rpoS Gene Research Articles

Biofilm formation ability and tolerance to food-associated stresses among ESBL-producing Escherichia coli strains from foods of animal origin and human patients

The dissemination of extended-spectrum β-lactamase (ESBL)-producing Escherichia coli continues to be an important health concern, with the food production chain as a suggested reservoir. A collection of 31 strains, including ESBL-producing E. coli strains isolated from foods of animal origin and from human patients and reference collection strains, was evaluated regarding their biofilm formation ability, tolerance to food-associated stresses (heat, acid, non-thermal atmospheric plasma (NTAP) and UV-C light) and RpoS status. The most relevant phenotypic differences among strains were observed for biofilm formation and heat resistance, being related to the source of isolation (clinical vs food vs reference) or to the sequence type (ST131 vs other STs), while only minor differences were related to the occurrence of the ESBL genes (blaTEM, blaCTX-M, blaSHV). The biofilm formation ability on stainless steel was significantly higher for the field isolates, both clinical- and food-related, than for the reference strains. Food isolates were more thermotolerant (58 oC-1 and 2 min) than clinical isolates. Minor differences among strain categories were observed for their tolerance to the other inactivation technologies. Some polymorphisms in the rpoS gene sequences were detected, but loss-of-function mutations were not found, with the clustering of strains mainly based on their sequence type.

Induction of viable but nonculturable Salmonella spp. in liquid eggs by mild heat and subsequent resuscitation

Salmonella spp. is one of the leading causes of foodborne outbreaks worldwide. Salmonella spp. has been associated with a variety of food sources, particularly egg products. They can enter a viable but nonculturable (VBNC) state in response to harsh stress. VBNC cells still retain membrane integrity and metabolic activity, which may pose health risks. However, the formation mechanism and resuscitation ability of VBNC cells are not well understood. In this work, Salmonella spp. cocktails, including Salmonella enterica serovar Newport and Salmonella enterica serovar Enteritidis, in liquid egg products was induced into a VBNC state by mild heat treatment, a commonly used method to inhibit the growth of pathogenic in liquid egg industry. Mild heat induced VBNC cells were found to resuscitate in liquid egg yolk (LEY) and liquid whole egg (LWE), but they failed to recover in liquid egg white (LEW). In addition, a certain number of cells remained as VBNC state after in vitro digestion. The membrane vesicle (MV) protein encoding gene pagC, two-component system encoding genes phoP/Q and sigma factor encoding gene rpoS were highly expressed in VBNC cells compared with the culturable counterparts. The results of this study can contribute to a better understanding of the health risks associated with Salmonella spp. in VBNC state and provide a theoretical basis for formation mechanism of VBNC state.

Phenotypic and genotypic detection of Enterobacter spp isolated from food

The alternative sigma factor is essential for bacterial survival in harsh environments. Many Enterobacter spp. are opportunistic human pathogens, and their ability to adapt to changing environments may be critical to their virulence. These specialized sigma factors bind the promoters of genes appropriate to the environmental conditions and selectively increase the transcription of those genes. We used PCR to detected presence of RpoS, fimH and fimA genes in Enterobacter Cloacae Complex that isolated from food, (50%) of the isolates contain RpoS gene, (30%) of the isolates contain fimH and (20%) of the isolates contain fimA. RpoS was an important factor in cell control and bacterial persistence under stress conditions, and it contributed to virulence through a variety of mechanisms. Biofilm-producing bacteria were identified by the Congo Red Agar (CRA) method we obtained (50%) isolated of Enterobacter Cloacae Complex (ECC) formed Biofilm, according to laboratory investigations, 10 food samples in the current study contained Enterobacter spp. and were tested for antibiotic resistance. In our study, Amoixcillin-clavulanate and Ampicillin resistance was observed in all sample, while Imipenem and Levofloxacin showed high sensitivity.

Loss of rpoE Encoding the δ-Factor of RNA Polymerase Impacts Pathophysiology of the Streptococcus pyogenes M1T1 Strain 5448.

