Genetic Drift Suppresses Bacterial Conjugation in Spatially Structured Populations

Conjugation is the primary mechanism of horizontal gene transfer that spreads antibiotic resistance among bacteria. Although conjugation normally occurs in surface-associated growth (e.g., biofilms), it has been traditionally studied in well-mixed liquid cultures lacking spatial structure, which is known to affect many evolutionary and ecological processes. Here we visualize spatial patterns of gene transfer mediated by F plasmid conjugation in a colony of Escherichia coli growing on solid agar, and we develop a quantitative understanding by spatial extension of traditional mass-action models. We found that spatial structure suppresses conjugation in surface-associated growth because strong genetic drift leads to spatial isolation of donor and recipient cells, restricting conjugation to rare boundaries between donor and recipient strains. These results suggest that ecological strategies, such as enforcement of spatial structure and enhancement of genetic drift, could complement molecular strategies in slowing the spread of antibiotic resistance genes.     

Novel recA-Independent Horizontal Gene Transfer in Escherichia coli K-12

In bacteria, mechanisms that incorporate DNA into a genome without strand-transfer proteins such as RecA play a major role in generating novelty by horizontal gene transfer. We describe a new illegitimate recombination event in Escherichia coli K-12: RecA-independent homologous replacements, with very large (megabase-length) donor patches replacing recipient DNA. A previously uncharacterized gene (yjiP) increases the frequency of RecA-independent replacement recombination. To show this, we used conjugal DNA transfer, combining a classical conjugation donor, HfrH, with modern genome engineering methods and whole genome sequencing analysis to enable interrogation of genetic dependence of integration mechanisms and characterization of recombination products. As in classical experiments, genomic DNA transfer begins at a unique position in the donor, entering the recipient via conjugation; antibiotic resistance markers are then used to select recombinant progeny. Different configurations of this system were used to compare known mechanisms for stable DNA incorporation, including homologous recombination, F’-plasmid formation, and genome duplication. A genome island of interest known as the immigration control region was specifically replaced in a minority of recombinants, at a frequency of 3 X 10^-12 CFU/recipient per hour.     

Gene transfer between Salmonella enterica serovar Typhimurium inside epithelial cells

Virulence and antibiotic resistance genes transfer between bacteria by bacterial conjugation. Conjugation also mediates gene transfer from bacteria to eukaryotic organisms, including yeast and human cells. Predicting when and where genes transfer by conjugation could enhance our understanding of the risks involved in the release of genetically modified organisms, including those being developed for use as vaccines. We report here that Salmonella enterica serovar Typhimurium conjugated inside cultured human cells. The DNA transfer from donor to recipient bacteria was proportional to the probability that the two types of bacteria occupied the same cell, which was dependent on viable and invasive bacteria and on plasmid tra genes. Based on the high frequencies of gene transfer between bacteria inside human cells, we suggest that such gene transfers occur in situ. The implications of gene transfer between bacteria inside human cells, particularly in the context of antibiotic resistance, are discussed.     

Plasmid- and strain-specific factors drive variation in ESBL-plasmid spread in vitro and in vivo

Horizontal gene transfer, mediated by conjugative plasmids, is a major driver of the global rise of antibiotic resistance. However, the relative contributions of factors that underlie the spread of plasmids and their roles in conjugation in vivo are unclear. To address this, we investigated the spread of clinical Extended Spectrum Beta-Lactamase (ESBL)-producing plasmids in the absence of antibiotics in vitro and in the mouse intestine. We hypothesised that plasmid properties would be the primary determinants of plasmid spread and that bacterial strain identity would also contribute. We found clinical Escherichia coli strains natively associated with ESBL-plasmids conjugated to three distinct E. coli strains and one Salmonella enterica serovar Typhimurium strain. Final transconjugant frequencies varied across plasmid, donor, and recipient combinations, with qualitative consistency when comparing transfer in vitro and in vivo in mice. In both environments, transconjugant frequencies for these natural strains and plasmids covaried with the presence/absence of transfer genes on ESBL-plasmids and were affected by plasmid incompatibility. By moving ESBL-plasmids out of their native hosts, we showed that donor and recipient strains also modulated transconjugant frequencies. This suggests that plasmid spread in the complex gut environment of animals and humans can be predicted based on in vitro testing and genetic data.Subject terms: Antibiotics, Microbial ecology, Phylogenomics     

