Mechanism Of Horizontal Gene Transfer Research Articles

Molecular characterization of methicilin-resistant Staphylococcus aureus strain BM85 isolated from a Vietnamese patient with bloodstream infection

Methicillin-resistant Staphylococcus aureus (MRSA) is a threat to global health due to its resistance to β-lactam antibiotics and many other antibiotic classes developed via both intrinsic and acquired mechanisms. In this study, molecular characteristics related to antibiotic resistance of MRSA strain BM85 were investigated by whole-genome sequencing of a sample isolated from a patient with bloodstream infection at Bach Mai Hospital, Vietnam. Antibiotic susceptibility testing was also performed to determine the correlation between the presence of antibiotic-resistant genes and resistance phenotypes. Genomic analyses showed that the MRSA strain BM85 belonged to the major community-acquired (CA)-MRSA lineage ST59 originating from Taiwan. The strain harbored Staphylococcal Cassette Chromosome mec (SCCmec) type Vb (5C2&5) and Panton-Valentine leukocidin (PVL). Additionally, MRSA strain BM85 also possessed various antibiotic-resistant genes including tet38, tetK, blaZ, mecA, aph(3')-IIIa, aacA-aphD, and ermB which were located on mobile genetic elements MESPM1, Tn553-Tn4001 transposon, and a plasmid carrying the tetK gene, which was responsible for tetracycline resistance. The genotypic-resistant results were concordant with the phenotypic-resistant profile in which MRSA strain BM85 was resistant to penicillin, cefoxitin, gentamicin, kanamycin, tobramycin, erythromycin, and tetracycline. The sequencing data for the MRSA strain BM85 was deposited in GenBank, NCBI under accession number: BioProject PRJNA857185. In conclusion, the acquisition of the foreign genetic elements associated with antibiotic resistances through horizontal gene transfer mechanisms was the key driver of multidrug resistance in the multidrug-resistant MRSA strain BM85.

Inhibition of Plasmid Conjugation in Escherichia coli by Targeting rbsB Gene Using CRISPRi System.

Bacterial conjugation constitutes a major horizontal gene transfer mechanism for the dissemination of antibiotic-resistant genes (ARGs) among human pathogens. The spread of ARGs can be halted or diminished by interfering with the conjugation process. In this study, we explored the possibility of using an rbsB gene as a single target to inhibit plasmid-mediated horizontal gene transfer in Escherichia coli by CRISPR interference (CRISPRi) system. Three single-guide RNAs (sgRNAs) were designed to target the rbsB gene. The transcriptional levels of the rbsB gene, the conjugation-related genes, and the conjugation efficiency in the CRISPRi strain were tested. We further explored the effect of the repressed expression of the rbsB gene on the quorum sensing (QS) system and biofilm formation. The results showed that the constructed CRISPRi system was effective in repressing the transcriptional level of the rbsB gene at a rate of 66.4%. The repressed expression of the rbsB gene resulted in the reduced conjugation rate of RP4 plasmid by 88.7%, which significantly inhibited the expression of the conjugation-related genes (trbBp, trfAp, traF and traJ) and increased the global regulator genes (korA, korB and trbA). The repressed rbsB gene expression reduced the depletion of autoinducer 2 signals (AI-2) by 12.8% and biofilm formation by a rate of 68.2%. The results of this study indicated the rbsB gene could be used as a universal target for the inhibition of conjugation. The constructed conjugative CRISPRi system has the potential to be used in ARG high-risk areas.

Detecting patterns of accessory genome coevolution in Staphylococcus aureus using data from thousands of genomes

Bacterial genomes exhibit widespread horizontal gene transfer, resulting in highly variable genome content that complicates the inference of genetic interactions. In this study, we develop a method for detecting coevolving genes from large datasets of bacterial genomes based on pairwise comparisons of closely related individuals, analogous to a pedigree study in eukaryotic populations. We apply our method to pairs of genes from the Staphylococcus aureus accessory genome of over 75,000 annotated gene families using a database of over 40,000 whole genomes. We find many pairs of genes that appear to be gained or lost in a coordinated manner, as well as pairs where the gain of one gene is associated with the loss of the other. These pairs form networks of rapidly coevolving genes, primarily consisting of genes involved in virulence, mechanisms of horizontal gene transfer, and antibiotic resistance, particularly the SCCmec complex. While we focus on gene gain and loss, our method can also detect genes that tend to acquire substitutions in tandem, or genotype-phenotype or phenotype-phenotype coevolution. Finally, we present the R package DeCoTUR that allows for the computation of our method.