Streptococcus pyogenes, also known as the Group A Streptococcus (GAS), is a Gram-positive bacterial pathogen of major clinical significance. Despite remaining relatively susceptible to conventional antimicrobial therapeutics, GAS still causes millions of infections and hundreds of thousands of deaths each year worldwide. Thus, a need for prophylactic and therapeutic interventions for GAS is in great demand. In this study, we investigated the importance of the gene encoding the delta (δ) subunit of the GAS RNA polymerase, rpoE, for its impact on virulence during skin and soft-tissue infection. A defined 5448 mutant with an insertionally-inactivated rpoE gene was defective for survival in whole human blood and was attenuated for both disseminated lethality and lesion size upon mono-culture infection in mouse soft tissue. Furthermore, the mutant had reduced competitive fitness when co-infected with wild type (WT) 5448 in the mouse model. We were unable to attribute this attenuation to any observable growth defect, although colony size and the ability to grow at higher temperatures were both affected when grown with nutrient-rich THY media. RNA-seq of GAS grown in THY to late log phase found that mutation of rpoE significantly impacted (>2-fold) the expression of 429 total genes (205 upregulated, 224 downregulated), including multiple virulence and “housekeeping” genes. The arc operon encoding the arginine deiminase (ADI) pathway was the most upregulated in the rpoE mutant and this could be confirmed phenotypically. Taken together, these findings demonstrate that the delta (δ) subunit of RNA polymerase is vital in GAS gene expression and virulence.

Phylogenomic analysis of the genus Leuconostoc.

Leuconostoc is a genus of saccharolytic heterofermentative lactic acid bacteria that inhabit plant-derived matrices and a variety of fermented foods (dairy products, dough, milk, vegetables, and meats), contributing to desired fermentation processes or playing a role in food spoilage. At present, the genus encompasses 17 recognized species. In total, 216 deposited genome sequences of Leuconostoc were analyzed, to check the delineation of species and to infer their evolutive genealogy utilizing a minimum evolution tree of Average Nucleotide Identity (ANI) and the core genome alignment. Phylogenomic relationships were compared to those obtained from the analysis of 16S rRNA, pheS, and rpoA genes. All the phylograms were subjected to split decomposition analysis and their topologies were compared to check the ambiguities in the inferred phylogenesis. The minimum evolution ANI tree exhibited the most similar topology with the core genome tree, while single gene trees were less adherent and provided a weaker phylogenetic signal. In particular, the 16S rRNA gene failed to resolve several bifurcations and Leuconostoc species. Based on an ANI threshold of 95%, the organization of the genus Leuconostoc could be amended, redefining the boundaries of the species L. inhae, L. falkenbergense, L. gelidum, L. lactis, L. mesenteroides, and L. pseudomesenteroides. Two strains currently recognized as L. mesenteroides were split into a separate lineage representing a putative species (G16), phylogenetically related to both L. mesenteroides (G18) and L. suionicum (G17). Differences among the four subspecies of L. mesenteroides were not pinpointed by ANI or by the conserved genes. The strains of L. pseudomesenteroides were ascribed to two putative species, G13 and G14, the former including also all the strains presently belonging to L. falkenbergense. L. lactis was split into two phylogenetically related lineages, G9 and G10, putatively corresponding to separate species and both including subgroups that may correspond to subspecies. The species L. gelidum and L. gasicomitatum were closely related but separated into different species, the latter including also L. inhae strains. These results, integrating information of ANI, core genome, and housekeeping genes, complemented the taxonomic delineation with solid information on the phylogenetic lineages evolved within the genus Leuconostoc.

Mutation of rpoS is Beneficial for Suppressing Organic Acid Secretion During 1,3-Propandiol Biosynthesis in Klebsiella pneumoniae

In this study, to reduce the formation of organic acid during 1,3-propanediol biosynthesis in Klebsiella pneumoniae, a method combining UV mutagenesis and high-throughput screening with pH color plates was employed to obtain K. pneumoniae mutants. When compared with the parent strain, the total organic acid formation by the mutant decreased, whereas 1,3-propanediol biosynthesis increased after 24h anaerobic shake flask culture. Subsequently, genetic changes in the mutant were analyzed by whole-genome sequencing and verified by signal gene deletion. Mutation of the rpoS gene was confirmed to contribute to the regulation of organic acid synthesis in K. pneumoniae. Besides, rpoS deletion eliminated the formation of 2,3-butanediol, the main byproduct produced during 1,3-propanediol fermentation, indicating the role of rpoS in metabolic regulation in K. pneumoniae. Thus, a K. pneumoniae mutant was developed, which could produce lower organic acid during 1,3-propanediol fermentation due to an rpoS mutation in this study.