Cut and move: protein machinery for DNA processing in bacterial conjugation

Conjugation is a paradigmatic example of horizontal or lateral gene transfer, whereby DNA is translocated between bacterial cells. It provides a route for the rapid acquisition of new genetic information. Increased antibiotic resistance among pathogens is a troubling consequence of this microbial capacity. DNA transfer across cell membranes requires a sophisticated molecular machinery that involves the participation of several proteins in DNA processing and replication, cell recruitment, and the transport of DNA and proteins from donor to recipient cells. Although bacterial conjugation was first reported in the 1940s, only now are we beginning to unravel the molecular mechanisms behind this process. In particular, structural biology is revealing the detailed molecular architecture of several of the pieces involved.     

Conjugal transfer of chromosomal DNA in Mycobacterium smegmatis

The genus Mycobacterium includes the major human pathogens Mycobacterium tuberculosis and Mycobacterium leprae . The development of rational drug treatments for the diseases caused by these and other mycobacteria requires the establishment of basic molecular techniques to determine the genetic basis of pathogenesis and drug resistance. To date, the ability to manipulate and move DNA between mycobacterial strains has relied on the processes of transformation and transduction. Here, we describe a naturally occurring conjugation system present in Mycobacterium smegmatis , which we anticipate will further facilitate the ability to manipulate the mycobacterial genome. Our data rule out transduction and transformation as possible mechanisms of gene transfer in this system and are most consistent with conjugal transfer. We show that recombinants are not the result of cell fusion and that transfer occurs from a distinct donor to a recipient. One of the donor strains is mc²155, a highly transformable derivative that is considered the prototype laboratory strain for mycobacterial genetics; the demonstration that it is conjugative should increase its genetic manipulability dramatically. During conjugation, extensive regions of chromosomal DNA are transferred into the recipient and then integrated into the recipient chromosome by multiple recombination events. We propose that DNA transfer is occurring by a mechanism similar to Hfr conjugation in Escherichia coli .     

The human gut resistome

In recent decades, the emergence and spread of antibiotic resistance among bacterial pathogens has become a major threat to public health. Bacteria can acquire antibiotic resistance genes by the mobilization and transfer of resistance genes from a donor strain. The human gut contains a densely populated microbial ecosystem, termed the gut microbiota, which offers ample opportunities for the horizontal transfer of genetic material, including antibiotic resistance genes. Recent technological advances allow microbiota-wide studies into the diversity and dynamics of the antibiotic resistance genes that are harboured by the gut microbiota (‘the gut resistome’). Genes conferring resistance to antibiotics are ubiquitously present among the gut microbiota of humans and most resistance genes are harboured by strictly anaerobic gut commensals. The horizontal transfer of genetic material, including antibiotic resistance genes, through conjugation and transduction is a frequent event in the gut microbiota, but mostly involves non-pathogenic gut commensals as these dominate the microbiota of healthy individuals. Resistance gene transfer from commensals to gut-dwelling opportunistic pathogens appears to be a relatively rare event but may contribute to the emergence of multi-drug resistant strains, as is illustrated by the vancomycin resistance determinants that are shared by anaerobic gut commensals and the nosocomial pathogen Enterococcus faecium.     

Biofilm growth alters regulation of conjugation by a bacterial pheromone

Conjugation is an important mode of horizontal gene transfer in bacteria, enhancing the spread of antibiotic resistance. In clinical settings, biofilms are likely locations for antibiotic resistance transfer events involving nosocomial pathogens such as Enterococcus faecalis. Here we demonstrate that growth in biofilms alters the induction of conjugation by a sex pheromone in E. faecalis. Mathematical modelling suggested that a higher plasmid copy number in biofilm cells would enhance a switch-like behaviour in the pheromone response of donor cells with a delayed, but increased response to the mating signal. Alterations in plasmid copy number, and a bimodal response to induction of conjugation in populations of plasmid-containing donor cells were both observed in biofilms, consistent with the predictions of the model. The pheromone system may have evolved such that donor cells in biofilms are only induced to transfer when they are in extremely close proximity to potential recipients in the biofilm community. These results may have important implications for development of chemotherapeutic agents to block resistance transfer and treat biofilm-related clinical infections.     

