Plasmid Gene Transfer Research Articles

Multidrug-resistant plasmid RP4 inhibits the nitrogen removal capacity of ammonia-oxidizing archaea, ammonia-oxidizing bacteria, and comammox in activated sludge

In wastewater treatment plants (WWTPs), ammonia oxidation is primarily carried out by three types of ammonia oxidation microorganisms (AOMs): ammonia-oxidizing archaea (AOA), ammonia-oxidizing bacteria (AOB), and comammox (CMX). Antibiotic resistance genes (ARGs), which pose an important public health concern, have been identified at every stage of wastewater treatment. However, few studies have focused on the impact of ARGs on ammonia removal performance. Therefore, our study sought to investigate the effect of the representative multidrug-resistant plasmid RP4 on the functional microorganisms involved in ammonia oxidation. Using an inhibitor-based method, we first evaluated the contributions of AOA, AOB, and CMX to ammonia oxidation in activated sludge, which were determined to be 13.7%, 41.1%, and 39.1%, respectively. The inhibitory effects of C2H2, C8H14, and 3,4-dimethylpyrazole phosphate (DMPP) were then validated by qPCR. After adding donor strains to the sludge, fluorescence in situ hybridization (FISH) imaging analysis demonstrated the co-localization of RP4 plasmids and all three AOMs, thus confirming the horizontal gene transfer (HGT) of the RP4 plasmid among these microorganisms. Significant inhibitory effects of the RP4 plasmid on the ammonia nitrogen consumption of AOA, AOB, and CMX were also observed, with inhibition rates of 39.7%, 36.2%, and 49.7%, respectively. Moreover, amoA expression in AOB and CMX was variably inhibited by the RP4 plasmid, whereas AOA amoA expression was not inhibited. These results demonstrate the adverse environmental effects of the RP4 plasmid and provide indirect evidence supporting plasmid-mediated conjugation transfer from bacteria to archaea.

Role of natural transformation in the evolution of small cryptic plasmids in Synechocystis sp. PCC 6803.

Small cryptic plasmids have no clear effect on the host fitness and their functional repertoire remains obscure. The naturally competent cyanobacterium Synechocystis sp. PCC 6803 harbours several small cryptic plasmids; whether their evolution with this species is supported by horizontal transfer remains understudied. Here, we show that the small cryptic plasmid DNA is transferred in the population exclusively by natural transformation, where the transfer frequency of plasmid-encoded genes is similar to that of chromosome-encoded genes. Establishing a system to follow gene transfer, we compared the transfer frequency of genes encoded in cryptic plasmids pCA2.4 (2378 bp) and pCB2.4 (2345 bp) within and between populations of two Synechocystis sp. PCC 6803 labtypes (termed Kiel and Sevilla). Our results reveal that plasmid gene transfer frequency depends on the recipient labtype. Furthermore, gene transfer via whole plasmid uptake in the Sevilla labtype ranged among the lowest detected transfer rates in our experiments. Our study indicates that horizontal DNA transfer via natural transformation is frequent in the evolution of small cryptic plasmids that reside in naturally competent organisms. Furthermore, we suggest that the contribution of natural transformation to cryptic plasmid persistence in Synechocystis is limited.

Impact of mutagenesis and lateral gene transfer processes in bacterial susceptibility to phage in food biocontrol and phage therapy.

The emergence of resistance and interference mechanisms to phage infection can hinder the success of bacteriophage-based applications, but the significance of these mechanisms in phage therapy has not been determined. This work studies the emergence of Salmonella isolates with reduced susceptibility to a cocktail of three phages under three scenarios: i) Salmonella cultures (LAB), ii) biocontrol of cooked ham slices as a model of food safety (FOOD), and iii) oral phage therapy in broilers (PT). S. Typhimurium ATCC 14028 RifR variants with reduced phage susceptibility were isolated from the three scenarios and conventional and molecular microbiology techniques were applied to study them. In LAB, 92% of Salmonella isolates lost susceptibility to all three phages 24 h after phage infection. This percentage was lower in FOOD, with 4.3% of isolates not susceptible to at least two of the three phages after seven days at 4°C following phage treatment. In PT, 9.7% and 3.3 % of isolates from untreated and treated broilers, respectively, displayed some mechanism of interference with the life cycle of some of the phages. In LAB and FOOD scenarios, resistant variants carrying mutations in rfc and rfaJ genes involved in lipopolysaccharide synthesis (phage receptor) were identified. However, in PT, the significant decrease of EOP, ECOI, and burst size observed in isolates was prompted by lateral gene transfer of large IncI1 plasmids, which may encode phage defense mechanisms. These data indicate that the acquisition of specific conjugative plasmids has a stronger impact than mutagenesis on the emergence of reduced phage-susceptibility bacteria in certain environments. In spite of this, neither mechanism seems to significantly impair the success of Salmonella biocontrol and oral phage therapy.