The predominance of Klebsiella pneumoniae carbapenemase (KPC-type) gene among high-level carbapenem-resistant Klebsiella pneumoniae isolates in Baghdad, Iraq.

The serine carbapenemase enzymes (KPC) which produce from bacteria klebsiella pneumoniae today have been emerged as one of the β-lactamase enzymes that is capable to inactivating the last line of carbapenems. The gene encoding the K. pneumonia (blaKPC) belongs to gene carried on plasmid among Enterobacteriaceae family, which has modulation for the infections control so this study is aimed to spot the presence and evaluate blaKPC gene expression by real-time PCR in local isolates of K. pneumonia. Forty-seven of K. pneumonia isolates were isolated from different clinical samples (blood, sputum, urine, wounds and burns) from patients in separate hospitals in Baghdad., Antimicrobial sensitivity test was carried out by vitik-2 system and Kirby- Bauer method. The PCR was employed to detect carbapenemase gene. The results of this study showed that all explored isolates were resistant to Ertapenem, Meropenem and imipenem 47(100%). Phenotypically, all the isolates had carbapenemase which hydrolyzed the carbapenem antibiotics. Furthermore, the isolates showed (100%) resistance to Cefazolin, Ampicillin and Amoxicillin/ Clavulic acid. However, the most effective antibiotic was Levofloxacin (91.5%). The results of conventional PCR technique for the detection of blaKPC gene showed that 38 (80.9%) isolates of carbapenem-resistant K. pneumoniae harboured blaKPC gene (1010bp), while none carried other carbapenemase genes including blaNDM1, blaVIM and blaIMP genes. High levels of carbapenem resistance was clarified by the imipenem and meropenem MICs determination. All 38 isolates were positive in CNPT. Furthermore, the 38 isolates showed over expression of blaKPC gene compared with housekeeping rpo gene in Real-Time PCR. According to these results, the resistant isolates to carbapenem were belong to the present and high level expression of blaKPC gene in our local isolates.

Latilactobacillus fragifolii sp. nov., isolated from leaves of a strawberry plant (Fragaria x ananassa).

Thirteen Gram-positive, catalase-positive, rod-shaped single colonies were obtained after culturing a strawberry leaf on de Man–Rogosa–Sharpe agar. Based on 16S rRNA gene and rpoA gene sequence similarities, ranging between 99.0–100% and 96.5–100%, respectively, the 13 isolates were found to be closely related to each other. Two of the independent isolates, AMBP162T and AMBP252, were whole-genome sequenced, and showed to be undistinguishable with an average nucleotide identity (ANI) value of 100 %. Compared to the reference genomes for all species in the family Lactobacillaceae , the AMBP162T genome was most similar to the reference strain of Latilactobacillus curvatus with ANI of only 89.5 %, indicating they were a different species. Based on genotypic and phenotypic data, a novel Latilactobacillus species, Latilactobacillus fragifolii sp. nov., with the type strain AMBP162T (=LMG 32285T=CECT 30357T) is proposed.

Lamium cappadocicum, a new species from Central Anatolia, Turkey: evidence from molecular and morphological studies

Lamium is a taxonomically convoluted genus of about 34 species. Within Lamium, the L. garganicum species complex is particularly challenging. Here, based on morphological and molecular studies, Lamium cappadocicum Celep & Karaer sp. nova (Lamiaceae) is separated from L. garganicum and L. bilgilii and described as a new species, and L. garganicum subsp. rectum (= L. garganicum subsp. pulchrum) is resurrected. The new species is only known from the Hasan Mountain (Aksaray) in Central Anatolia, Turkey. Lamium cappadocicum is closely related to L. garganicum subsp. rectum but differs from it by its mat-forming caespitose habit, reniform (rarely ovate in upper part) and deeply cordate leaves with dense white villous hairs, deeply crenate and undulate leaf margins, subglabrous to sparsely pilose stems, and densely white villous calyces. Lamium cappadocicum also differs from L. bilgilii by its matforming caespitose habit, smaller corollas (25-33 mm versus 40-52 mm in L. bilgilii), subglabrous to sparsely pilose stems and smaller leaves (3-20 (-30) mm long × 3-20 (-30) mm wide, versus 5-45 mm long × 5-45 mm wide in L. bilgilii). Molecular phylogenetic analyses from nuclear ribosomal (nrITS) and chloroplast (matK, rpoA and psbA-trnH) gene regions support the morphological results. The IUCN conservation status, ecology, phenology, etymology, and notes on biogeography of the new species are also given and diagnostic features are discussed.

