Dynamic cellular location of bacterial plasmids

Sporadic clone Escherichia coli ST615 as a vector and reservoir for dissemination of crucial antimicrobial resistance genes

There is scarce information concerning the role of sporadic clones in the dissemination of antimicrobial resistance genes (ARGs) within the nosocomial niche. We confirmed that the clinical Escherichia coli M19736 ST615 strain, one of the first isolates of Latin America that harbors a plasmid with an mcr-1 gene, could receive crucial ARG by transformation and conjugation using as donors critical plasmids that harbor bla CTX-M-15, bla KPC-2, bla NDM-5, bla NDM-1, or aadB genes. Escherichia coli M19736 acquired bla CTX-M-15, bla KPC-2, bla NDM-5, bla NDM-1, and aadB genes, being only blaNDM-1 maintained at 100% on the 10th day of subculture. In addition, when the evolved MDR-E. coli M19736 acquired sequentially bla CTX-M-15 and bla NDM-1 genes, the maintenance pattern of the plasmids changed. In addition, when the evolved XDR-E. coli M19736 acquired in an ulterior step the paadB plasmid, a different pattern of the plasmid's maintenance was found. Interestingly, the evolved E. coli M19736 strains disseminated simultaneously the acquired conjugative plasmids in different combinations though selection was ceftazidime in all cases. Finally, we isolated and characterized the extracellular vesicles (EVs) from the native and evolved XDR-E. coli M19736 strains. Interestingly, EVs from the evolved XDR-E. coli M19736 harbored bla CTX-M-15 though the pDCAG1-CTX-M-15 was previously lost as shown by WGS and experiments, suggesting that EV could be a relevant reservoir of ARG for susceptible bacteria. These results evidenced the genetic plasticity of a sporadic clone of E. coli such as ST615 that could play a relevant transitional link in the clinical dynamics and evolution to multidrug/extensively/pandrug-resistant phenotypes of superbugs within the nosocomial niche by acting simultaneously as a vector and reservoir of multiple ARGs which later could be disseminated.

Free ammonia pretreatment enhances the removal of antibiotic resistance genes in anaerobic sludge digestion

Sludge has been recognized as a reservoir of antibiotic resistance genes (ARGs) in the wastewater treatment plants. Our previous study has demonstrated that free ammonia (FA, i.e., NH₃-N) pretreatment is an effective method for enhancing anaerobic digestion of sludge. However, the effects of FA pretreatment on the removal of ARGs in the anaerobic sludge digestion is still unknown. In this study, several ARGs representing various antibiotic classes and integrase gene (intI1) which is crucial for horizontal transfer of ARGs were chosen. This study demonstrated that combined FA pretreatment (420 mg NH₃-N/L for 24 h, under which the highest anaerobic sludge biodegradability was achieved in our previous study) and anaerobic digestion could enhance the removal of aac(6')-Ib-cr, blaTEM, sul2, tetA, tetB and tetX from sludge by 17-74% compared with anaerobic digestion without FA pretreatment, resulting in a lower ARGs abundance in the anaerobically digested sludge. This is caused by the removal of tested ARGs during FA pretreatment and the reduced abundance of potential microbial hosts of ARGs due to FA pretreatment during anaerobic digestion. The removal of IntI1 was not significantly affected by FA pretreatment and intI1 did not play a large role in the fate of the tested ARGs in this study. This study indicated that FA pretreatment for anaerobic digestion could potentially reduce the spread of ARGs from the sludge to the natural environment during sludge disposal or reuse.

Genetic cargo and bacterial species set the rate of vesicle-mediated horizontal gene transfer

Most bacteria release extracellular vesicles (EVs). Recent studies have found these vesicles are capable of gene delivery, however the consequences of vesicle-mediated transfer on the patterns and rates of gene flow within microbial communities remains unclear. Previous studies have not determined the impact of both the genetic cargo and the donor and recipient species on the rate of vesicle-mediated gene exchange. This report examines the potential for EVs as a mechanism of gene transfer within heterogeneous microbial populations. EVs were harvested from three species of Gram-negative microbes carrying different plasmids. The dynamics of gene transfer into recipient species was measured. This study demonstrates that vesicles enable gene exchange between five species of Gram-negative bacteria, and that the identity of the genetic cargo, donor strain, and recipient strain all influence gene transfer rates. Each species released and acquired vesicles containing genetic material to a variable degree, and the transfer rate did not correlate with the relatedness of the donor and recipient species. The results suggest that EVs may be a general mechanism to exchange non-specialized genetic cargo between bacterial species.