The complex regulation of competence in Staphylococcus aureus under microaerobic conditions

To perform natural transformation, one of the three main Horizontal Gene Transfer mechanisms, bacteria need to enter a physiological differentiated state called genetic competence. Interestingly, new bacteria displaying such aptitude are often discovered, and one of the latest is the human pathogen Staphylococcus aureus.Here, we show an optimized protocol, based on planktonic cells cultures, leading to a large percentage of the population activating the development of competence and a significant improvement of S. aureus natural transformation efficiencies. Taking advantage of these conditions, we perform transcriptomics analyses to characterize the regulon of each central competence regulator. SigH and ComK1 are both found essential for activating natural transformation genes but also important for activation or repression of peripheral functions. Even though ComK2 is not found important for the control of transformation genes, its regulon shows an important overlap with that of SigH and ComK1. Finally, we propose that microaerobic conditions, sensed by the SrrAB two-component system, are key to activate competence in S. aureus.

Catch me if you can: capturing microbial community transformation by extracellular DNA using Hi-C sequencing

The transformation of environmental microorganisms by extracellular DNA is an overlooked mechanism of horizontal gene transfer and evolution. It initiates the acquisition of exogenous genes and propagates antimicrobial resistance alongside vertical and conjugative transfers. We combined mixed-culture biotechnology and Hi-C sequencing to elucidate the transformation of wastewater microorganisms with a synthetic plasmid encoding GFP and kanamycin resistance genes, in the mixed culture of chemostats exposed to kanamycin at concentrations representing wastewater, gut and polluted environments (0.01–2.5–50–100 mg L−1). We found that the phylogenetically distant Gram-negative Runella (102 Hi-C links), Bosea (35), Gemmobacter (33) and Zoogloea (24) spp., and Gram-positive Microbacterium sp. (90) were transformed by the foreign plasmid, under high antibiotic exposure (50 mg L−1). In addition, the antibiotic pressure shifted the origin of aminoglycoside resistance genes from genomic DNA to mobile genetic elements on plasmids accumulating in microorganisms. These results reveal the power of Hi-C sequencing to catch and surveil the transfer of xenogenetic elements inside microbiomes.

Guidelines for the estimation and reporting of plasmid conjugation rates

Conjugation is a central characteristic of plasmid biology and an important mechanism of horizontal gene transfer in bacteria. However, there is little consensus on how to accurately estimate and report plasmid conjugation rates, in part due to the wide range of available methods. Given the similarity between approaches, we propose general reporting guidelines for plasmid conjugation experiments. These constitute best practices based on recent literature about plasmid conjugation and methods to measure conjugation rates. In addition to the general guidelines, we discuss common theoretical assumptions underlying existing methods to estimate conjugation rates and provide recommendations on how to avoid violating these assumptions. We hope this will aid the implementation and evaluation of conjugation rate measurements, and initiate a broader discussion regarding the practice of quantifying plasmid conjugation rates.

