McbR is involved in biofilm formation and H2O2 stress response in avian pathogenic Escherichia coli X40

The effects of NDM-5 on Escherichia coli and the screening of interacting proteins

Carbapenem-resistant Escherichia coli (E. coli) strains are widely distributed and spreading rapidly, creating significant challenges for clinical therapeutics. NDM-5, a novel mutant of New Delhi Metallo-β-Lactamase-1 (NDM-1), exhibits high hydrolase activity toward carbapenems. Since the genetic backgrounds of clinically isolated carbapenem-resistant E. coli are heterogeneous, it is difficult to accurately evaluate the impact of blaNDM-5 on antibiotic resistance. Herein, E. coli BL21 was transformed with a plasmid harboring blaNDM-5, and the resultant strain was named BL21 (pET-28a-blaNDM-5). Consistent with the findings of previous studies, the introduction of exogenous blaNDM-5 resulted in markedly greater resistance of E. coli to multiple β-lactam antibiotics. Compared with BL21 (pET-28a), BL21 (pET-28a-blaNDM-5) exhibited reduced motility but a significant increase in biofilm formation capacity. Furthermore, transcriptome sequencing was conducted to compare the transcriptional differences between BL21 (pET-28a) and BL21 (pET-28a-blaNDM-5). A total of 461 differentially expressed genes were identified, including those related to antibiotic resistance, such as genes associated with the active efflux system (yddA, mcbR and emrY), pili (csgC, csgF and fimD), biofilm formation (csgD, csgB and ecpR) and antioxidant processes (nuoG). Finally, the pGS21a plasmid harboring blaNDM-5 was transformed into E. coli Rosetta2, after which the expression of the NDM-5 protein was induced using isopropyl-β-D-thiogalactoside (IPTG). Using glutathione-S-transferase (GST) pull-down assays, total proteins from E. coli were scanned to screen out 82 proteins that potentially interacted with NDM-5. Our findings provide new insight into the identified proteins to identify potential antibiotic targets and design novel inhibitors of carbapenem-resistant bacteria.

The transcriptional regulator EtrA mediates ompW contributing to the pathogenicity of avian pathogenic Escherichia coli

Avian pathogenic Escherichia coli (APEC) causes avian colibacillosis and leads to high mortality in poultry and huge economic losses. Therefore, it is important to investigate the pathogenic mechanisms of APEC. Outer membrane protein OmpW is involved in the environmental adaptation and pathogenesis of Gram-negative bacteria. OmpW is regulated by many proteins, including FNR, ArcA, and NarL. In previous studies, regulator EtrA is involved in the pathogenicity of APEC and affects the transcript levels of ompW. However, the function of OmpW in APEC and its regulation remain unclear. In this study, we constructed mutant strains with altered etrA and/or ompW genes to evaluate the roles of EtrA and OmpW in the biological characteristics and pathogenicity of APEC. Compared with wild-type strain AE40, mutant strains ∆etrA, ∆ompW, and ∆etrA∆ompW showed significantly lower motility, lower survival under external environmental stress, and lower resistance to serum. Biofilm formation by ∆etrA and ∆etrA∆ompW was significantly enhanced relative to that of AE40. The transcript levels of TNF-α, IL1β, and IL6 were also significantly enhanced in DF-1 cells infected with these mutant strains. Animal infection assays showed that deletion of etrA and ompW genes attenuated the virulence of APEC in chick models, and damage to the trachea, heart, and liver caused by these mutant strains was attenuated relative to that caused by the wild-type strain. RT-qPCR and β-galactosidase assay showed that EtrA positively regulates the expression of the ompW gene. These findings demonstrate that regulator EtrA positively regulates the expression of OmpW, and that they both contribute to APEC motility, biofilm formation, serum resistance, and pathogenicity.