Analysis of the features of 105 confirmed CRISPR loci in 487 Klebsiella variicola.

Klebsiella variicola, an emerging human pathogen, poses a threat to public health. The horizontal gene transfer (HGT) of plasmids is an important driver of the emergence of multiple antibiotic-resistant K. variicola. Clustered regularly interspersed short palindromic repeats (CRISPR) coupled with CRISPR-associated genes (CRISPR/Cas) constitute an adaptive immune system in bacteria, and can provide acquired immunity against HGT. However, the information about the CRISPR/Cas system in K. variicola is still limited. In this study, 487 genomes of K. variicola obtained from the National Center for Biotechnology Information database were used to analyze the characteristics of CRISPR/Cas systems. Approximately 21.56% of genomes (105/487) harbor at least one confirmed CRISPR array. Three types of CRISPR/Cas systems, namely the type I-E, I-E*, and IV-A systems, were identified among 105 strains. Spacer origin analysis further revealed that approximately one-third of spacers significantly match plasmids or phages, which demonstrates the implication of CRISPR/Cas systems in controlling HGT. Moreover, spacers in K. variicola tend to target mobile genetic elements from K. pneumoniae. This finding provides new evidence of the interaction of K. variicola and K. pneumoniae during their evolution. Collectively, our results provide valuable insights into the role of CRISPR/Cas systems in K. variicola.

SourceFinder: a Machine-Learning-Based Tool for Identification of Chromosomal, Plasmid, and Bacteriophage Sequences from Assemblies.

High-throughput genome sequencing technologies enable the investigation of complex genetic interactions, including the horizontal gene transfer of plasmids and bacteriophages. However, identifying these elements from assembled reads remains challenging due to genome sequence plasticity and the difficulty in assembling complete sequences. In this study, we developed a classifier, using random forest, to identify whether sequences originated from bacterial chromosomes, plasmids, or bacteriophages. The classifier was trained on a diverse collection of 23,211 chromosomal, plasmid, and bacteriophage sequences from hundreds of bacterial species. In order to adapt the classifier to incomplete sequences, each complete sequence was subsampled into 5,000 nucleotide fragments and further subdivided into k-mers. This three-class classifier succeeded in identifying chromosomes, plasmids, and bacteriophages using k-mer distributions of complete and partial genome sequences, including simulated metagenomic scaffolds with minimum performance of 0.939 area under the receiver operating characteristic curve (AUC). This classifier, implemented as SourceFinder, has been made available as an online web service to help the community with predicting the chromosomal, plasmid, and bacteriophage sources of assembled bacterial sequence data (https://cge.food.dtu.dk/services/SourceFinder/). IMPORTANCE Extra-chromosomal genes encoding antimicrobial resistance, metal resistance, and virulence provide selective advantages for bacterial survival under stress conditions and pose serious threats to human and animal health. These accessory genes can impact the composition of microbiomes by providing selective advantages to their hosts. Accurately identifying extra-chromosomal elements in genome sequence data are critical for understanding gene dissemination trajectories and taking preventative measures. Therefore, in this study, we developed a random forest classifier for identifying the source of bacterial chromosomal, plasmid, and bacteriophage sequences.

The effect of sequencing and assembly on the inference of horizontal gene transfer on chromosomal and plasmid phylogenies.

