Bringing them together: Plasmid pMV158 rolling circle replication and conjugation under an evolutionary perspective
Rolling circle-replicating plasmids constitute a vast family that is particularly abundant in, but not exclusive of, Gram-positive bacteria. These plasmids are constructed as cassettes that harbor genes involved in replication and its control, mobilization, resistance determinants and one or two origins of lagging strand synthesis. Any given plasmid may contain all, some, or just only the replication cassette. We discuss here the family of the promiscuous streptococcal plasmid pMV158, with emphasis on its mobilization functions: the product of the mobM gene, prototype of the MOBV relaxase family, and its cognate origin of transfer, oriT. Amongst the subfamily of MOBV1 plasmids, three groups of oriT sequences, represented by plasmids pMV158, pT181, and p1414 were identified. In the same subfamily, we found four types of single-strand origins, namely ssoA, ssoU, ssoW, and ssoT. We found that plasmids of the rolling-circle Rep_2 family (to which pMV158 belongs) are more frequently found in Lactobacillales than in any other bacterial order, whereas Rep_1 initiators seemed to prefer hosts included in the Bacillales order. In parallel, MOBV1 relaxases associated with Rep_2 initiators tended to cluster separately from those linked to Rep_1 plasmids. The updated inventory of MOBV1 plasmids still contains exclusively mobilizable elements, since no genes associated with conjugative transfer (other than the relaxase) were detected. These plasmids proved to have a great plasticity at using a wide variety of conjugative apparatuses. The promiscuous recognition of non-cognate oriT sequences and the role of replication origins for lagging-strand origin in the host range of these plasmids are also discussed.
Structural basis of a histidine-DNA nicking/joining mechanism for gene transfer and promiscuous spread of antibiotic resistance
Relaxases are metal-dependent nucleases that break and join DNA for the initiation and completion of conjugative bacterial gene transfer. Conjugation is the main process through which antibiotic resistance spreads among bacteria, with multidrug-resistant staphylococci and streptococci infections posing major threats to human health. The MOB V family of relaxases accounts for approximately 85% of all relaxases found in Staphylococcus aureus isolates. Here, we present six structures of the MOB V relaxase MobM from the promiscuous plasmid pMV158 in complex with several origin of transfer DNA fragments. A combined structural, biochemical, and computational approach reveals that MobM follows a previously uncharacterized histidine/metal-dependent DNA processing mechanism, which involves the formation of a covalent phosphoramidate histidine-DNA adduct for cell-to-cell transfer. We discuss how the chemical features of the high-energy phosphorus-nitrogen bond shape the dominant position of MOB V histidine relaxases among small promiscuous plasmids and their preference toward Gram-positive bacteria.histidine relaxase | antibiotic resistance | horizontal gene transfer | X-ray structure | Staphylococcus aureus A cquisition of exogenous genetic material by bacteria is achieved via conjugative DNA transfer of mobile genetic elements, such as plasmids and especially integrative and conjugative elements and integrative and mobilizable elements (1). Such processes of horizontal gene transfer (HGT) are considered a strong driving force in bacterial evolution and in the ability of bacteria to colonize different niches (2). In addition to permitting the rapid evolution of the bacterial pangenome, HGT is involved in the acquisition of genetic traits that may confer selective advantages to the recipient bacteria, including antibiotic resistance (3). This is particularly important when resistance genes encoded by mobile elements are spread explosively among bacteria in hospitals, posing a serious threat to public health systems (www.cdc.gov/drugresistance/threat-report-2013; www. who.int/drugresistance/documents/surveillancereport/en/). Thus, the so-called mobilome (4) participates in the spread of antibiotic resistance, which is expected to cause 10 million casualties annually by 2050, and the consequent huge economic burden (amr-review.org/sites/default/files/Report-52.15.pdf). This has generated a unanimous call for new approaches to deal with infectious diseases caused by pathogenic bacteria (5).A main performer in HGT is the protein relaxase, a topoisomeraselike enzyme that cleaves supercoiled plasmid DNA in a strandand sequence-specific manner and ligates it after cell-to-cell transfer. Relaxases start DNA transfer by conjugation on recognition of their target DNA, the origin of transfer (oriT), on which they mediate generation of a hairpin-loop structure that leaves the dinucleotide to be cleaved (the nic site) in a singlestranded (ss) DNA configuration (Fig. 1B) (6, 7). On the oriT, the relaxase assembles with other proteins p...
The MobM relaxase (494 amino acids) encoded by the promiscuous streptococcal plasmid pMV158 recognizes the plasmid origin of transfer, oriTpMV158, and converts supercoiled pMV158 DNA into relaxed molecules by cleavage of the phosphodiester bond of a specific dinucleotide within the sequence 5'-GTGTG/TT-3' ("/" being the nick site). After cleavage, the protein remains stably bound to the 5´-end of the nick site. Band-shift assays with single-stranded oligonucleotides and sizeexclusion chromatography allowed us to show that MobM was able to generate specific complexes with one of the inverted repeats of the oriTpMV158, presumably extruded as stem-loop structure. A number of tests have been performed to attain a better characterization of the nicking activity of MobM and its linkage with its target DNA. The optimal pH for DNA relaxation was found to be 6.5. Upon nicking, gel retardation assays showed that MobM formed stable complexes with its target DNA. Moreover, MobM bound to relaxed pMV158 molecules were visualized by electron microscopy. The staphylococcal plasmids pUB110 and pE194, and the streptococcal plasmid pDL287 harbour putative oriTs and may encode Mob proteins homologous to MobM. The oriTpUB110, oriTpDL287, and oriTpE194 sequences share 100%, 70%, and 67% (in a 43-nucleotide stretch and allowing a 3-bp gap) identity to oriTpMV158, respectively. Nicking assays using supercoiled DNAs from pUB110, pDL287, and pE194 showed that MobM was able to relax, to a different degree, all plasmid DNAs. Our results suggest that cross-recognition of heterologous oriTs by Mob proteins could play an important role in the plasmid spreading between bacteria.Suggested Reviewers:Opposed Reviewers:Here we present information on the features of the MobM relaxase encoded by the promiscuous plasmid pMV158. The protein binds to oligonucleotides and to supercoiled plasmid DNA containing the origin of transfer. MobM-relaxed pMV158 DNA forms could be visualized by electron microscopy. The MobM protein relaxed supercoiled DNAs from other rolling circle-replicating plasmids which harbor origins of transfer with similarities to the one present in pMV158. Abstract 27The MobM relaxase (494 amino acids) encoded by the promiscuous 28 streptococcal plasmid pMV158 recognizes the plasmid origin of transfer, oriT pMV158 , 29 and converts supercoiled pMV158 DNA into relaxed molecules by cleavage of the 30 phosphodiester bond of a specific dinucleotide within the sequence 5"-GTGTG/TT-3" 31 ("/" being the nick site). After cleavage, the protein remains stably bound to the 5´-32 end of the nick site. Band-shift assays with single-stranded oligonucleotides and size-33 exclusion chromatography allowed us to show that MobM was able to generate 34 specific complexes with one of the inverted repeats of the oriT pMV158 , presumably 35 extruded as stem-loop structure. A number of tests have been performed to attain a 36 better characterization of the nicking activity of MobM and its linkage with its target 37 DNA. The optimal pH for DNA relaxa...
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