by exchange, transfer, and uptake of DNA, among other things. Conjugation is one of the main mechanisms by which bacteria share their DNA, and it is thought to be controlled by varied bacterial immune systems. Contradictory results about restriction-modification systems based on phenotypic studies have been presented as reasons for a barrier to conjugation with and other means of uptake of exogenous DNA. In this study, we show that inactivation of the R.EcoKI restriction enzyme in strain Escherichia coli K-12 strain MG1655 increases the conjugational transfer of plasmid pOLA52, which carriers two EcoKI recognition sites. Interestingly, the results were not absolute, and uptake of unmethylated pOLA52 was still observed in the wild-type strain (with an intact hsdR gene) but at a reduction of 85% compared to the uptake of the mutant recipient with a disrupted hsdR gene. This leads to the conclusion that EcoKI restriction-modification affects the uptake of DNA by conjugation but is not a major barrier to plasmid transfer.

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.

Bacterial conjugation-based antimicrobial agents

A clear imperative exists to generate radically different antibacterial technologies that will reduce the usage of conventional chemical antibiotics. Here we trace one route into this new frontier of drug discovery, a concept that we call the bacterial conjugation-based technologies (BCBT). One of the objectives of the BCBT is to exploit plasmid biology for combating the rising tide of antibiotic-resistant bacteria. Specifically, the concept utilizes conjugationally delivered plasmids as antimicrobial agents, and it builds on the accumulated work of many scientists dating back to the discoveries of conjugation and plasmids themselves. Each of the individual components that comprise the approach has been demonstrated to be feasible. We discuss the properties of bacterial plasmids to be employed in BCBT.

Plasmid-encoded antirestriction protein ArdA can discriminate between type I methyltransferase and complete restriction-modification system

Many promiscuous plasmids encode the antirestriction proteins ArdA (alleviation of restriction of DNA) that specifically affect the restriction activity of heterooligomeric type I restriction-modification (R-M) systems in Escherichia coli cells. In addition, a lot of the putative ardA genes encoded by plasmids and bacterial chromosomes are found as a result of sequencing of complete genomic sequences, suggesting that ArdA proteins and type I R-M systems that seem to be widespread among bacteria may be involved in the regulation of gene transfer among bacterial genomes. Here, the mechanism of antirestriction action of ArdA encoded by IncI plasmid ColIb-P9 has been investigated in comparison with that of well-studied T7 phage-encoded antirestriction protein Ocr using the mutational analysis, retardation assay and His-tag affinity chromatography. Like Ocr, ArdA protein was shown to be able to efficiently interact with EcoKI R-M complex and affect its in vivo and in vitro restriction activity by preventing its interaction with specific DNA. However, unlike Ocr, ArdA protein has a low binding affinity to EcoKI Mtase and the additional C-terminal tail region (VF-motif) is needed for ArdA to efficiently interact with the type I R-M enzymes. It seems likely that this ArdA feature is a basis for its ability to discriminate between activities of EcoKI Mtase (modification) and complete R-M system (restriction) which may interact with unmodified DNA in the cells independently. These findings suggest that ArdA may provide a very effective and delicate control for the restriction and modification activities of type I systems and its ability to discriminate against DNA restriction in favour of the specific modification of DNA may give some advantage for efficient transmission of the ardA-encoding promiscuous plasmids among different bacterial populations.

The activity of a single-stranded promoter of plasmid ColIb-P9 depends on its secondary structure

The leading region of the conjugal bacterial plasmid ColIb-P9 contains three dispersed repeats of a 328 bp sequence homologous to Frpo, a sequence from plasmid F that acts as a promoter in single-stranded DNA. One of these sequences, ssi3, inactive in the double-stranded form, promoted in vitro transcription exclusively from the single strand that is transferred during conjugation. Promoter activity was dependent on the presence of RNA polymerase holoenzyme containing sigma 70. Transcription initiated from the position predicted from folding the single-stranded DNA to form a pseudo double-stranded hairpin structure containing recognizable -35 and -10 promoter elements. Footprinting of RNA polymerase holoenzyme on single-stranded ssi3 DNA was consistent with this suggestion. Mutagenesis of the putative -35 region inactivated the promoter, but random mutations in the -10 region had little effect. The putative -10 region is a poor match to the consensus sequence and contains mismatched bases. Elimination of these mismatches invariably destroyed single-strand promoter activity. These observations reveal the crucial contribution of the unpaired bases in the -10 region in potentiating the formation of the productive open complex with RNA polymerase.