The spread of antibiotic resistance genes on plasmids is a threat to human and animal health. Phylogenies of bacteria and their plasmids contain clues regarding the frequency of plasmid transfer events, as well as the co-evolution of plasmids and their hosts. However, whole genome sequencing data from diverse ecological or clinical bacterial samples are rarely used to study plasmid phylogenies and resistance gene transfer. This is partially due to the difficulty of extracting plasmids from short-read sequencing data. Here, we use both short- and long-read sequencing data of 24 clinical extended-spectrum -lactamase (ESBL)-producing Escherichia coli to estimate chromosomal and plasmid phylogenies. We compare the impact of different sequencing and assembly methodologies on these phylogenies and on the inference of horizontal gene transfer. We find that chromosomal phylogenies can be estimated robustly with all methods, whereas plasmid phylogenies have more variable topology and branch lengths across the methods used. Specifically, hybrid methods that use long reads to resolve short-read assemblies (HybridSPAdes and Unicycler) perform better than those that started from long reads during assembly graph generation (Canu). By contrast, the inference of plasmid and antibiotic resistance gene transfer using a parsimony-based criterion is mostly robust to the choice of sequencing and assembly method.This article is part of a discussion meeting issue ‘Genomic population structures of microbial pathogens’.

Landscape of blaNDM genes in Enterobacteriaceae.

The blaNDM-1 gene encodes a carbapenemase, New Delhi metallo-β-lactamase (NDM-1), and the ability to produce NDM-1 is spread among Enterobacteriaceae via horizontal gene transfer of plasmids. It has been widely accepted that blaNDM-1 is regulated by a hybrid promoter (PISAba125) consisting of a -10 box from the original blaNDM-1 and a -35 box from ISAba125. However, the conservation of this promoter and the vertical transmission of blaNDM genes by chromosomal integration have not been comprehensively analyzed. We retrieved the region containing the ORF of blaNDM-1 (>95% translated protein identity) and a region 120 bp upstream of the blaNDM-1 start codon from the complete sequence data of Enterobacteriaceae plasmids (n = 10,914) and chromosomes (n = 4908) deposited in GenBank, and the 310 extracted blaNDM genes were analyzed by an in-silico approach. The results showed that most blaNDM genes (99.0%) utilized the promoter, PISAba125. Interestingly, two blaNDM-1 genes from the genus Citrobacter utilized the ISCR1-derived outward-oriented promoters POUT (PISCR1). Furthermore, the insertion of ISAba125 and ISCR1 occurred upstream of the CCATATTT sequence, which is located upstream of the -10 box. We also confirmed that most of the blaNDM genes were disseminated by horizontal gene transfer of the plasmid, but 10 cases of the blaNDM genes were integrated into the chromosome via mobile genetic elements such as IS26, IS150, ISCR1, ICE, and Tn7-like elements. Thus, plasmid-mediated transmission of the PISAba125-blaNDM genes is predominant in Enterobacteriaceae. However, the spread of blaNDM genes with new promoters and vertical dissemination via chromosomal integrations may pose additional serious clinical problems.

Horizontal Gene Transfer of an IncP1 Plasmid to Soil Bacterial Community Introduced by Escherichia coli through Manure Amendment in Soil Microcosms.

The quantification and identification of new plasmid-acquiring bacteria in representative mating conditions is critical to characterize the risk of horizontal gene transfer in the environment. This study aimed to quantify conjugation events resulting from manure application to soils and identify the transconjugants resulting from these events. Conjugation was quantified at multiple time points by plating and flow cytometry, and the transconjugants were recovered by fluorescence-activated cell sorting and identified by 16S rRNA sequencing. Overall, transconjugants were only observed within the first 4 days after manure application and at values close to the detection limits of this experimental system (1.00–2.49 log CFU/g of manured soil, ranging between 10–5 and 10–4 transconjugants-to-donor ratios). In the pool of recovered transconjugants, we found amplicon sequence variants (ASVs) of genera whose origin was traced to soils (Bacillus and Nocardioides) and manure (Comamonas and Rahnella). This work showed that gene transfer from fecal to soil bacteria occurred despite the less-than-optimal conditions faced by manure bacteria when transferred to soils, but these events were rare, mainly happened shortly after manure application, and the plasmid did not colonize the soil community. This study provides important information to determine the risks of AMR spread via manure application.