THE PREFERENCE PRIORITY OF Bacillus subtilis IN UPTAKING FREE DNA DURING THE NATURAL TRANSFORMATION

Although genetic material is vertically transferred between generations via sexual or asexual reproduction, similarities in some chromosome and gene parts of unrelated organisms provide important clues for another way of transfer. The mobility of genetic information among different organisms, known as horizontal gene transfer (HGT) has immediate or delayed effects on the recipient host. One of the most notable mechanisms of HGT is natural transformation (NT), a process in which cells take free DNA from the extracellular environment and incorporate it into their chromosomes by homologous recombination. NT is widely conserved in many bacterial species as it can promote to spread of resistance genes. Although it is known that many organisms rely on HGT, there is limited information about how they decide which particular genetic material to horizontally transfer. Here, I have investigated the preference priority among different gene sources presented under certain stress conditions for Bacillus subtilis possessing NT ability. To test this, two DNA specimens (E and C) with different sequence contents of the same length were presented to B. subtilis under different stress environments (BK, BC, BE and BCE). The hypothesis was evaluated according to the analysis of the results of colonial formations on selective plates (pE, pC and pCE). The obtained data presented a strong positive correlation that the bacteria have preference priority during NT depending on a stimulator. The tendency of the bacteria to uptake useful DNA fragments in a specific environment can be suggested. For instance, the majority of colonies grow on pE plates rather than the pC and pCE when the transformation media includes erythromycin (Eryt) as an inducer. Although the data significantly overlaps with the idea claiming that the bacteria have a preference priority to uptake free DNAs during NT, further investigations are needed to support the present data and for better understanding of the phenomenon.

Metagenomic profiling of antibiotic resistance genes in Red Sea brine pools.

Antibiotic resistance (AR) is an alarming global health concern, causing an annual death rate of more than 35,000 deaths in the US. AR is a natural phenomenon, reported in several pristine environments. In this study, we report AR in pristine Red Sea deep brine pools. Antimicrobial resistance genes (ARGs) were detected for several drug classes with tetracycline and macrolide resistance being the most abundant. As expected, ARGs abundance increased in accordance with the level of human impact with pristine Red Sea samples having the lowest mean ARG level followed by estuary samples, while activated sludge samples showed a significantly higher ARG level. ARG hierarchical clustering grouped drug classes for which resistance was detected in Atlantis II Deep brine pool independent of the rest of the samples. ARG abundance was significantly lower in the Discovery Deep brine pool. A correlation between integrons and ARGs abundance in brine pristine samples could be detected, while insertion sequences and plasmids showed a correlation with ARGs abundance in human-impacted samples not seen in brine pristine samples. This suggests different roles of distinct mobile genetic elements (MGEs) in ARG distribution in pristine versus human-impacted sites. Additionally, we showed the presence of mobile antibiotic resistance genes in the Atlantis II brine pool as evidenced by the co-existence of integrases and plasmid replication proteins on the same contigs harboring predicted multidrug-resistant efflux pumps. This study addresses the role of non-pathogenic environmental bacteria as a silent reservoir for ARGs, and the possible horizontal gene transfer mechanism mediating ARG acquisition.

The Effect of Outer Space and Other Environmental Cues on Bacterial Conjugation.

Bacterial conjugation is one of the most abundant horizontal gene transfer (HGT) mechanisms, playing a fundamental role in prokaryote evolution. A better understanding of bacterial conjugation and its cross talk with the environment is needed for a more complete understanding of HGT mechanisms and to fight the dissemination of malicious genes between bacteria. Here, we studied the effect of outer space, microgravity, and additional key environmental cues on transfer (tra) gene expression and conjugation efficiency, using the under studied broad-host range plasmid pN3, as a model. High resolution scanning electron microscopy revealed the morphology of the pN3 conjugative pili and mating pair formation during conjugation. Using a nanosatellite carrying a miniaturized lab, we studied pN3 conjugation in outer space, and used qRT-PCR, Western blotting and mating assays to determine the effect of ground physicochemical parameters on tra gene expression and conjugation. We showed for the first time that bacterial conjugation can occur in outer space and on the ground, under microgravity-simulated conditions. Furthermore, we demonstrated that microgravity, liquid media, elevated temperature, nutrient depletion, high osmolarity and low oxygen significantly reduce pN3 conjugation. Interestingly, under some of these conditions we observed an inverse correlation between tra gene transcription and conjugation frequency and found that induction of at least traK and traL can negatively affect pN3 conjugation frequency in a dose-dependent manner. Collectively, these results uncover pN3 regulation by various environmental cues and highlight the diversity of conjugation systems and the different ways in which they may be regulated in response to abiotic signals. IMPORTANCE Bacterial conjugation is a highly ubiquitous and promiscuous process, by which a donor bacterium transfers a large portion of genetic material to a recipient cell. This mechanism of horizontal gene transfer plays an important role in bacterial evolution and in the ability of bacteria to acquire resistance to antimicrobial drugs and disinfectants. Bacterial conjugation is a complex and energy-consuming process, that is tightly regulated and largely affected by various environmental signals sensed by the bacterial cell. Comprehensive knowledge about bacterial conjugation and the ways it is affected by environmental cues is required to better understand bacterial ecology and evolution and to find new effective ways to counteract the threating dissemination of antibiotic resistance genes between bacterial populations. Moreover, characterizing this process under stress or suboptimal growth conditions such as elevated temperatures, high salinity or in the outer space, may provide insights relevant to future habitat environmental conditions.