Isolation of the R'his plasmids of Vibrio cholerae

V. cholerae strain VT5104 capable of donor activity in conjugation has been constructed by the genetic technique based on plasmid RP4::Mucts62 integration into V. cholerae chromosome due to plasmid homology with Mucts62 inserted into the chromosome. The gene for histidine synthesis has been mobilized and transferred into the recipient cells from VT5104 donor. The conjugants obtained are able to efficiently transfer his+ gene included into the plasmid structure in conjugation with eltor recipient. Thus, the constructed strain VT5104 generates R' plasmids carrying V. cholerae chromosomal genes.     

螺旋链霉菌遗传操作系统-接合转移体系的建立

背景:螺旋链霉菌(Streptomyces spiramyceticus)为国内螺旋霉素(spiramycin,SPM)的生产菌,但目前工业生产中螺旋链霉菌利用遗传操作进行基因改造还没有成功报道。目的:建立螺旋链霉菌遗传操作系统,利用遗传改造的方法改变SPM的组分比例,降低SPM的分离成本。方法:以大肠杆菌(Escherichia coli ET12567/pUZ8002)为供体,螺旋链霉菌为受体进行接合转移实验,建立螺旋链霉菌接合转移的遗传操作系统,并对影响接合转移效率的培养基种类、抗生素覆盖时间、供受体比例等条件进行优化。结果:螺旋链霉菌不适合利用孢子进行接合转移,利用菌体进行接合转移时ISP4培养基为接合转移的最适培养基,供受体比例为103∶1得到的接合子数量最多,接合转移效率为1.93×10-4,SPM中三种组分百分含量变化显著。结论:实验首次建立了螺旋链霉菌接合转移的方法,利用菌体进行接合转移操作,简化了实验操作过程,并且利用CRISRP/Cas9基因编辑系统成功阻断3-O-酰基转移酶基因,并在该位置导入φC31整合位点att B,为后续螺旋链霉菌的基因改造奠定了基础。     

Conjugational chromosome transfer—Complete or partial? Kinetics of chromosome transfer in bacterial conjugation

A mathematical model is proposed which describes the kinetics of chromosome transfer during conjugation of bacteria Escherichia coli K-12. The kinetics of pairing and the appearance of individual recombinants is expressed quantitatively, and on this basis the quantity of donor genetic material transferred to the recipient cell during crossing is considered. Predictions of the theoretical model are compared with experiments on transfer of radioactive label. This comparison indicates that the whole donor chromosome is transferred during conjugation.     

Evidence for natural horizontal transfer of tetO gene between Campylobacter jejuni strains in chickens

AIMS: The transfer of tetO gene conferring resistance to tetracycline was studied between Campylobacter jejuni strains, in the digestive tract of chickens. METHODS AND RESULTS: In vitro conjugation experiments were first performed in order to select donor/recipient couples for further in vivo assay. Then, chickens were inoculated with a donor/recipient couple of C. jejuni strains displaying spontaneous in vitro tetracycline resistance gene transfer. The donor was a tetracycline-resistant ampicillin-susceptible strain, and the recipient was a tetracycline-susceptible ampicillin-resistant strain. Chicken droppings were streaked on antimicrobial selective media and bi-resistant Campylobacter isolates were further characterized according to their donor or recipient flaA gene RFLP profile. The acquisition of tetracycline-resistance gene by the recipient C. jejuni strain from the donor C. jejuni strain was confirmed by tetO PCR. CONCLUSIONS: The study showed that transfer of tetO gene occurs rapidly and without antimicrobial selection pressure between C. jejuni strains in the digestive tract of chickens. SIGNIFICANCE AND IMPACT OF THE STUDY: The rapid and spontaneous transfer of tetO gene may explain the high prevalence of tetracycline resistance in chicken Campylobacter strains.     