Influence of N-glycosylation in the A and C domains on the immunogenicity of factor VIII

AbstractThe most significant complication in hemophilia A treatment is the formation of inhibitors against factor VIII (FVIII) protein. Glycans and glycan-binding proteins are central to a properly functioning immune system. This study focuses on whether glycosylation of FVIII plays an important role in induction and regulation of anti-FVIII immune responses. We investigated the potential roles of 4 N-glycosylation sites, including N41 and N239 in the A1 domain, N1810 in the A3 domain, and N2118 in the C1 domain of FVIII, in moderating its immunogenicity. Glycomics analysis of plasma-derived FVIII revealed that sites N41, N239, and N1810 contain mostly sialylated complex glycoforms, while high mannose glycans dominate at site N2118. A missense variant that substitutes asparagine (N) to glutamine (Q) was introduced to eliminate glycosylation on each of these sites. Following gene transfer of plasmids encoding B domain deleted FVIII (BDD-FVIII) and each of these 4 FVIII variants, it was found that specific activity of FVIII in plasma remained similar among all treatment groups. Slightly increased or comparable immune responses in N41Q, N239Q, and N1810Q FVIII variant plasmid-treated mice and significantly decreased immune responses in N2118Q FVIII plasmid-treated mice were observed when compared with BDD-FVIII plasmid-treated mice. The reduction of inhibitor response by N2118Q FVIII variant was also demonstrated in AAV-mediated gene transfer experiments. Furthermore, a specific glycopeptide epitope surrounding the N2118 glycosylation site was identified and characterized to activate T cells in an FVIII-specific proliferation assay. These results indicate that N-glycosylation of FVIII can have significant impact on its immunogenicity.

The Conjugation Window in an Escherichia coli K-12 Strain with an IncFII Plasmid.

Many studies have examined the role that conjugation plays in disseminating antibiotic resistance genes in bacteria. However, relatively little research has quantitively examined and modeled the dynamics of conjugation under growing and nongrowing conditions beyond a couple of hours. We therefore examined growing and nongrowing cultures of Escherichia coli over a 24-h period to understand the dynamics of bacterial conjugation in the presence and absence of antibiotics with pUUH239.2, an IncFII plasmid containing multiantibiotic- and metal-resistant genes. Our data indicate that conjugation occurs after E. coli cells divide and before they have transitioned to a nongrowing phase. The result is that there is only a small window of opportunity for E. coli to conjugate with pUUH239.2 under both growing and nongrowing conditions. Only a very small percentage of the donor cells likely are capable of even undergoing conjugation, and not all transconjugants can become donor cells due to molecular regulatory controls and not being in the correct growth phase. Once a growing culture enters stationary phase, the number of capable donor cells decreases rapidly and conjugation slows to produce a plateau. Published models did not provide accurate descriptions of conjugation under nongrowing conditions. We present here a modified modeling approach that accurately describes observed conjugation behavior under growing and nongrowing conditions.IMPORTANCE There has been growing interest in horizontal gene transfer of antibiotic resistance plasmids as the antibiotic resistance crisis has worsened over the years. Most studies examining conjugation of bacterial plasmids focus on growing cultures of bacteria for short periods, but in the environment, most bacteria grow episodically and at much lower rates than in the laboratory. We examined conjugation of an IncFII antibiotic resistance plasmid in E. coli under growing and nongrowing conditions to understand the dynamics of conjugation under which the plasmid is transferred. We found that conjugation occurs in a narrow time frame when E. coli is transitioning from a growing to nongrowing phase and that the conjugation plateau develops because of a lack of capable donor cells in growing cultures. From an environmental aspect, our results suggest that episodic growth in nutrient-depleted environments could result in more conjugation than sustained growth in a nutrient rich environment.