Biocontainment Techniques and Applications for Yeast Biotechnology

Biocontainment techniques for genetically modified yeasts (GMYs) are pivotal due to the importance of these organisms for biotechnological processes and also due to the design of new yeast strains by using synthetic biology tools and technologies. Due to the large genetic modifications that many yeast strains display, it is highly desirable to avoid the leakage of GMY cells into natural environments and, consequently, the spread of synthetic genes and circuits by horizontal or vertical gene transfer mechanisms within the microorganisms. Moreover, it is also desirable to avoid patented yeast gene technologies spreading outside the production facility. In this review, the different biocontainment technologies currently available for GMYs were evaluated. Interestingly, uniplex-type biocontainment approaches (UTBAs), which rely on nutrient auxotrophies induced by gene mutation or deletion or the expression of the simple kill switches apparatus, are still the major biocontainment approaches in use with GMY. While bacteria such as Escherichia coli account for advanced biocontainment technologies based on synthetic biology and multiplex-type biocontainment approaches (MTBAs), GMYs are distant from this scenario due to many reasons. Thus, a comparison of different UTBAs and MTBAs applied for GMY and genetically engineered microorganisms (GEMs) was made, indicating the major advances of biocontainment techniques for GMYs.

Cell-to-cell natural transformation in Bacillus subtilis facilitates large scale of genomic exchanges and the transfer of long continuous DNA regions.

Natural transformation is one of the major mechanisms of horizontal gene transfer. Although it is usually studied using purified DNA in the laboratory, recent studies showed that many naturally competent bacteria acquired exogenous DNA from neighboring donor cells. Our previous work indicates that cell-to-cell natural transformation (CTCNT) using two different Bacillus subtilis strains is a highly efficient process; however, the mechanism is unclear. In this study, we further characterized CTCNT and mapped the transferred DNA in the recombinants using whole genome sequencing. We found that a recombinant strain generated by CTCNT received up to 66 transferred DNA segments; the average length of acquired continuous DNA stretches was approximately 27 kbwith a maximum length of 347 kb. Moreover, up to 1.54 Mb genomic DNA (37% of the chromosome) was transferred from the donors into one recipient cell. These results suggest that B. subtilis CTCNT facilitates horizontal gene transfer by increasing the transfer of DNA segments and fostering the exchange of large continuous genomic regions. This indicates that the potency of bacterial natural transformation is underestimated using traditional approaches and reveals that DNA donor cells may play an important role in the transformation process in natural environments.

In the interkingdom horizontal gene transfer, the small rolA gene is a big mystery.

The biological function of the agrobacterial oncogene rolA is very poorly understood compared to other components of the mechanism of horizontal gene transfer during agrobacterial colonization of plants. Research groups around the world have worked on this problem, and available information is reviewed in this review, but other rol oncogenes have been studied much more thoroughly. Having one unexplored element makes it impossible to form a complete picture. However, the limited data suggest that the rolA oncogene and its regulatory apparatus have great potential in plant biotechnology and genetic engineering. Here, we collect and discuss available experimental data about the function and structure of rolA. There is still no clear understanding of the mechanism of RolA and its structure and localization. We believe this is because of the nucleotide structure of a frameshift in the most well-studied rolA gene of the agropine type pRi. In fact, interest in the genes of agrobacteria as natural tools for the phenotypic or biochemical engineering of plants increased. We believe that a detailed understanding of the molecular mechanisms will be forthcoming. KEY POINTS: • Among pRi T-DNA oncogenes, rolA is the least understood in spite of many studies. • Frameshift may be the reason for the failure to elucidate the role of agropine rolA. • Understanding of rolA is promising for the phenotypic and biochemical engineering of plants.