Disrupting Biofilm Formation and Antibiotic Resistance in Pseudomonas aeruginosa Using Phage-Delivered Sensitivity Cassettes: A Research Protocol

Introduction: Despite antimicrobial resistance topping the list of global health concerns, the development of novel antibiotics has been nearly abandoned due to strict regulations and dwindling economic incentives in the pharmaceutical industry. There is a critical need for alternative strategies to treat multidrug resistant pathogens like Pseudomonas aeruginosa, a pestilent cause of nosocomial infections. Here, we aim to target adaptive resistance in P. aeruginosa biofilms by inducing hypersensitivity to existing antibiotics through phage-delivery of a particular gene cassette. Previous studies have suggested that the rpoS gene is repressed in P. aeruginosa biofilms and that its deletion is correlated with hypervirulence, increased biofilm thickness and antibiotic resistance. Methods: In this protocol, we aim to explore the effect of inducing rpoS overexpression in P. aeruginosa colonies as a potential method to disrupt biofilm structure and increase sensitivity to tobramycin. Phagemids containing rpoS, an accompanying promoter, and a tellurite resistance gene are delivered by P1 bacteriophages to the biofilm to be shared through horizontal gene transfer (HGT). Tellurite is then administered to induce selective pressure for HGT, by favouring uptake of the phagemids due to the presence of the tellurite resistance gene. Consequently, we can assess the effect of rpoS overexpression on biofilm organization and tobramycin sensitivity using measures from confocal laser scanning microscopy (CLSM). Anticipated Results: Given the hypervirulent effects of rpoS deletion, we expect that forcing rpoS overexpression in P. aeruginosa would result in decreased biofilm thickness compared to controls. Furthermore, the colonies are also expected to have lower cell viability following tobramycin administration. Discussion: Overall, our experiment characterizes the effects of rpoS overexpression on biofilm thickness, cell viability and tobramycin resistance. As such, this protocol may have practical implications for re-sensitization of P.aeroginosa to antibiotics. Conclusion: This would demonstrate a potential for phage-mediated hypersensitization of P. aeruginosa that is adaptable to more practical settings, such as in situ on hospital surfaces.

Paclitaxel and its derivative facilitate the transmission of plasmid-mediated antibiotic resistance genes through conjugative transfer

The rapid dissemination of antibiotic resistance by horizontal gene transfer (HGT) renders the global resistance crisis more tense and urgent as few effective antimicrobials are available to combat multidrug-resistant (MDR) pathogens at present. Conjugation is one of the most dominant and representative pathways of HGT. Antibiotic residue in environment is recognized as an important accelerator for conjugal transfer, whereas the roles of non-antibiotic pharmaceuticals in this process are not fully understood. Here we found that environmentally relevant concentrations of paclitaxel as well as its derivative docetaxel, two commonly used anticancer drugs, remarkably facilitated the conjugative transfer of resistance plasmids carrying multiple antibiotic resistance genes (ARGs). The underlying mechanisms accounting for the enhanced conjugation were investigated by detecting the activity of RpoS regulon, membrane permeability, SOS response and gene expression of conjugative transfer systems. Our results showed that paclitaxel induced a series of cellular responses, including up-regulation of rpoS expression, activated SOS response, increased cell membrane permeability, enhanced plasmid replication and mating pilus formation. Collectively, our data provide new insight on the roles of paclitaxel and its derivative in promoting the conjugal transfer of ARGs, highlighting the importance of good antimicrobial stewardship.

Variation in genomic traits of microbial communities among ecosystems.