Environmental Performance of Pseudomonas putida with a Uracylated Genome

A variant of the soil bacterium Pseudomonas putida with a genome containing a ∼20 % replacement of the whole of thymine (T) by uracil (U) was made by deleting genes ung (uracil DNA glycosylase) and dut (deoxyuridine 5'-triphosphate nucleotide hydrolase). Proteomic comparisons revealed that, of 281 up-regulated and 96 down-regulated proteins in the Δung Δdut cells, as compared to the wild-type, many were involved in nucleotide metabolism. Unexpectedly, genome uracylation did not greatly change the gross environmental endurance profile of P. putida, increased spontaneous mutagenesis by only twofold and supported expression of heterologous proteins well. As U-enriched DNA is potentially degraded by the base excision repair of recipients encoding a uracil DNA glycosylase, we then tested the spread potential of genetic material originating in the Δung Δdut cells either within the same species or in a commonly used Escherichia coli strain. Transformation and conjugation experiments revealed that horizontal gene transfer of U-containing plasmids fared worse than those made of standard DNA by two orders of magnitude. Although this figure does not guarantee the certainty of containment, it suggests a general strategy for curbing the dispersal of recombinant genetic constructs.

Determination of Plasmid pSN1216-29 Host Range and the Similarity in Oligonucleotide Composition Between Plasmid and Host Chromosomes.

Plasmids are extrachromosomal DNA that can be horizontally transferred between different bacterial cells by conjugation. Horizontal gene transfer of plasmids can promote rapid evolution and adaptation of bacteria by imparting various traits involved in antibiotic resistance, virulence, and metabolism to their hosts. The host range of plasmids is an important feature for understanding how they spread in environmental microbial communities. Earlier bioinformatics studies have demonstrated that plasmids are likely to have similar oligonucleotide (k-mer) compositions to their host chromosomes and that evolutionary host ranges of plasmids could be predicted from this similarity. However, there are no complementary studies to assess the consistency between the predicted evolutionary host range and experimentally determined replication/transfer host range of a plasmid. In the present study, the replication/transfer host range of a model plasmid, pSN1216-29, exogenously isolated from cow manure as a newly discovered self-transmissible plasmid, was experimentally determined within microbial communities extracted from soil and cow manure. In silico prediction of evolutionary host range was performed with the pSN1216-29 using its oligonucleotide compositions independently. The results showed that oligonucleotide compositions of the plasmid pSN1216-29 had more similarities to those of hosts (transconjugants genera) than those of non-hosts (other genera). These findings can contribute to the understanding of how plasmids behave in microbial communities, and aid in the designing of appropriate plasmid vectors for different bacteria.

SO025DCR2 ACCELERATES RENAL FIBROSIS AND TUBULAR CELL SENESCENCE BY PHOSPHORYLATING TYR 194 OF PRDX1 IN DIABETIC NEPHROPATHY

Abstract Background and Aims Cell senescence of renal tubular epithelial cells (RTECs), which is involved in renal tubulointerstitial fibrosis (TIF), is a key event in the progression of diabetic nephropathy (DN). However, the underlying mechanism remains unclear. This study aims to investigate the role and mechanism of decoy receptor 2 (DcR2) in TIF and cell senescence of RTECs. Method Streptozotocin (STZ)-induced DN mice model and high glucose (HG)-induced cell senescent model were constructed. The expression of DcR2 were regulated by ultrasound-mediated gene transfer of DcR2-siRNA or DcR2-overexpression plasmid in vivo. The co-expression of DcR2 with senescent markers (p16, p21 and SA-β-gal) and fibrotic markers (FN, collagen I and α-SMA). The interaction of DcR2 and its ligand TRAIL and antagonistic receptor DR5 were detected by laser confocal and Co-IP. The DcR2-interaction proteins were screened in renal tissue of DN patients and HG-induced cells by Co-IP combining with LC-MS/MS. The interaction of DcR2 and PRDX1 was validated by Co-IP, pull down assay and immunofluorescence co-staining. Peroxidase activity of PRDX1 was assessed by the kits of reactive oxygen species (ROS) and specific 2-cys peroxidase activity. The level of PRDX1 phosphorylation was measured through WB and the phosphorylated site were studied by wild-type PRDX1 and mutant Tyr194 PRDX1. Results DcR2 was co-expressed with senescent markers and co-localization with fibrotic markers in DN patients and STZ-DN mice. Knockdown of DcR2 effectively decreased renal fibrosis and tubular cell senescence in STZ-induced DN mice. However, DcR2 overexpression showed the opposite effects. DcR2 didn’t interacted with TRAIL or DR5 in vivo and vitro. The following study indicated that PRDX1 is a novel DcR2-interacting protein using quantitative proteomics, which have peroxidase and antioxidant activity in cytoplasm. The interaction of DcR2-PRDX1 mediated RTEC senescence in vitro. Knockdown of DcR2 inhibited the level of ROS and promoted the peroxidase activity of PRDX1, resulting in oxidative stress and cell senescence, and DcR2 overexpression presented the contrary results. DcR2 regulated the level of PRDX1 phosphorylation by interacting Tyr194 of PRDX1, and the mutant Tyr194 of PRDX1 can’t be phosphorylated by DcR2. Conclusion DcR2 mediates renal fibrosis and RTEC senescence by phosphorylating with PRDX1, suggesting DcR2 could serve as a potential therapeutic target for the amelioration of DN progression.