In vivo transfer of pAMβ1 from Lactobacillus reuteri to Enterococcus faecalis

Trials were conducted to determine the in vivo transferability of plasmid-mediated antibiotic resistance between two strains of enteric Gram-positive bacteria. Germfree mice were associated with the donor Lactobacillus reuteri DSM 20016 strain, carrying the broad host range pAMβ1 plasmid, and with the Enterococcus faecalis JH2SS recipient strain.
Analysis of faecal content of associated mice demonstrated that the in vivo transfer of this plasmid did occur and that frequencies of conjugation were affected by the presence of subtherapeutic levels of antibiotic in the diet.     

The peptide pheromone-inducible conjugation system of Enterococcus faecalis plasmid pCF10: cell-cell signalling, gene transfer, complexity and evolution

Expression of a large set of gene products required for conjugative transfer of the antibiotic resistance plasmid pCF10 is controlled by cell-cell communication between plasmid-free recipient cells and plasmid-carrying donor cells using a peptide mating pheromone cCF10. Most of the recent experimental analysis of this system has focused on the molecular events involved in initiation of the pheromone response in the donor cells, and on the mechanisms by which the donor cells control self-induction by endogenously produced pheromone. Recently, studies of the molecular machinery of conjugation encoded by the pheromone-inducible genes have been initiated. In addition, the system may serve as a useful bacterial model for addressing the evolution of biological complexity.     

In vivo transfer of pAM beta 1 from Lactobacillus reuteri to Enterococcus faecalis

Trials were conducted to determine the in vivo transferability of plasmid-mediated antibiotic resistance between two strains of enteric Gram-positive bacteria. Germ-free mice were associated with the donor Lactobacillus reuteri DSM 20016 strain, carrying the broad host range pAM beta 1 plasmid, and with the Enterococcus faecalis JH2SS recipient strain. Analysis of faecal content of associated mice demonstrated that the in vivo transfer of this plasmid did occur and that frequencies of conjugation were affected by the presence of subtherapeutic levels of antibiotic in the diet.     

Carica papaya seed macerate as inhibitor of conjugative R plasmid transfer from Salmonella typhimurium to Escherichia coli in vitro and in the digestive tract of gnotobiotic mice

In this study, the effect of Carica papaya seed macerate on conjugal R plasmid transfer from Salmonella typhimurium to Escherichia coli was investigated in vitro and in the digestive tract of gnotobiotic mice. Twenty-five micrograms per milliliter and 430 mg (administered intragastrically twice a day) of papaya seed macerate concentrations were used during conjugation for in vitro and in vivo assays, respectively. High frequency of conjugation inhibition by macerate was observed for both in vitro and in vivo experiments, independently of bacterial growth and mating conditions. Papaya seed macerate caused a reduction of the transconjugant population ranging from 71% to about 100%. There was no lethal effect of the seed macerate on donor or recipient cells in the concentrations used. Once the mechanisms and magnitude of resistance gene transfer are clearly understood, strategies to reduce or minimize the dissemination of these genes could be relevant. The data here obtained show a clinical potential use of papaya seed macerate on this transfer.     

Heat Shock-Enhanced Conjugation Efficiency in Standard Campylobacter jejuni Strains

Campylobacter jejuni, the leading bacterial cause of human gastroenteritis in the United States, displays significant strain diversity due to horizontal gene transfer. Conjugation is an important horizontal gene transfer mechanism contributing to the evolution of bacterial pathogenesis and antimicrobial resistance. It has been observed that heat shock could increase transformation efficiency in some bacteria. In this study, the effect of heat shock on C. jejuni conjugation efficiency and the underlying mechanisms were examined. With a modified Escherichia coli donor strain, different C. jejuni recipient strains displayed significant variation in conjugation efficiency ranging from 6.2 × 10⁻⁸ to 6.0 × 10⁻³ CFU per recipient cell. Despite reduced viability, heat shock of standard C. jejuni NCTC 11168 and 81-176 strains (e.g., 48 to 54°C for 30 to 60 min) could dramatically enhance C. jejuni conjugation efficiency up to 1,000-fold. The phenotype of the heat shock-enhanced conjugation in C. jejuni recipient cells could be sustained for at least 9 h. Filtered supernatant from the heat shock-treated C. jejuni cells could not enhance conjugation efficiency, which suggests that the enhanced conjugation efficiency is independent of secreted substances. Mutagenesis analysis indicated that the clustered regularly interspaced short palindromic repeats system and the selected restriction-modification systems (Cj0030/Cj0031, Cj0139/Cj0140, Cj0690c, and HsdR) were dispensable for heat shock-enhanced conjugation in C. jejuni. Taking all results together, this study demonstrated a heat shock-enhanced conjugation efficiency in standard C. jejuni strains, leading to an optimized conjugation protocol for molecular manipulation of this organism. The findings from this study also represent a significant step toward elucidation of the molecular mechanism of conjugative gene transfer in C. jejuni.     