Free-living bacteria in nutrient limited environments often exhibit traits which may reduce the cost of reproduction, such as smaller genome size, low GC content and fewer sigma (σ) factor and 16S rRNA gene copies. Despite the potential utility of these traits to detect relationships between microbial communities and ecosystem-scale properties, few studies have assessed these traits on a community-scale. Here, we analysed these traits from publicly available metagenomes derived from marine, soil, host-associated and thermophilic communities. In marine and thermophilic communities, genome size and GC content declined in parallel, consistent with genomic streamlining, with GC content in thermophilic communities generally higher than in marine systems. In contrast, soil communities averaging smaller genomes featured higher GC content and were often from low-carbon environments, suggesting unique selection pressures in soil bacteria. The abundance of specific σ-factors varied with average genome size and ecosystem type. In oceans, abundance of fliA, a σ-factor controlling flagella biosynthesis, was positively correlated with community average genome size-reflecting known trade-offs between nutrient conservation and chemotaxis. In soils, a high abundance of the stress response σ-factor gene rpoS was associated with smaller average genome size and often located in harsh and/or carbon-limited environments-a result which tracks features observed in culture and indicates an increased capacity for stress response in nutrient-poor soils. This work shows how ecosystem-specific constraints are associated with trade-offs which are embedded in the genomic features of bacteria in microbial communities, and which can be detected at the community level, highlighting the importance of genomic features in microbial community analysis.

The complete chloroplast genome sequence of Melampyrum koreanum (Orobanchaceae), an endemic and hemi-parasitic herb in Korea

Melampyrum koreanum K.-J. Kim and S.-M. Yun 2012 (Orobanchaceae) is a hemi-parasitic herb, endemic to Korea. Here, the chloroplast genome of this species is reported. It was found to be 143,865 bp long, with a large single-copy region of 83,133 bp, a small single-copy region of 10,308 bp, and a pair of inverted repeat regions of 25,212 bp each. The chloroplast genome harbors 124 genes, including 79 protein-coding genes, 37 transfer RNA genes, and eight ribosomal RNA genes. Among the identified genes, rpoA and several ndh genes were determined to be pseudogenized due to the stop codon in the middle of the gene. The phylogenetic tree of the family was reconstructed based on 20 protein-coding genes, conserved across studied taxa. As a result, Melampyrum L. 1753 species were found to form a monophyletic group in the family.

σS-Mediated Stress Response Induced by Outer Membrane Perturbation Dampens Virulence in Salmonella enterica serovar Typhimurium.

Salmonella alters cellular processes as a strategy to improve its intracellular fitness during host infection. Alternative σ factors are known to rewire cellular transcriptional regulation in response to environmental stressors. σs factor encoded by the rpoS gene is a key regulator required for eliciting the general stress response in many proteobacteria. In this study, Salmonella Typhimurium deprived of an outer membrane protein YcfR was attenuated in intracellular survival and exhibited downregulation in Salmonella pathogenicity island-2 (SPI-2) genes. This decreased SPI-2 expression caused by the outer membrane perturbation was abolished in the absence of rpoS. Interestingly, regardless of the defects in the outer membrane integrity, RpoS overproduction decreased transcription from the common promoter of ssrA and ssrB, which encode a two-component regulatory system for SPI-2. RpoS was found to compete with RpoD for binding to the PssrA region, and its binding activity with RNA polymerase (RNAP) to form Eσs holoenzyme was stimulated by the small regulatory protein Crl. This study demonstrates that Salmonella undergoing RpoS-associated stress responses due to impaired envelope integrity may reciprocally downregulate the expression of SPI-2 genes to reduce its virulence.

Rejection of the reclassification of Leuconostoc gasicomitatum as Leuconostoc gelidum subsp. gasicomitatum based on whole genome analysis.

In 2014, Rahkila et al. transferred Leuconostoc gasicomitatum to Leuconostoc gelidum as L. gelidum subsp. gasicomitatum comb. nov. based on a 75 % DNA-DNA hybridization value. In the present study, the taxonomic status of L. gelidum subsp. gasicomitatum is re-evaluated by a polyphasic approach, including 16S rRNA, pheS, rpoA, recA, and atpA gene sequence analyses, phylogenomic treeing, analyses of ANI (average nucleotide identity) and dDDH (digital DNA-DNA hybridization), fatty acid methyl ester analysis and a phenotypic characterization. On the basis of the ANI and dDDH values, we propose to reject the proposal of Rahkila et al. to reclassify L. gasicomitatum as L. gelidum subsp. gasicomitatum.