Plasmid R16 ArdA protein preferentially targets restriction activity of the type I restriction-modification system EcoKI

The ArdA antirestriction protein of the IncB plasmid R16 selectively inhibited the restriction activity of EcoKI, leaving significant levels of modification activity under conditions in which restriction was almost completely prevented. The results are consistent with the hypothesis that ArdA functions in bacterial conjugation to allow an unmodified plasmid to evade restriction in the recipient bacterium and yet acquire cognate modification.

Type I restriction systems: sophisticated molecular machines (a legacy of Bertani and Weigle)

Restriction enzymes are well known as reagents widely used by molecular biologists for genetic manipulation and analysis, but these reagents represent only one class (type II) of a wider range of enzymes that recognize specific nucleotide sequences in DNA molecules and detect the provenance of the DNA on the basis of specific modifications to their target sequence. Type I restriction and modification (R-M) systems are complex; a single multifunctional enzyme can respond to the modification state of its target sequence with the alternative activities of modification or restriction. In the absence of DNA modification, a type I R-M enzyme behaves like a molecular motor, translocating vast stretches of DNA towards itself before eventually breaking the DNA molecule. These sophisticated enzymes are the focus of this review, which will emphasize those aspects that give insights into more general problems of molecular and microbial biology. Current molecular experiments explore target recognition, intramolecular communication, and enzyme activities, including DNA translocation. Type I R-M systems are notable for their ability to evolve new specificities, even in laboratory cultures. This observation raises the important question of how bacteria protect their chromosomes from destruction by newly acquired restriction specifities. Recent experiments demonstrate proteolytic mechanisms by which cells avoid DNA breakage by a type I R-M system whenever their chromosomal DNA acquires unmodified target sequences. Finally, the review will reflect the present impact of genomic sequences on a field that has previously derived information almost exclusively from the analysis of bacteria commonly studied in the laboratory.

Antirestriction protein Ard (Type C) encoded by IncW plasmid pSa has a high similarity to the "protein transport" domain of TraC1 primase of promiscuous plasmid RP4

The IncW plasmid pSa contains the gene ard encoding an antirestriction function that is specific for type I restriction and modification systems. The nucleotide sequence of ard was determined and an appropriate polypeptide of about 33 kDa was identified in Escherichia coli T7 expression system. Analysis of deduced amino acid sequence of Ard encoded by pSa revealed that this protein has no significant similarities with the known Ard proteins (ArdA and ArdB types) except the "antirestriction" motif (14 amino acid residues in length) conserved for all known Ard proteins. This finding suggests that pSa Ard may be classified as a new type of Ard proteins which we designated ArdC. The remarkable feature of ArdC is that it has a high degree of similarity (about 38 % identity) to the N-terminal region of RP4 TraC1 primase which includes about 300 amino acid residues and seems to be essential for binding to the single-stranded DNA and TraC1 protein transport to the recipient cells during the conjugal transfer of plasmid DNA. ArdC also binds to single-stranded DNA. In addition, this protein is able in vitro to protect the single-stranded but not double-stranded plasmid DNA against the activity of type II restriction endonuclease HhaI that cleaves both single and double-stranded DNA. We suggest that like TraC1, ArdC would be transported as a result of their interaction with the single-stranded DNA of transferred plasmid strand during conjugative passage through the cell envelope to the recipient bacterium. Such properties of ArdC protein might be useful to protect immediately the incoming single-stranded DNA from the host endonucleases.