Dissecting horizontal and vertical gene transfer of antibiotic resistance plasmid in bacterial community using microfluidics

The spread of antibiotic resistance genes (ARGs) has become an emerging threat to the global health. Although horizontal gene transfer (HGT) is regarded as one of the major pathways, more evidence has shown the significant involvement of vertical gene transfer (VGT). However, traditional cultivation-based methods cannot distinguish HGT and VGT, resulting in often contradictory conclusions. Here, single-cell microfluidics with time-lapse imaging has been successfully employed to dissect the contribution of plasmid-mediated HGT and VGT to ARG transmission in an environmental community. Using Escherichia coli with an ARG-coded plasmid pKJK5 with trimethoprim resistance as the donor, we quantified the effects of three representative antibiotics (trimethoprim, tetracycline and amoxicillin) on the ARG transfer process in an activated sludge bacterial community. It was found that HGT was influenced by the inhibitory mechanism of an antibiotic and its targets (donor, recipient alone or together), whereas VGT contributes significantly to the formation of transconjugants and consequently ARG spreading. Trimethoprim is highly resisted by the donor and transconjugants, and its presence significantly increased both the HGT and VGT rates. Although tetracycline and amoxicillin both inhibit the donor, they showed different effects on HGT rate as a result of different inhibitory mechanisms. Furthermore, we show the kinetics of HGT in a community can be described using an epidemic infection model, which in combination with quantitative measure of HGT and VGT on chip provides a promising tool to study and predict the dynamics of ARG spread in real-world communities.

Diversity of CRISPR/Cas system in Clostridium perfringens.

Clostridium perfringens is an important pathogen of human and livestock infections, posing a threat to health. The horizontal gene transfer (HGT) of plasmids that carry toxin-related genes is involved in C. perfringens pathogenicity. The CRISPR/Cas system, which has been identified in a wide range of prokaryotes, provides acquired immunity against HGT. However, information about the CRISPR/Cas system in Clostridium perfringens is still limited. In this study, 111 C. perfringens strains with publicly available genomes were used to analyze the occurrence and diversity of CRISPR/Cas system and evaluate the potential of CRISPR-based genotyping in this multi-host pathogen. A total of 59 out of the 111 genomes harbored at least one confirmed CRISPR array. Four CRISPR/Cas system subtypes, including subtypes IB, IIA, IIC, and IIID systems, were identified in 32 strains. Subtype IB system was the most prevalent in this species, which was subdivided into four subgroups displaying subgroup specificity in terms of cas gene content, repeat sequence content, and PAM. We showed that the CRISPR spacer polymorphism can be used for evolutionary studies, and that it can provide discriminatory power for typing strains. Nevertheless, the application of this approach was largely limited to strains that contain the CRISPR/Cas system. Spacer origin analysis revealed that approximately one-fifth of spacers showed significant matches to plasmids and phages, thereby suggesting the implication of CRISPR/Cas systems in controlling HGT. Collectively, our results provide new insights into the diversity and evolution of CRISPR/Cas system in C. perfringens.