Location and dynamics of an active promoter in Escherichia coli K-12

In the present paper, we report that transcription affects the location of a DNA target in Escherichia coli K-12. A strain whose chromosome had been engineered to encode a lac repressor-GFP (green fluorescent protein) fusion was used as a host for a low copy number plasmid that carries an array of five lac operator sites. Individual cells of this strain exhibited a diffuse fluorescence signal, suggesting that the plasmid is distributed throughout the cell cytoplasm. However, a derivative of this plasmid carrying a cloned constitutive promoter is targeted to a location at the edge of the nucleoid towards the pole of the host cell. We conclude that transcription from the cloned promoter is driving the location of the plasmid and that specific locations in bacterial cells may favour gene expression.

Eclipse period of R1 plasmids during downshift from elevated copy number: Nonrandom selection of copies for replication

The classical Meselson-Stahl density-shift method was used to study replication of pOU71, a runaway-replication derivative of plasmid R1 in Escherichia coli. The miniplasmid maintained the normal low copy number of R1 during steady growth at 30°C, but as growth temperatures were raised above 34°C, the copy number of the plasmid increased to higher levels, and at 42°C, it replicated without control in a runaway replication mode with lethal consequences for the host. The eclipse periods (minimum time between successive replication of the same DNA) of the plasmid shortened with rising copy numbers at increasing growth temperatures (Olsson et al., 2003). In this work, eclipse periods were measured during downshifts in copy number of pOU71 after it had replicated at 39 and 42°C, resulting in 7- and 50-fold higher than normal plasmid copy number per cell, respectively. Eclipse periods for plasmid replication, measured during copy number downshift, suggested that plasmid R1, normally selected randomly for replication, showed a bias such that a newly replicated DNA had a higher probability of replication compared to the bulk of the R1 population. However, even the unexpected nonrandom replication followed the copy number kinetics such that every generation, the plasmids underwent the normal inherited number of replication, n, independent of the actual number of plasmid copies in a newborn cell.

Characterizing cross-talk in vivo avoiding pitfalls and overinterpretation

Cross-talk between noncognate histidine kinases and response regulators has been widely reported in vitro and, in specific mutant backgrounds and conditions, in vivo. However, in most cases there is little evidence supporting a physiological role of cross-talk. Indeed, histidine kinases and response regulators show remarkable specificity for their cognate partners. In vivo studies of cross-talk have the potential to establish mechanisms that control specificity and, if the cross-talk is observable in wild-type strains, may reveal new levels of cross-regulation. However such studies can be complicated by effects of other regulatory circuits and by the inactivation of mechanisms that would otherwise suppress cross-talk. It is thus easy to mis- or overinterpret the significance of such studies. We address potential complications associated with measuring cross-talk and discuss some methods for identifying and unmasking sources of cross-talk in cells using transcriptional reporters and in vivo DNA-binding assays.

Novel toxin-antitoxin system composed of serine protease and AAA-ATPase homologues determines the high level of stability and incompatibility of the tumor-inducing plasmid pTiC58

Stability of plant tumor-inducing (Ti) plasmids differs among strains. A high level of stability prevents basic and applied studies including the development of useful strains. The nopaline type Ti plasmid pTiC58 significantly reduces the transconjugant efficiency for incoming incompatible plasmids relative to the other type, such as octopine-type plasmids. In this study we identified a region that increases the incompatibility and stability of the plasmid. This region was located on a 4.3-kbp segment about 38 kbp downstream of the replication locus, repABC. We named two open reading frames in the segment, ietA and ietS, both of which were essential for the high level of incompatibility and stability. Plasmid stabilization by ietAS was accomplished by a toxin-antitoxin (TA) mechanism, where IetS is the toxin and IetA is the antitoxin. A database search revealed that putative IetA and IetS proteins are highly similar to AAA-ATPases and subtilisin-like serine proteases, respectively. Amino acid substitution experiments in each of the highly conserved characteristic residues, in both putative enzymes, suggested that the protease activity is essential and that ATP binding activity is important for the operation of the TA system. The ietAS-containing repABC plasmids expelled Ti plasmids even in strains which were tolerant to conventional Ti-curing treatments.