The Two-Component System CpxRA Affects Antibiotic Susceptibility and Biofilm Formation in Avian Pathogenic Escherichia coli

Avian pathogenic Escherichia coli (APEC) is one of the common extraintestinal infectious disease pathogens in chickens, geese, and other birds. It can cause a variety of infections, and even the death of poultry, causing enormous economic losses. However, the misuse and abuse of antibiotics in the poultry industry have led to the development of drug resistance in the gut microbes, posing a challenge for the treatment of APEC infections. It has been reported that the CpxRA two-component system has an effect on bacterial drug resistance, but the specific regulatory mechanism remains unclear. In this study, the regulatory mechanism of CpxRA on APEC biofilm formation and EmrKY efflux pump was investigated. The cpxRA knockout strain of E. coli APEC40 was constructed, and the molecular regulatory mechanism of CpxR on biofilms and efflux pump-coding genes were identified by biofilm formation assays, drug susceptibility test, real-time reverse transcription quantitative PCR, and electrophoretic mobility shift assay (EMSA). The results indicated that CpxR can directly bind to the promoter region of emrKY and negatively regulate the sensitivity of bacteria to ofloxacin and erythromycin. These results confirm the important regulatory role of the CpxRA two-component system under antibiotic stress in APEC.

The two-component system histidine kinase EnvZ contributes to Avian pathogenic Escherichia coli pathogenicity by regulating biofilm formation and stress responses

EnvZ, the histidine kinase (HK) of OmpR/EnvZ, transduces osmotic signals in Escherichia coli K12 and affects the pathogenicity of Shigella flexneri and Vibrio cholera. Avian pathogenic E. coli (APEC) is an extra-intestinal pathogenic E. coli (ExPEC), causing acute and sudden death in poultry and leading to severe economic losses to the global poultry industry. How the functions of EnvZ correlate with APEC pathogenicity was still unknown. In this study, we successfully constructed the envZ mutant strain AE17ΔenvZ and the inactivation of envZ significantly reduced biofilms and altered red, dry, and rough (rdar) morphology. In addition, AE17ΔenvZ was significantly less resistant to acid, alkali, osmotic, and oxidative stress conditions. Deletion of envZ significantly enhanced sensitivity to specific pathogen-free (SPF) chicken serum and increased adhesion to chicken embryonic fibroblast DF-1 cells and elevated inflammatory cytokine IL-1β, IL6, and IL8 expression levels. Also, when compared with the WT strain, AE17ΔenvZ attenuated APEC pathogenicity in chickens. To explore the molecular mechanisms underpinning envZ in APEC17, we compared the WT and envZ-deletion strains using transcriptome analyses. RNA-Seq results identified 711 differentially expressed genes (DEGs) in the envZ mutant strain and DEGs were mainly enriched in outer membrane proteins, stress response systems, and TCSs. Quantitative real-time reverse transcription PCR (RT-qPCR) showed that EnvZ influenced the expression of biofilms and stress responses genes, including ompC, ompT, mlrA, basR, hdeA, hdeB, adiY, and uspB. We provided compelling evidence showing EnvZ contributed to APEC pathogenicity by regulating biofilms and stress response expression.

LuxR family transcriptional repressor YjjQ modulates the biofilm formation and motility of avian pathogenic Escherichia coli

Avian pathogenic Escherichia coli (APEC) can cause the acute and sudden death of poultry, which leads to serious economic losses in the poultry industry. Biofilm formation contributes to the persistence of bacterial infection, drug resistance, and resistance to diverse environmental stress. Many transcription regulators in APEC play an essential role in the formation of biofilm and could provide further insights into APEC pathogenesis. YjjQ has an important role in the pathogenicity of bacteria by regulating the expression of virulence factors, such as flagellar and iron uptake. However, YjjQ regulates other virulence factors, and their role in the overall regulatory network is unclear. Here, we further evaluate the function of YjjQ on APEC biofilm formation and motility. In this study, we successfully constructed mutant (AE27∆yjjQ) and complement (AE27ΔyjjQ-comp) strains of the wild-type strain AE27. Inactivation of the yjjQ gene significantly increased biofilm-forming ability in APEC. Scanning electron microscopy showed that the biofilm formation of the AE27 was single-layered and flat, whereas that of the AE27∆yjjQ had a porous three-dimensional structure. Moreover, the deletion of the yjjQ gene inhibited the motility of APEC. RNA-sequencing was used to further investigate the regulatory mechanism of YjjQ in APEC. The results indicate that YjjQ regulates biofilm formation and flagellar genes in AE27∆yjjQ. RT-qPCR shows that YjjQ affects the transcriptional levels of genes, including flagella genes (flhD, flhC and flgE), and biofilm formation genes (pstA, uhpC, nikD, and ygcS). These results confirm that the transcription regulator YjjQ is involved in APEC biofilm formation and motility, and provide new evidence for the prevention and control of APEC.