Expression of leading region genes on IncI1 plasmid ColIb-P9: genetic evidence for single-stranded DNA transcription

The leading region of a plasmid is the first sector to enter the recipient cell in bacterial conjugation. This sector of IncI1 plasmid ColIb-P9 includes genes that are transcribed in a transient pulse early in the conjugatively infected cell to promote establishment of the immigrant plasmid. Evidence is presented that the burst of gene expression is regulated by a process which is independent of a repressor but dependent on the orientation of the genes on the unique plasmid strand transferred in conjugation. The nucleotide sequence of 11.7 kb of the leading region was determined and found to contain 10 ORFs; all are orientated such that the template strand for transcription corresponds to the transferred strand. The leading region contains three dispersed repeats of a sequence homologous to a novel promoter in ssDNA described by H. Masai & K. Arai (1997, Cell 89, 897-907). It is proposed that the repeats are promoters that form in the transferring strand of ColIb to support transient transcription of genes transferred early in conjugation.

Transient transcriptional activation of the Incl1 plasmid anti-restriction gene (ardA) and SOS inhibition gene (psiB) early in conjugating recipient bacteria

The ardA gene of the enterobacterial plasmid CollbP-9 acts to alleviate restriction of DNA by type I systems, while psiB inhibits induction of the bacterial SOS response. Both genes are transferred early in a round of bacterial conjugation as part of the plasmid leading region. We report here that ardA and psiB are transcribed transiently after their conjugative transport into the recipient cell. Transcript levels, monitored by competitive reverse transcription-polymerase chain reaction (RT-PCR) amplification of RNA templates, started to increase about 5 min after the initiation of conjugation in a cell population and probably before the first round of plasmid transfer was completed. Genetic evidence is given that the expression of ardA and psiB is activated when the genes enter the recipient cell on the transferring plasmid strand. It is proposed that these and other leading region genes function to promote the establishment of the immigrant plasmid in the new host and are expressed by transcription from promoters active only in single-stranded DNA.

Organization of the leading region of IncN plasmid pKM101 (R46): a regulation controlled by CUP sequence elements

Analysis of the nucleotide sequence of the 13.8 kb leading region of the IncN plasmid pKM101 (a deletion derivative of R46) revealed eight copies of highly conserved repetitive elements, CUP (Conserved UPstream), and at least nine novel open reading frames (ORFs). Appropriate protein products were identified for eight ORFs and the analysis of their deduced amino acid sequences revealed similarities with some well-known proteins (KorA of RK2/RP4, RecX and PsiB) that may play a role in the adaptation of promiscuous plasmids to the new host. Comparison of CUP elements revealed that the CUP core is 417 nucleotides long and consists of two portions that markedly differ in GC content. The larger portion (307 nucleotides) of the core is about 74% GC and contains at least one NotI site, while the other (110 nucleotides) is only about 40% GC. The remarkable features of CUP elements is that five of them are oriented in the same direction and fused in a similar mode to the open reading frames (ORFs) that are able to encode unrelated proteins. The spacings between the right boundary of the CUP core and the potential ATG start codons of these ORFs are slightly different in length (16 to 18 bp), highly divergent in sequence but in all cases contain the conserved hexamer 5'-AGGAGT-3' at the position that is typical for the ribosome binding site of Escherichia coli. The A+T-rich portion of the CUP sequences contains the strong negatively regulated promoter and appears to function as a genetic switch that coordinately controls the expression of CUP-fused genes during the conjugal transfer. These findings suggest that seven plasmid genes fused to the CUP elements including repA and two ard genes encoding positively acting replication protein and antirestriction proteins, respectively, may be members of one regulatory network based on the CUP elements and two plasmid-encoded regulatory proteins ArdK and ArdR. At least, the ArdK protein may act as a typical repressor by binding to the promoter region of the CUP sequence. Most of the structural and functional features of organization of the CUP-controlled regulatory network are associated with the idea that the CUP elements may be involved in the natural genetic engineering process of organizing various functionally related genes in one regulon.

Reduction of conjugal transfer efficiency by three restriction activities of Anabaena sp. strain PCC 7120

The efficiency of conjugal transfer of plasmids from Escherichia coli to the cyanobacterium Anabaena sp. strain PCC 7120 was quantitated as a function of the number of restriction sites for the restriction enzymes carried by the recipient. In addition to the previously recognized isoschizomers of AvaI and AvaII, PCC 7120 was found to possess an isoschizomer of AvaIII. Plasmids modified in E. coli with methylases that protect in vitro against restriction by the three enzymes were transferred with high efficiency, nearly independent of the number of restriction sites on the plasmid. Plasmids left unprotected against one of the three restriction enzymes were transferred with lower efficiencies. For low numbers of sites, the efficiency of conjugal transfer decreased as an exponential function of the number of unprotected sites. The methods presented may be used to increase the efficiency of conjugal transfer into restriction-competent bacteria.