Collection of Annotated Acinetobacter Genome Sequences.

The genus Acinetobacter contains environmental species as well as opportunistic pathogens of humans. Several species are competent for natural transformation, an important mechanism of horizontal gene transfer. Here, we present the genome sequences of 19 Acinetobacter strains used in past and upcoming studies of natural transformation.

The RecA-directed recombination pathway of natural transformation initiates at chromosomal replication forks in the pneumococcus

Homologous recombination (HR) is a crucial mechanism of DNA strand exchange that promotes genetic repair and diversity in all kingdoms of life. Bacterial HR is driven by the universal recombinase RecA, assisted in the early steps by dedicated mediators that promote its polymerization on single-stranded DNA (ssDNA). In bacteria, natural transformation is a prominent HR-driven mechanism of horizontal gene transfer specifically dependent on the conserved DprA recombination mediator. Transformation involves internalization of exogenous DNA as ssDNA, followed by its integration into the chromosome by RecA-directed HR. How DprA-mediated RecA filamentation on transforming ssDNA is spatiotemporally coordinated with other cellular processes remains unknown. Here, we tracked the localization of fluorescent fusions to DprA and RecA in Streptococcus pneumoniae and revealed that both accumulate in an interdependent manner with internalized ssDNA at replication forks. In addition, dynamic RecA filaments were observed emanating from replication forks, even with heterologous transforming DNA, which probably represent chromosomal homology search. In conclusion, this unveiled interaction between HR transformation and replication machineries highlights an unprecedented role for replisomes as landing pads for chromosomal access of tDNA, which would define a pivotal early HR step for its chromosomal integration.

Archaeal DNA-import apparatus is homologous to bacterial conjugation machinery

Conjugation is a major mechanism of horizontal gene transfer promoting the spread of antibiotic resistance among human pathogens. It involves establishing a junction between a donor and a recipient cell via an extracellular appendage known as the mating pilus. In bacteria, the conjugation machinery is encoded by plasmids or transposons and typically mediates the transfer of cognate mobile genetic elements. Much less is known about conjugation in archaea. Here, we determine atomic structures by cryo-electron microscopy of three conjugative pili, two from hyperthermophilic archaea (Aeropyrum pernix and Pyrobaculum calidifontis) and one encoded by the Ti plasmid of the bacterium Agrobacterium tumefaciens, and show that the archaeal pili are homologous to bacterial mating pili. However, the archaeal conjugation machinery, known as Ced, has been ‘domesticated’, that is, the genes for the conjugation machinery are encoded on the chromosome rather than on mobile genetic elements, and mediates the transfer of cellular DNA.

Horizontal Gene Transfer of Antibiotic Resistance Genes in Biofilms

Most bacteria attach to biotic or abiotic surfaces and are embedded in a complex matrix which is known as biofilm. Biofilm formation is especially worrisome in clinical settings as it hinders the treatment of infections with antibiotics due to the facilitated acquisition of antibiotic resistance genes (ARGs). Environmental settings are now considered as pivotal for driving biofilm formation, biofilm-mediated antibiotic resistance development and dissemination. Several studies have demonstrated that environmental biofilms can be hotspots for the dissemination of ARGs. These genes can be encoded on mobile genetic elements (MGEs) such as conjugative and mobilizable plasmids or integrative and conjugative elements (ICEs). ARGs can be rapidly transferred through horizontal gene transfer (HGT) which has been shown to occur more frequently in biofilms than in planktonic cultures. Biofilm models are promising tools to mimic natural biofilms to study the dissemination of ARGs via HGT. This review summarizes the state-of-the-art of biofilm studies and the techniques that visualize the three main HGT mechanisms in biofilms: transformation, transduction, and conjugation.