Biofilm formation by Non-O157 Shiga toxin-producing Escherichia coli in monocultures and co-cultures with meat processing surface bacteria

This study investigated the impact of meat processing surface bacteria (MPB) on biofilm formation by non-O157 Shiga toxin-producing Escherichia coli (STEC), and potential links between biofilm formation by STEC and biofilm-related genes in their genomes. Biofilm development by 50 MPB and 6 STEC strains in mono- and co-cultures was assessed by the crystal violet staining method, and their expression of curli and cellulose was determined using the Congo red agar method. Genes (n = 141) associated with biofilm formation in the STEC strains were profiled. Biofilm formation in general correlated with cellulose and curli expression in both mono- and co-cultures. Most MPB strains had antagonistic effects on the biofilm formation of the STEC strains. Of the genes investigated, 81% were common among the STEC strains and there seems to be a gene-redundancy in biofilm formation. The inability of the O26 strain to form biofilms could be due to mutations in the rpoS gene. Truncation in the mlrA gene in the O145 strain seems not affecting its biofilm formation alone or with MPB. The O45 strain, despite having the greatest number of biofilm-related genes, did not form measurable biofilms. Overall, biofilm formation of STEC was affected by curli-cellulose expression and companion strains.

Persistence of Salmonella enterica and Enterococcus faecium NRRL B-2354 on Baby Spinach Subjected to Temperature Abuse after Exposure to Sub-Lethal Stresses.

The exposure of foodborne pathogens such as Salmonella enterica to a sub-lethal stress may protect bacterial cells against distinct stresses during the production of leafy greens, which can constitute potential health hazards to consumers. In this study, we evaluated how the prior exposure of S. enterica to sub-lethal food processing-related stresses influenced its subsequent persistence on baby spinach under cold (4 °C for 7 days) and temperature abuse (37 °C for 2 h + 4 °C for 7 days) conditions. We also compared the survival characteristics of pre-stressed S. enterica and Enterococcus faecium NRRL B-2354 as its surrogate on baby spinach. A cocktail of three S. enterica serovars, as well as S. Typhimurium ATCC 14028 wild type and its ΔrpoS mutant, and E. faecium NRRL B-2354, was first exposed to sub-lethal desiccation, oxidation, heat shock, and acid stresses. Afterward, baby spinach was inoculated with unstressed or pre-stressed cells at 7.0 log CFU/sample unit, followed by 7-day storage under cold and temperature abuse conditions. The unstressed S. enterica (fresh cells in sterile 0.85% saline) decreased rapidly within the first day and thereafter persisted around 5.5 log CFU/sample unit under both conditions. The desiccation-stressed S. enterica showed the highest bacterial counts (p < 0.05) compared to other conditions. The unstressed S. enterica survived better (p < 0.05) than the oxidation- and acid-stressed S. enterica, while there were no significant differences (p > 0.05) between the unstressed and heat-shocked S. enterica. Unlike the wild type, temperature abuse did not lead to the enhanced survival of the ΔrpoS mutant after exposure to desiccation stress, indicating that the rpoS gene could play a critical role in the persistence of desiccation-stressed S. enterica subjected to temperature abuse. E. faecium NRRL B-2354 was more persistent (p < 0.05) than the pre-stressed S. enterica under both conditions, suggesting its use as a suitable surrogate for pre-stressed S. enterica by providing a sufficient safety margin. Our results demonstrate the merit of considering the prior exposure of foodborne pathogens to sub-lethal stresses when validating the storage conditions for leafy greens.

Inhibitory effect of modified atmosphere packaging on Escherichia coli O157:H7 in fresh-cut cucumbers (Cucumis sativus L.) and effectively maintain quality during storage

Modified atmosphere packaging (MAP) can inhibit microbial growth and prolong shelf life of fresh-cut cucumbers. This study compared the effects of different packaging gases on the growth of E. coli O157:H7 and sensory characteristics of fresh-cut cucumbers. Changes in key movement, adhesion, and oxidative stress genes expression of strain under optimal MAP and air were determined. Cell population density, the extracellular carbohydrate complex content and expression of curli fimbriae were evaluated. Results revealed that the growth of E. coli O157:H7 in fresh-cut cucumbers could be effectively inhibited under MAP (atmosphere = 2% O2, 7% CO2, 91% N2), and better maintained the sensory characteristics. Furthermore, the inhibition mechanism was revealed by inhibiting the expression of movement (fliC), adhesion (eaeA) and oxidative stress (rpoS and sodB) genes in E. coli O157:H7, reducing biofilm formation, extracellular carbohydrate production and curli fimbriae expression. Proper MAP can maintain the quality and safety of fresh-cut cucumbers.