Occurrence of human pathogenic bacteria carrying antibiotic resistance genes revealed by metagenomic approach: A case study from an aquatic environment

Antibiotic resistance genes (ARGs), human pathogenic bacteria (HPB), and HPB carrying ARGs are public issues that pose a high risk to aquatic environments and public health. Their diversity and abundance in water, intestine, and sediments of shrimp culture pond were investigated using metagenomic approach. A total of 19 classes of ARGs, 52 HPB species, and 7 species of HPB carrying ARGs were found. Additionally, 157, 104, and 86 subtypes of ARGs were detected in shrimp intestine, pond water, and sediment samples, respectively. In all the samples, multidrug resistance genes were the highest abundant class of ARGs. The dominant HPB was Enterococcus faecalis in shrimp intestine, Vibrio parahaemolyticus in sediments, and Mycobacterium yongonense in water, respectively. Moreover, E. faecalis (contig Intestine_364647) and Enterococcus faecium (contig Intestine_80272) carrying efrA, efrB and ANT(6)-Ia were found in shrimp intestine, Desulfosaricina cetonica (contig Sediment_825143) and Escherichia coli (contig Sediment_188430) carrying mexB and APH(3′)-IIa were found in sediments, and Laribacter hongkongensis (contig Water_478168 and Water_369477), Shigella sonnei (contig Water_880246), and Acinetobacter baumannii (contig Water_525520) carrying sul1, sul2, ereA, qacH, OXA-21, and mphD were found in pond water. Mobile genetic elements (MGEs) analysis indicated that horizontal gene transfer (HGT) of integrons, insertion sequences, and plasmids existed in shrimp intestine, sediment, and water samples, and the abundance of integrons was higher than that of other two MGEs. The results suggested that HPB carrying ARGs potentially existed in aquatic environments, and that these contributed to the environment and public health risk evaluation.

Eigensolutions and spectral analysis of a model for vertical gene transfer of plasmids.

Plasmids are autonomously replicating genetic elements in bacteria. At cell division, plasmids are distributed among the two daughter cells. This gene transfer from one generation to the next is called vertical gene transfer. We study the dynamics of a bacterial population carrying plasmids and are in particular interested in the long-time distribution of plasmids. Starting with a model for a bacterial population structured by the discrete number of plasmids, we proceed to the continuum limit in order to derive a continuous model. The model incorporates plasmid reproduction, division and death of bacteria, and distribution of plasmids at cell division. It is a hyperbolic integro-differential equation and a so-called growth-fragmentation-death model. As we are interested in the long-time distribution of plasmids we study the associated eigenproblem and show existence of eigensolutions. The stability of this solution is studied by analyzing the spectrum of the integro-differential operator given by the eigenproblem. By relating the spectrum with the spectrum of an integral operator we find a simple real dominating eigenvalue with a non-negative corresponding eigenfunction. Moreover, we describe an iterative method for the numerical construction of the eigenfunction.

PEGylated enhanced cell penetrating peptide nanoparticles for lung gene therapy

The lung remains an attractive target for the gene therapy of monogenetic diseases such as cystic fibrosis (CF). Despite over 27 clinical trials, there are still very few gene therapy vectors that have shown any improvement in lung function; highlighting the need to develop formulations with improved gene transfer potency and the desirable physiochemical characteristics for efficacious therapy. Herein, we introduce a novel cell penetrating peptide (CPP)-based non-viral vector that utilises glycosaminoglycan (GAG)-binding enhanced transduction (GET) for highly efficient gene transfer. GET peptides couple directly with DNA through electrostatic interactions to form nanoparticles (NPs). In order to adapt the GET peptide for efficient in vivo delivery, we engineered PEGylated versions of the peptide and employed a strategy to form DNA NPs with different densities of PEG coatings. We were able to identify candidate formulations (PEGylation rates ≥40%) that shielded the positively charged surface of particles, maintained colloidal stability in bronchoalveolar lavage fluid (BALF) and retained gene transfer activity in human bronchial epithelial cell lines and precision cut lung slices (PCLS) in vitro. Using multiple particle tracking (MPT) technology, we demonstrated that PEG-GET complexes were able to navigate the mucus mesh and diffuse rapidly through patient CF sputum samples ex vivo. When tested in mouse lung models in vivo, PEGylated particles demonstrated superior biodistribution, improved safety profiles and efficient gene transfer of a reporter luciferase plasmid compared to non-PEGylated complexes. Furthermore, gene expression was significantly enhanced in comparison to polyethylenimine (PEI), a non-viral gene carrier that has been widely tested in pre-clinical settings. This work describes an innovative approach that combines novel GET peptides for enhanced transfection with a tuneable PEG coating for efficacious lung gene therapy.