Transferable lincosamide-macrolide resistance in Bacteroides.

Inter- and intraspecies transfer of resistance to clindamycin, lincomycin, and erythromycin in the strict anaerobe, Bacteroides, is described. This lincosamide-macrolide resistance was found to be specified by a 27 × 10⁶-dalton plasmid, designated pBF4, originally identified in a clinical Bacteroides fragilis isolate. Transfer of this plasmid to a strain of Bacteroides uniformis was demonstrated to occur by a deoxyribonuclease insensitive process which required cell-to-cell contact. Chloroform sterilized donor cell supernatants or filtrates of donor cells did not mediate resistance transfer. Transfer of the antibiotic resistance and pBF4 plasmid deoxyribonucleic acid (DNA) were always coincident. Drug resistant progeny recovered from such matings were able to transfer the pBF4 plasmid and its associated resistance markers to a suitable B.fragilis recipient strain. Compared to interspecies matings, resistance transfer was 100- to 1000-fold greater between isogenic donor and recipient strains, suggesting the possibility of a host controlled restriction-modification system.     

Hfr mapping of mutations in Bordetella pertussis that define a genetic locus involved in virulence gene regulation.

We report the development of techniques for the genetic mapping of point mutations in the bacterial pathogen Bordetella pertussis. A plasmid vector which is self-transmissible by conjugation and which, by insertion into the B. pertussis chromosome, can mobilize chromosomal sequences during conjugation with a recipient B. pertussis bacterium has been constructed. This vector is used in conjunction with a set of strains containing kanamycin resistance gene insertions at defined physical locations in the B. pertussis genome. In crosses between these donor strains and a mutant recipient strain, transfer of a chromosomal segment flanking the kanamycin resistance gene insertion is selected for, and the percentage of exconjugants which reacquire the wild-type trait is scored. In this way the linkage of the mutant allele to these markers, and thus the approximate chromosomal position of the mutant allele, is determined. We have used this genetic system to map a newly described locus in B. pertussis involved in the regulation of the virulence genes ptx (pertussis toxin) and cya (adenylate cyclase toxin).     

Genetic Analysis of the Role of the Transfer Gene, traN, of the F and R100-1 Plasmids in Mating Pair Stabilization during Conjugation

Mating pair stabilization occurs during conjugative DNA transfer whereby the donor and recipient cells form a tight junction which requires pili as well as TraN and TraG in the donor cell. The role of the outer membrane protein, TraN, during conjugative transfer was examined by introduction of a chloramphenicol resistance cassette into the traN gene on an F plasmid derivative, pOX38, to produce pOX38N1::CAT. pOX38N1::CAT was greatly reduced in its ability to transfer DNA, indicating that TraN plays a greater role in conjugation than previously thought. F and R100-1 traN were capable of complementing pOX38N1::CAT transfer equally well when wild-type recipients were used. F traN, but not R100-1 traN, supported a much lower level of transfer when there was an ompA mutation or lipopolysaccharide (LPS) deficiency in the recipient cell, suggesting receptor specificity. The R100-1 traN gene was sequenced, and the gene product was found to exhibit 82.3% overall similarity with F TraN. The differences were mainly located within a central region of the proteins (amino acids 162 to 333 of F and 162 to 348 of R100-1). Deletion analysis of F traN suggested that this central portion might be responsible for the receptor specificity displayed by TraN. TraN was not responsible for TraT-dependent surface exclusion. Thus, TraN, and not the F pilus, appears to interact with OmpA and LPS moieties during conjugation, resulting in mating pair stabilization, the first step in efficient mobilization of DNA.