Identification of a methyl-specific restriction system mediated by a conjugative element from Streptomyces bambergiensis

pBL2 was identified genetically but not physically in Streptomyces lividans after its mating with S. bambergiensis. During conjugation, pBL2 was transferred at high frequency to S. lividans and S. coelicolor. pBL2.1 DNA isolated from S. coelicolor exconjugants as a circular plasmid was shown to derive from the genome of S. bambergiensis. S. lividans carrying pBL2 or pBL2.1 acquired a methyl-specific restriction (MsrA+) phenotype. The corresponding enzyme was partially purified and shown to resemble a class II endonuclease which cleaves Dam-methylated DNA preferentially.

On the regulation and diversity of restriction in Escherichia coli

The effect of UV irradiation on restriction mediated by four endogenous restriction systems of E. coli K-12 was investigated using a uniform testing method. Restriction by all four systems was reduced when treated cells were separately challenged with lambda phage carrying modification patterns that elicit restriction by each system. The response of each system was genetically and physiologically distinct.

A motif conserved among the type I restriction-modification enzymes and antirestriction proteins: a possible basis for mechanism of action of plasmid-encoded antirestriction functions

Antirestriction proteins Ard encoded by some self-transmissible plasmids specifically inhibit restriction by members of all three families of type I restriction-modification (R-M) systems in E.coli. Recently, we have identified the amino acid region, 'antirestriction' domain, that is conserved within different plasmid and phage T7-encoded antirestriction proteins and may be involved in interaction with the type I R-M systems. In this paper we demonstrate that this amino acid sequence shares considerable similarity with a well-known conserved sequence (the Argos repeat) found in the DNA sequence specificity (S) polypeptides of type I systems. We suggest that the presence of these similar motifs in restriction and antirestriction proteins may give a structural basis for their interaction and that the antirestriction action of Ard proteins may be a result of the competition between the 'antirestriction' domains of Ard proteins and the similar conserved domains of the S subunits that are believed to play a role in the subunit assembly of type I R-M systems.

Response to UV damage by four Escherichia coli K-12 restriction systems

To understand the role of restriction in regulating gene flow in bacterial populations, we would like to understand the regulation of restriction enzyme activity. Several antirestriction (restriction alleviation) systems are known that reduce the activity of type I restriction enzymes like EcoKI in vivo. Most of these do not act on type II or type III enzymes, but little information is available for the unclassified modification-dependent systems, of which there are three in E. coli K-12. Of particular interest are two physiological controls on type I enzymes: EcoKI restriction is reduced 2 to 3 orders of magnitude following DNA damage, and a similar effect is seen constitutively in Dam- cells. We used the behavior of EcoKI as a control for testing the response to UV treatment of the three endogenous modification-dependent restriction systems of K-12, McrA, McrBC, and Mrr. Two of these were also tested for response to Dam status. We find that all four resident restriction systems show reduced activity following UV treatment, but not in a unified fashion; each response was genetically and physiologically distinct. Possible mechanisms are discussed.

Structure, expression, and regulation of the kilC operon of promiscuous IncP alpha plasmids