The Transcription Regulator YgeK Affects Biofilm Formation and Environmental Stress Resistance in Avian Pathogenic Escherichia coli

Simple Summary

Avian pathogenic Escherichia coli (APEC) is the pathogen responsible for colibacillosis in poultry. Transcriptional regulator ygeK has been shown to decrease APEC’s flagellar formation ability, bacterial motility ability, serum sensitivity, and adhesion ability. However, we did not study the effects of ygeK on biofilm formation and environmental stress resistance in APEC. In this study, we investigated ygeK in APEC biofilm formation and bacterial resistance to different environmental stresses. We also analyzed the multi-level regulation of ygeK in APEC and investigated associations between differentially expressed proteins and key ygeK targets. This work provides a basis for further analysis of APEC pathogenesis mechanisms.

Abstract

Avian pathogenic Escherichia coli (APEC) is one of the most common pathogens in poultry and a potential gene source of human extraintestinal pathogenic E. coli (ExPEC), leading to serious economic losses in the poultry industry and public health concerns. Exploring the pathogenic mechanisms underpinning APEC and the identification of new targets for disease prevention and treatment are warranted. YgeK is a transcriptional regulator in APEC and is localized to the type III secretion system 2 of E. coli. In our previous work, the transcription factor ygeK significantly affected APEC flagella formation, bacterial motility, serum sensitivity, adhesion, and virulence. To further explore ygeK functions, we evaluated its influence on APEC biofilm formation and resistance to environmental stress. Our results showed that ygeK inactivation decreased biofilm formation and reduced bacterial resistance to environmental stresses, including acid and oxidative stress. In addition, the multi-level regulation of ygeK in APEC was analyzed using proteomics, and associations between differentially expressed proteins and the key targets of ygeK were investigated. Overall, we identified ygeK’s new function in APEC. These have led us to better understand the transcriptional regulatory ygeK and provide new clues about the pathogenicity of APEC.

Transcription Regulator YgeK Affects the Virulence of Avian Pathogenic Escherichia coli

Simple Summary

Avian pathogenic Escherichia coli (APEC) is the responsible pathogen for colibacillosis in poultry. Transcriptional regulator YgeK was a transcriptional regulator locating at E. coli type three secretion system 2 (ETT2) in APEC. However, the role of YgeK in APEC has not been reported. In this study, we found that the inactivation of YgeK in APEC decreased the flagellar formation ability, bacterial motility ability, serum sensitivity, adhesion ability, and virulence. Results suggested that the transcriptional regulator YgeK plays a crucial role in APEC virulence.

Abstract

Avian pathogenic Escherichia coli (APEC) is the responsible pathogen for colibacillosis in poultry, and is a potential gene source for human extraintestinal pathogenic Escherichia coli. Escherichia coli type III secretion system 2 (ETT2) is widely distributed in human and animal ExPEC isolates, and is crucial for the virulence of ExPEC. Transcriptional regulator YgeK, located in the ETT2 gene cluster, was identified as an important regulator of gene expression in enterohemorrhagic E. coli (EHEC). However, the role of YgeK in APEC has not been reported. In this study, we performed amino acid alignment analysis of YgeK among different E. coli strains and generated ygeK mutant strain AE81ΔygeK from clinical APEC strain AE81. Flagellar formation, bacterial motility, serum sensitivity, adhesion, and virulence were all significantly reduced following the inactivation of YgeK in APEC. Then, we performed transcriptome sequencing to analyze the functional pathways involved in the biological processes. Results suggested that ETT2 transcriptional regulator YgeK plays a crucial role in APEC virulence. These findings thus contribute to our understanding of the function of the ETT2 cluster, and clarify the pathogenic mechanism of APEC.