Gene transfer of a naked plasmid (pUDK-HGF) encoding human hepatocyte growth factor attenuates skin/muscle incision and retraction-induced chronic post-surgical pain in rats.

Chronic post-surgical pain (CPSP) remains a major clinical problem and is often refractory to current treatments. New analgesic medications and strategies for pain relief are needed. Hepatocyte growth factor (HGF) is known to be a multi-functional growth factor and regulates various biological activities. We investigated the analgesic effect and underlying mechanism of plasmid pUDK-HGF encoding human HGF gene on CPSP induced by skin/muscle incision and retraction (SMIR) in rats. The possible changes of inflammatory factors, glial cell activation and pain sensitivity after pUDK-HGF administration were investigated by ELISA, western blot and Von Frey tests, respectively. In behavioural assays, we found that a single intramuscular or intrathecal injection of pUDK-HGF significantly attenuated mechanical hypersensitivity to von Frey stimulation of plantar ipsilateral hind paw after SMIR. Intramuscular injection of pUDK-HGF promoted blood flow and proliferation of satellite cells and inhibited inflammatory cells recruitment, collagen accumulation and expression of pronociceptive factors. Intrathecal injection of pUDK-HGF inhibited activation of spinal glial cells and production of inflammatory mediators induced by SMIR. pUDK-HGF has a strong analgesic potency and efficacy in CPSP induced by SMIR in rats. This study highlights a new strategy for the treatment of CPSP. The CPSP occurs following various surgical procedures and remains a major clinical problem due to the lack of study on the mechanisms of CPSP. Our findings provide the first evidence that pUDK-HGF attenuates SMIR-induced pain behaviuors through peripheral or central mechanisms. The peripheral analgesic effect of pUDK-HGF is associated with promoting tissue repair and inhibiting inflammatory response; furthermore, pUDK-HGF inhibits activation of spinal glial cells and overexpression of inflammatory mediators in spinal cord. Therefore, naked pUDK-HGF may be a potential therapeutic strategy for treatment of CPSP in clinic.

The Intriguing Evolutionary Journey of Enteroinvasive E. coli (EIEC) toward Pathogenicity

Among the intestinal pathogenic Escherichia coli, enteroinvasive E. coli (EIEC) are a group of intracellular pathogens able to enter epithelial cells of colon, multiplicate within them, and move between adjacent cells with a mechanism similar to Shigella, the ethiological agent of bacillary dysentery. Despite EIEC belong to the same pathotype of Shigella, they neither have the full set of traits that define Shigella nor have undergone the extensive gene decay observed in Shigella. Molecular analysis confirms that EIEC are widely distributed among E. coli phylogenetic groups and correspond to bioserotypes found in many E. coli serogroups. Like Shigella, also in EIEC the critical event toward a pathogenic life-style consisted in the acquisition by horizontal gene transfer of a large F-type plasmid (pINV) containing the genes required for invasion, intracellular survival, and spreading through the intestinal mucosa. In Shigella, the ample gain in virulence determinants has been counteracted by a substantial loss of functions that, although important for the survival in the environment, are redundant or deleterious for the life inside the host. The pathoadaptation process that has led Shigella to modify its metabolic profile and increase its pathogenic potential is still in infancy in EIEC, although maintenance of some features typical of E. coli might favor their emerging relevance as intestinal pathogens worldwide, as documented by recent outbreaks in industrialized countries. In this review, we will discuss the evolution of EIEC toward Shigella-like invasive forms going through the epidemiology, including the emergence of new virulent strains, their genome organization, and the complex interactions they establish with the host.