The kil-kor regulon was first identified on the broad-host-range IncP alpha plasmid RK2 by the presence of multiple kil loci (kilA, kilB, kilC, and recently kilE) that are lethal to Escherichia coli host cells in the absence of regulation by kor functions in various combinations. Whereas the kilB operon is required for mating-pair formation during conjugation, the functions encoded by the other kil loci are not known. They are not essential for replication or conjugal transfer, but their coregulation with replication and transfer genes indicates that they are likely to be important for RK2. In this report, we describe molecular and genetic studies on kilC. We determined the nucleotide sequence of the kilC region, which is located between the origin of vegetative replication (oriV) and transposon Tn1 on RK2. Primer extension analysis identified the transcriptional start site and showed that a sequence corresponding to a strong sigma 70 promoter is functional. The abundance of RNA initiated from the kilC promoter is reduced in the presence of korA and korC, as predicted from genetic analysis of kilC regulation. The first gene of the kilC operon (klcA) is sufficient to express the host-lethal phenotype of the kilC determinant in the absence of korA and korC. By comparing RK2 to the related IncP alpha plasmids pUZ8 and R995, we determined that the Tn1 transposon in RK2 interrupts a gene (klcB) immediately downstream of klcA. Thus, the kilC determinant is normally part of an autoregulated operon of three genes: klcA, klcB, and korC. klcA is predicted to encode a 15,856-Da polypeptide that is related to the ArdB antirestriction protein of the IncN plasmid pKM101, suggesting a role for klcA in the broad host ranges of IncP alpha plasmids. The predicted product of the uninterrupted klcB gene is a polypeptide of 51,133 Da that contains a segment with significant similarity to the RK2 regulatory proteins KorA and TrbA. Located 145 bp upstream of the kilC promoter is a 10th copy of the 17-bp oriV iteron sequence in inverted orientation relative to that of the other nine iterons of oriV. Iteron 10 is identical to the "orphan" iteron 1, and both have identical 6-bp flanking sequences that make them likely to be strong binding sites for the TrfA replication initiator protein. The locations and relative orientation of orphan iterons 10 and 1 raise the possibility that these iterons promote the formation of a DNA loop via protein-protein interactions by bound TrfA and lead us to propose that they demarcate the functional origin of replication. This analysis of the kilC region and our previous studies on the other kil loci of RK2 have revealed that the region between oriV and the korABF operon in wild-type IncP alpha plasmids is saturated by the kilC, kilE, and kilA loci arranged in four kor-regulated operons encoding a total of 12 genes.

The accessory genetic elements of bacteria: existence conditions and (co)evolution

The accessory elements of bacteria, transposons, plasmids and phages provide tillable as well as fertile ground for studying the ecology and (co)evolution of parasite and symbiont interactions with their hosts. The recent climate has yielded a bountiful harvest of delicious evolutionary food for thought.

Plasmid pKM101 encodes two nonhomologous antirestriction proteins (ArdA and ArdB) whose expression is controlled by homologous regulatory sequences

The IncN plasmid pKM101 (a derivative of R46) encodes the antirestriction protein ArdB (alleviation of restriction of DNA) in addition to another antirestriction protein, ArdA, described previously. The relevant gene, ardB, was located in the leading region of pKM101, about 7 kb from oriT. The nucleotide sequence of ardB was determined, and an appropriate polypeptide was identified in maxicells of Escherichia coli. Like ArdA, ArdB efficiently inhibits restriction by members of the three known families of type I systems of E. coli and only slightly affects the type II enzyme, EcoRI. However, in contrast to ArdA, ArdB is ineffective against the modification activity of the type I (EcoK) system. Comparison of deduced amino acid sequences of ArdA and ArdB revealed only one small region of similarity (nine residues), suggesting that this region may be somehow involved in the interaction with the type I restriction systems. We also found that the expression of both ardA and ardB genes is controlled jointly by two pKM101-encoded proteins, ArdK and ArdR, with molecular weights of about 15,000 and 20,000, respectively. The finding that the sequences immediately upstream of ardA and ardB share about 94% identity over 218 bp suggests that their expression may be controlled by ArdK and ArdR at the transcriptional level. Deletion studies and promoter probe analysis of these sequences revealed the regions responsible for the action of ArdK and ArdR as regulatory proteins. We propose that both types of antirestriction proteins may play a pivotal role in overcoming the host restriction barrier by self-transmissible broad-host-range plasmids. It seems likely that the ardKR-dependent regulatory system serves in this case as a genetic switch that controls the expression of plasmid-encoded antirestriction functions during mating.

Biology of DNA restriction

Our understanding of the evolution of DNA restriction and modification systems, the control of the expression of the structural genes for the enzymes, and the importance of DNA restriction in the cellular economy has advanced by leaps and bounds in recent years. This review documents these advances for the three major classes of classical restriction and modification systems, describes the discovery of a new class of restriction systems that specifically cut DNA carrying the modification signature of foreign cells, and deals with the mechanisms developed by phages to avoid the restriction systems of their hosts.