Intracellular mobility of plasmid DNA is limited by the ParA family of partitioning systems

The highly conserved ParA family of partitioning systems is responsible for positioning DNA and protein complexes in bacteria. In Escherichia coli, plasmids that rely upon these systems are positioned at mid-cell and are repositioned at the quarter-cell positions after replication. How they remain fixed at these positions throughout the cell cycle is unknown. We use fluorescence recovery after photobleaching and time-lapse microscopy to measure plasmid mobility in living E. coli cells. We find that a minimalized version of plasmid RK2 that lacks its Par system is highly mobile, that the intact RK2 plasmid is relatively immobile, and that the addition of a Par system to the minimalized RK2 plasmid limits its mobility to that of the intact RK2. Mobility is thus the default state, and Par systems are required not only to position plasmids, but also to hold them at these positions. The intervention of Par systems is required continuously throughout the cell cycle to restrict plasmid movement that would, if unrestricted, subvert the segregation process. Our results reveal an important function for Par systems in plasmid DNA segregation that is likely to be conserved in bacteria.

Escherichia coli low-copy-number plasmid R1 centromere parC forms a U-shaped complex with its binding protein ParR

The Escherichia coli low-copy-number plasmid R1 contains a segregation machinery composed of parC, ParR and parM. The R1 centromere-like site parC contains two separate sets of repeats. By atomic force microscopy (AFM) we show here that ParR molecules bind to each of the 5-fold repeated iterons separately with the intervening sequence unbound by ParR. The two ParR protein complexes on parC do not complex with each other. ParR binds with a stoichiometry of about one ParR dimer per each single iteron. The measured DNA fragment lengths agreed with B-form DNA and each of the two parC 5-fold interon DNA stretches adopts a linear path in its complex with ParR. However, the overall parC/ParR complex with both iteron repeats bound by ParR forms an overall U-shaped structure: the DNA folds back on itself nearly completely, including an angle of ∼150°. Analysing linear DNA fragments, we never observed dimerized ParR complexes on one parC DNA molecule (intramolecular) nor a dimerization between ParR complexes bound to two different parC DNA molecules (intermolecular). This bacterial segrosome is compared to other bacterial segregation complexes. We speculate that partition complexes might have a similar overall structural organization and, at least in part, common functional properties.

Transformation of rhizobia with broad-host-range plasmids by using a freeze-thaw method

Several species of rhizobia were successfully transformed with broad-host-range plasmids of different replicons by using a modified freeze-thaw method. A generic binary vector (pPZP211) was maintained in Mesorhizobium loti without selection and stably inherited during nodulation. The method could extend the potential of rhizobia as a vehicle for plant transformation.

Imaging OmpR localization in Escherichia coli

We have used a fusion of GFP to the response regulator OmpR to image the spatial distribution of OmpR in live cells of Escherichia coli. We observed foci of increased OmpR-GFP fluorescence that appear to be due to interactions with the histidine kinase EnvZ. We also observed colocalization of OmpR-GFP with clusters of plasmids carrying OmpR binding sites, which enabled us to develop a simple method for imaging the binding of OmpR to DNA in live cells. We used the peak fluorescence intensity within cells to quantify the extent of OmpR-GFP localization either due to interactions with EnvZ or due to binding DNA. With these assays we compared the effects of osmolarity and procaine, both of which are believed to modulate EnvZ activity. Our results suggest that, at least under our growth conditions, procaine activates EnvZ-OmpR signalling whereas osmolarity has, at best, a weak effect on the EnvZ-OmpR system.

Structures of omega repressors bound to direct and inverted DNA repeats explain modulation of transcription

Repressor omega regulates transcription of genes required for copy number control, accurate segregation and stable maintenance of inc18 plasmids hosted by Gram-positive bacteria. omega belongs to homodimeric ribbon-helix-helix (RHH2) repressors typified by a central, antiparallel beta-sheet for DNA major groove binding. Homodimeric omega2 binds cooperatively to promotors with 7 to 10 consecutive non-palindromic DNA heptad repeats (5'-(A)/(T)ATCAC(A)/(T)-3', symbolized by -->) in palindromic inverted, converging (--><--) or diverging (<---->) orientation and also, unique to omega2 and contrasting other RHH2 repressors, to non-palindromic direct (-->-->) repeats. Here we investigate with crystal structures how omega2 binds specifically to heptads in minimal operators with (-->-->) and (--><--) repeats. Since the pseudo-2-fold axis relating the monomers in omega(2) passes the central C-G base pair of each heptad with approximately 0.3 A downstream offset, the separation between the pseudo-2-fold axes is exactly 7 bp in (-->-->), approximately 0.6 A shorter in (--><--) but would be approximately 0.6 A longer in (<---->). These variations grade interactions between adjacent omega2 and explain modulations in cooperative binding affinity of omega2 to operators with different heptad orientations.