Genome-Wide Screening of Oxidizing Agent Resistance Genes in Escherichia coli

The use of oxidizing agents is one of the most favorable approaches to kill bacteria in daily life. However, bacteria have been evolving to survive in the presence of different oxidizing agents. In this study, we aimed to obtain a comprehensive list of genes whose expression can make Escherichiacoli cells resistant to different oxidizing agents. For this purpose, we utilized the ASKA library and performed a genome-wide screening of ~4200 E. coli genes. Hydrogen peroxide (H₂O₂) and hypochlorite (HOCl) were tested as representative oxidizing agents in this study. To further validate our screening results, we used different E. coli strains as host cells to express or inactivate selected resistance genes individually. More than 100 genes obtained in this screening were not known to associate with oxidative stress responses before. Thus, this study is expected to facilitate both basic studies on oxidative stress and the development of antibacterial agents.

Avian Pathogenic Escherichia coli (APEC): An Overview of Virulence and Pathogenesis Factors, Zoonotic Potential, and Control Strategies

Avian pathogenic Escherichia coli (APEC) causes colibacillosis in avian species, and recent reports have suggested APEC as a potential foodborne zoonotic pathogen. Herein, we discuss the virulence and pathogenesis factors of APEC, review the zoonotic potential, provide the current status of antibiotic resistance and progress in vaccine development, and summarize the alternative control measures being investigated. In addition to the known virulence factors, several other factors including quorum sensing system, secretion systems, two-component systems, transcriptional regulators, and genes associated with metabolism also contribute to APEC pathogenesis. The clear understanding of these factors will help in developing new effective treatments. The APEC isolates (particularly belonging to ST95 and ST131 or O1, O2, and O18) have genetic similarities and commonalities in virulence genes with human uropathogenic E. coli (UPEC) and neonatal meningitis E. coli (NMEC) and abilities to cause urinary tract infections and meningitis in humans. Therefore, the zoonotic potential of APEC cannot be undervalued. APEC resistance to almost all classes of antibiotics, including carbapenems, has been already reported. There is a need for an effective APEC vaccine that can provide protection against diverse APEC serotypes. Alternative therapies, especially the virulence inhibitors, can provide a novel solution with less likelihood of developing resistance.

Role of McbR in the regulation of antibiotic susceptibility in avian pathogenic Escherichia coli

Avian pathogenic Escherichia coli (APEC) causes a variety of bacterial infectious diseases known as avian colibacillosis leading to significant economic losses in the poultry industry worldwide and restricting the development of the poultry industry. The development of efflux pumps is one important bacterial antibiotic resistance mechanism. Efflux pumps are capable of extruding a wide range of antibiotics out of the cytoplasm of some bacterial species, including β-lactams, polymyxins, tetracyclines, fluoroquinolones, aminoglycosides, novobiocin, nalidixic acid, and fosfomycin. In the present study, we constructed the mcbR mutant and the mcbR-overexpressing strain of E. coli strain APECX40 and performed antimicrobial susceptibility testing, antibacterial activity assays, real-time reverse transcription PCR, and electrophoretic mobility shift assays (EMSA) to investigate the molecular regulatory mechanism of McbR on the genes encoding efflux pumps. Our results showed that McbR positively regulates cell susceptibility to 12 antibiotics, including clindamycin, lincomycin, cefotaxime, cefalexin, doxycycline, tetracycline, gentamicin, kanamycin, norfloxacin, ofloxacin, erythromycin, and rifampicin by activating the transcription of acrAB, acrD, emrD, and mdtD (P < 0.01). Additionally, EMSA indicated that McbR specifically binds to the promoter regions of acrAB, acrD, acrR, emrD, and mdtD. This study suggests that, in APECX40, McbR plays an important role in the regulation of bacterial susceptibility by directly activating the transcription of efflux pumps genes.