Domesticated conjugation machinery promotes DNA exchange in hyperthermophilic archaea.

Conjugation, a major mechanism of horizontal gene transfer promoting the spread of antibiotic resistance among human pathogens, involves establishing a junction between a donor and a recipient cell. The mating pilus plays a prominent role in this process. In bacteria, the conjugation machinery is encoded by plasmids or transposons and typically mediates the transfer of cognate mobile genetic elements. Much less has been known about conjugation in archaea, with no homologs of bacterial mating pilins having been identified in sequence searches. Here, using cryo-electron microscopy, we determined high-resolution structures of three conjugative pili, two from hyperthermophilic archaea, Aeropyrum pernix and Pyrobaculum calidifontis, and one encoded by the Ti plasmid of the bacterium Agrobacterium tumefaciens. We show that the archaeal pili are homologous to bacterial mating pili and display intricate pilin-lipid interaction networks. Unlike in bacteria, the conjugation machinery in hyperthermophilic archaea has been domesticated and mediates the transfer of cellular DNA. We suggest that the constitutive expression of the pili may be due to the chronic damage of DNA at high temperatures that is constantly being repaired using homologous recombination.

Gifts hidden in shadowy genome islands

Despite being typically perceived as "clonal" organisms, bacteria and archaea possess numerous mechanisms to share and co-opt genetic material from other lineages. Several mechanisms for horizontal gene transfer have been discovered, but the high mosaicity observed in many bacterial genomes outscales that explained by known mechanisms, hinting at yet undiscovered processes. In this issue of Cell, Hackl etal. introduce a new category of mobile genetic elements called tycheposons, providing a novel mechanism that contributes to the prodigious genomic diversity within microbial populations. The discovery and characterization of tycheposons prompts a reevaluation of microbial diversification in complex environments.

Effect of Protists on Horizontal Transfer of Antimicrobial Resistance Genes in Water Environment

There is much evidence that the environment is a reservoir of antibiotic resistance genes (ARGs). For ARG latency and stability, environmental factors should play a role since ARGs are transferred among bacterial species, which results in their evolution and dissemination. Recent findings have expanded the novel mechanisms of horizontal gene transfer (HGT) beyond classically accepted HGT mechanisms such as conjugation, transformation, and transduction. In these HGT processes, environmental factors directly or indirectly affect the transfer rate and mechanism. Here, we focus on the effect of protists that affect HGT, because HGT is regulated among the microbial community, in which protist grazing is one factor that enhances HGT. Protist grazing eliminates planktonic bacteria. However, it is reported that environmental DNA release and HGT in protist vacuoles are increased by the grazing, although the effect is not uniform and depends on the environmental conditions. Biofilms protect bacteria and accelerate HGT. In these processes, quorum sensing and organic matter contribute to HGT. Although HGT occurs between bacterial cells, other microorganisms such as protists should be recognized as factors relating to HGT. We should pay attention to microbial ecosystem when consider ARG risk from water environment in terms of “one health” aspect.

Mechanism of high-frequent horizontal gene transfer in Gram positive bacterial pathogens

Horizontal gene transfer through transconjugation and natural transformation plays a major role in the spread of antimicrobial resistance. Although the phenomenon of genetic element transmission has long been known, the rapid increase in the number of antimicrobial resistant bacteria in recent years and the accompanying accumulation of genomic information have revealed that horizontal gene transfer contributes to genome plasticity in various ways. The author reported the molecular mechanism of the antimicrobial activity of the accessory factor bacteriocin encoded by the junctional transfer plasmid of Enterococcus faecalis, a representative Gram-positive opportunistic pathogen that is concerned as highly antimicrobial resistant, and found diversity in the selfimmune system based on epidemiological studies. In addition, the author established a technique to visualize and quantify genomic recombination by natural transformation in Streptococcus pneumoniae which is also one of the most concerns for antimicrobial resistance and vaccine escape, at single cells level resolution in real time. Focuses on outcome from these research, this paper introduces the molecular mechanisms that promote horizontal gene transmission and the prospects for their technological application.