Compartmentalization of prokaryotic DNA replication

It becomes now apparent that prokaryotic DNA replication takes place at specific intracellular locations. Early studies indicated that chromosomal DNA replication, as well as plasmid and viral DNA replication, occurs in close association with the bacterial membrane. Moreover, over the last several years, it has been shown that some replication proteins and specific DNA sequences are localized to particular subcellular regions in bacteria, supporting the existence of replication compartments. Although the mechanisms underlying compartmentalization of prokaryotic DNA replication are largely unknown, the docking of replication factors to large organizing structures may be important for the assembly of active replication complexes. In this article, we review the current state of this subject in two bacterial species, Escherichia coli and Bacillus subtilis, focusing our attention in both chromosomal and extrachromosomal DNA replication. A comparison with eukaryotic systems is also presented.

Centromere parC of plasmid R1 is curved

The centromere sequence parC of Escherichia coli low-copy-number plasmid R1 consists of two sets of 11 bp iterated sequences. Here we analysed the intrinsic sequence-directed curvature of parC by its migration anomaly in polyacrylamide gels. The 159 bp long parC is strongly curved with anomaly values (k-factors) close to 2. The properties of the parC curvature agree with those of other curved DNA sequences. parC contains two regions of 5-fold repeated iterons separated by 39 bp. We modified 4 bp within this intermediate sequence so that we could analyse the two 5-fold repeated regions independently. The analysis shows that the two repeat regions are not independently curved parts of parC but that the overall curvature is a property of the whole fragment. Since the centromere sequence of an E.coli plasmid as well as eukaryotic centromere sequences show DNA curvature, we speculate that curvature might be a general property of centromeres.

Multicopy plasmids affect replisome positioning in Bacillus subtilis

The DNA replication machinery, various regions of the chromosome, and some plasmids occupy characteristic subcellular positions in bacterial cells. We visualized the location of a multicopy plasmid, pHP13, in living cells of Bacillus subtilis using an array of lac operators and LacI-green fluorescent protein (GFP). In the majority of cells, plasmids appeared to be highly mobile and randomly distributed. In a small fraction of cells, there appeared to be clusters of plasmids located predominantly at or near a cell pole. We also monitored the effects of the presence of multicopy plasmids on the position of DNA polymerase using a fusion of a subunit of DNA polymerase to GFP. Many of the plasmid-containing cells had extra foci of the replisome, and these were often found at uncharacteristic locations in the cell. Some of the replisome foci were dynamic and highly mobile, similar to what was observed for the plasmid. In contrast, replisome foci in plasmid-free cells were relatively stationary. Our results indicate that in B. subtilis, plasmid-associated replisomes are recruited to the subcellular position of the plasmid. Extending this notion to the chromosome, we postulated that the subcellular position of the chromosomally associated replisome is established by the subcellular location of oriC at the time of initiation of replication.

RNA dynamics in live Escherichia coli cells

We describe a method for tracking RNA molecules in Escherichia coli that is sensitive to single copies of mRNA, and, using the method, we find that individual molecules can be followed for many hours in living cells. We observe distinct characteristic dynamics of RNA molecules, all consistent with the known life history of RNA in prokaryotes: localized motion consistent with the Brownian motion of an RNA polymer tethered to its template DNA, free diffusion, and a few examples of polymer chain dynamics that appear to be a combination of chain fluctuation and chain elongation attributable to RNA transcription. We also quantify some of the dynamics, such as width of the displacement distribution, diffusion coefficient, chain elongation rate, and distribution of molecule numbers, and compare them with known biophysical parameters of the E. coli system.