Regulatory Role of the Two-Component System BasSR in the Expression of the EmrD Multidrug Efflux in Escherichia coli

Due to excessive use of antimicrobial agents in the treatment of infectious diseases, bacteria have developed resistance to antibacterial drugs and toxic compounds. The development of multidrug efflux pumps is one of the important mechanisms of bacterial drug resistance. A multidrug efflux pump, EmrD, belonging to the major facilitator superfamily of transporters, confers resistance to many antimicrobial agents. BasSR, a typical two-component signal transduction system (TCS), regulates susceptibility to the cationic antimicrobial peptide, polymyxin B, and the anionic bile detergent, deoxycholic acid, in Escherichia coli. However, whether or not the BasSR TCS affects susceptibility or resistance to other antimicrobial agents and transcription of emrD has not been reported in E. coli. In the present study, we constructed the basSR mutants of wild-type MG1655 and clinical strain APECX40 and performed antimicrobial susceptibility testing, antibacterial activity assays, real-time reverse transcription-PCR experiments and electrophoretic mobility shift assays (EMSA) to investigate the molecular mechanism by which BasSR regulates the EmrD multidrug efflux pump. Results showed that the basSR mutation increased cell susceptibility to eight antimicrobial agents, including ciprofloxacin, norfloxacin, doxycycline, tetracycline, clindamycin, lincomycin, erythromycin, and sodium dodecyl sulfate, by downregulating the transcriptional levels of emrD. Furthermore, EMSA indicated that BasR could directly bind to the emrD promoter. Therefore, this study was the first to demonstrate that BasSR activates transcription of emrD by binding directly to its promoter region, and then decreases susceptibility to various antimicrobial agents in E. coli strains, APECX40 and MG1655.

Coexistence of Two bla NDM- 5 Genes Carried on IncX3 and IncFII Plasmids in an Escherichia coli Isolate Revealed by Illumina and Nanopore Sequencing

The emergence of carbapenem-resistant Enterobacteriaceae poses a significant threat to public health worldwide. Here, we reported a multidrug-resistant Escherichia coli strain with two different bla_NDM–5-carrying plasmids from China. Illumina short-read and MinION long-read whole genome sequencing were performed. Genomic analysis found that one bla_NDM–5 gene together with mphA was located on a 55-kb IncX3 plasmid, while the other bla_NDM–5 gene was on a novel 68-kb IncFII plasmid. Susceptibility testing and quantitative reverse transcription PCR results further indicated that the transconjugants with the IncX3 plasmid exhibited higher-level carbapenem resistance and expression of bla_NDM–5 than those with both plasmids or the IncFII plasmid. Two other β-lactamase genes (bla_CTX–M–15 and bla_OXA–1) were also detected on another 160-kb IncF plasmid. This is the first report of coexistence of two bla_NDM–5-carrying plasmids in a single bacterial isolate, highlighting the genetic complexity of NDM-5 carbapenemase circulation, and the urgent need for continued active surveillance.

OxyR senses sulfane sulfur and activates the genes for its removal in Escherichia coli

Sulfane sulfur species including hydrogen polysulfide and organic persulfide are newly recognized normal cellular components, and they participate in signaling and protect cells from oxidative stress. Their production has been extensively studied, but their removal is less characterized. Herein, we showed that sulfane sulfur at high levels was toxic to Escherichia coli under both anaerobic and aerobic conditions. OxyR, a well-known regulator against H₂O₂, also sensed sulfane sulfur, as revealed via mutational analysis, constructed gene circuits, and in vitro gene expression. Hydrogen polysulfide modified OxyR at Cys199 to form a persulfide OxyR C199-SSH, and the modified OxyR activated the expression of thioredoxin 2 and glutaredoxin 1. The two enzymes are known to reduce sulfane sulfur to hydrogen sulfide. Bioinformatics analysis indicated that OxyR homologs are widely present in bacteria, including obligate anaerobic bacteria. Thus, the OxyR sensing of sulfane sulfur may represent a preserved mechanism for bacteria to deal with sulfane sulfur stress.

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OxyR also senses sulfane sulfur stress and activates the genes for its removal.

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OxyR senses hydrogen polysulfide via persulfidation of OxyR at Cys¹⁹⁹.

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OxyR responds to sulfane sulfur stress under both aerobic and anaerobic conditions.

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OxyR is widely distributed in bacterial genomes, including anaerobic bacteria.