Proposal of Lactococcus garvieae subsp. bovis Varsha and Nampoothiri 2016 as a later heterotypic synonym of Lactococcus formosensis Chen et al. 2014 and Lactococcus formosensis subsp. bovis comb. nov.

Currently, Lactococcus garvieae contains two subspecies: L. garvieae subsp. bovis and L. garvieae subsp. garvieae. In a study by Varsha and Nampoothiri, high pheS (99.7 %) and rpoA (99.6 %) sequence similarities indicated that L. garvieae subsp. bovis and Lactococcus formosensis probably have a close taxonomic relationship; low pheS (92.2 %) and rpoA (97.8 %) sequence similarities and relatively low DNA-DNA hybridization value (75.8 %) indicated that L. garvieae subsp. bovis and L. garvieae subsp. garvieae probably represent two different species. In the present study, the taxonomic relationships between L. garvieae subsp. bovis, L. garvieae subsp. garvieae and L. formosensis were re-examined based on sequence analyses of 16S rRNA, pheS, recA, rpoA and rpoB genes, average nucleotide identity (ANI), digital DNA-DNA hybridization (dDDH) values, average amino acid identity (AAI), fatty acid methyl ester analysis and phenotypic characterization. L. garvieae subsp. bovis LMG 30663T exhibited 97.3 % ANI, 78.3 % dDDH and 96.4 % AAI values to L. formosensis NBRC 109475T, higher than the threshold for species demarcation (95-96, 70 and 95-96 %, respectively), indicating that L. garvieae subsp. bovis LMG 30663T and L. formosensis NBRC 109475T belong to the same species. L. garvieae subsp. bovis LMG 30663T had 91.2 % ANI, 43.3 % dDDH and 92.9-93.0% AAI values with the type strain of L. garvieae subsp. garvieae, indicating that they represent two different species. Because L. formosensis has been proposed and validated before L. garvieae subsp. bovis, L. garvieae subsp. bovis is transferred to L. formosensis as L. formosensis subsp. bovis comb. nov. The type strain of L. formosensis subsp. bovis is BSN307T (=DSM 100577T=MCC 2824T=KCTC 21083T=LMG 30663T). The type strain of L. formosensis subsp. formosensis is 516T (=NBRC 109475T=BCRC 80576T).

Novel Insight into the Effects of CpxR on Salmonella enteritidis Cells during the Chlorhexidine Treatment and Non-Stressful Growing Conditions.

The development and spread of antibiotics and biocides resistance is a significant global challenge. To find a solution for this emerging problem, the discovery of novel bacterial cellular targets and the critical pathways associated with antimicrobial resistance is needed. In the present study, we investigated the role of the two most critical envelope stress response regulators, RpoE and CpxR, on the physiology and susceptibility of growing Salmonella enterica serovar enteritidis cells using the polycationic antimicrobial agent, chlorhexidine (CHX). It was shown that deletion of the cpxR gene significantly increased the susceptibility of this organism, whereas deletion of the rpoE gene had no effect on the pathogen’s susceptibility to this antiseptic. It has been shown that a lack of the CpxR regulator induces multifaceted stress responses not only in the envelope but also in the cytosol, further affecting the key biomolecules, including DNA, RNA, and proteins. We showed that alterations in cellular trafficking and most of the stress responses are associated with a dysfunctional CpxR regulator during exponential growth phase, indicating that these physiological changes are intrinsically associated with the lack of the CpxR regulator. In contrast, induction of type II toxin-antitoxin systems and decrease of abundances of enzymes and proteins associated with the recycling of muropeptides and resistance to polymixin and cationic antimicrobial peptides were specific responses of the ∆cpxR mutant to the CHX treatment. Overall, our study provides insight into the effects of CpxR on the physiology of S. Enteritidis cells during the exponential growth phase and CHX treatment, which may point to potential cellular targets for the development of an effective antimicrobial agent.