Unequal access of chromosomal regions to each other in Salmonella: probing chromosome structure with phage lambda integrase-mediated long-range rearrangements

We have investigated the fluidity of the Salmonella chromosome architecture using the phage lambda site-specific recombination system as a probe. We determined how chromosome position affects the extent of integrase-mediated recombination between pairs of inversely oriented att sites at various loci. We also investigated the accessibility of each chromosomal att site to an extrachromosomal partner carried on a low-copy plasmid. Recombination events were assayed by semi-quantitative polymerase chain reaction of the attP product. The extent of recombination between the chromosome and the plasmid was generally higher than intrachromosomal recombination except for two loci, araA::attL and galT::attL, which gave no detectable recombination with any other locus. Based on 20 intervals, we found that chromosomal locations are not equally accessible to each other. Although multiple factors probably affect accessibility, the most important is the specific combination of the end-points used. Neither the size of the intervals nor the accessibility of individual end-points to extrachromosomal sequences is as important. These results suggest that the chromosome is not completely fluid but rather organized in some way, with barriers that limit the movement of DNA within the cell. The nature of the barriers involved in chromosomal organization remains to be determined.

New shuttle vectors for ectopic insertion of genes into Bacillus subtilis

We have constructed shuttle vectors for integration of genes via double homologous recombination into three ectopic sites on the chromosome of Bacillus subtilis. The sites of integration are the pyrD, gltA, and sacA genes located at 139 degrees, 172 degrees, and 333 degrees, respectively, on the chromosome. Integration of the vectors into the target genes leads to antibiotic resistance as well as different metabolic phenotypes. B. subtilis strains with integrations of the empty vectors were able to sporulate at rates comparable to wild type cells. Similar levels of expression were obtained from constitutive lacZ fusions integrated at the different sites.

Interplay between plasmid partition and postsegregational killing systems

Active partition systems and postsegregational killing (PSK) systems are present together in naturally occurring low-copy-number plasmids. Theory suggests that PSK may act as the ultimate determinant of plasmid retention, whereas the partition system may minimize the growth penalty to the host, resulting in a near-ideal symbiosis when the systems combine. Here, we prove the validity of this principle for a specific case involving the P1par system and the mvp PSK system.

Regulatory proteins with a sense of direction: cell cycle signalling network in Caulobacter

Localization of kinases and other signalling molecules at discrete cellular locations is often an essential component of signal transduction in eukaryotes. Caulobacter crescentus is a small, single-celled bacterium that presumably lacks intracellular organelles. Yet in Caulobacter, the subcellular distribution of several two-component signal transduction proteins involved in the control of polar morphogenesis and cell cycle progression changes from a fairly dispersed distribution to a tight accumulation at one or both poles in a spatial and temporal pattern that is reproduced during each cell cycle. This cell cycle-dependent choreography suggests that similarly to what happens in eukaryotes, protein localization provides a means of modulating signal transduction in bacteria. Recent studies have provided important insights into the biological role and the mechanisms for the differential localization of these bacterial signalling proteins during the Caulobacter cell cycle.

Bacterial mitosis: ParM of plasmid R1 moves plasmid DNA by an actin-like insertional polymerization mechanism

Bacterial DNA segregation takes place in an active and ordered fashion. In the case of Escherichia coli plasmid R1, the partitioning system (par) separates paired plasmid copies and moves them to opposite cell poles. Here we address the mechanism by which the three components of the R1 par system act together to generate the force required for plasmid movement during segregation. ParR protein binds cooperatively to the centromeric parC DNA region, thereby forming a complex that interacts with the filament-forming actin-like ParM protein in an ATP-dependent manner, suggesting that plasmid movement is powered by insertional polymerization of ParM. Consistently, we find that segregating plasmids are positioned at the ends of extending ParM filaments. Thus, the process of R1 plasmid segregation in E. coli appears to be mechanistically analogous to the actin-based motility operating in eukaryotic cells. In addition, we find evidence suggesting that plasmid pairing is required for ParM polymerization.

Stable propagation of 'selfish' genetic elements

Extrachromosomal or chromosomally integrated genetic elements are common among prokaryotic and eukaryotic cells. These elements exhibit a variety of 'selfish' strategies to ensure their replication and propagation during the growth of their host cells. To establish long-term persistence, they have to moderate the degree of selfishness so as not to imperil the fitness of their hosts. Earlier genetic and biochemical studies together with more recent cell biological investigations have revealed details of the partitioning mechanisms employed by low copy bacterial plasmids. At least some bacterial chromosomes also appear to rely on similar mechanisms for their own segregation. The 2 mm plasmid of Saccharomyces cerevisiae and related yeast plasmids provide models for optimized eukaryotic selfish DNA elements. Selfish DNA elements exploit the genetic endowments of their hosts without imposing an undue metabolic burden on them. The partitioning systems of these plasmids appear to make use of a molecular trick by which the plasmids feed into the segregation pathway established for the host chromosomes.