Global ETD Search

1	Characterization of The Viable but Non-Culturable Legionella pneumophila in Water and the Role of 3-Hydroxybutyrate Dehydrogenase in Its Formation Al-Bana, Badii 16 September 2013 (has links) Legionella pneumophila, the causative agent of Legionnaires’ disease (LD), is an intracellular pathogen of freshwater protozoa that can also persist in the environment as a free-living bacterium. L. pneumophila has many morphological forms that fit within a developmental cycle. In water, L. pneumophila enters into a viable but non-culturable (VBNC) state that is largely uncharacterized. VBNC cells were produced from two developmental L. pneumophila forms, stationary phase forms (SPFs) and mature infectious forms (MIFs) by suspension in double deionized (dd) or tap-water at 45°C. Electron microscopy results showed that VBNC cells have a unique morphology and that in tap water they lose their poly 3-hydroxybutyrate inclusion bodies. Both SPFs and MIFs lost culturability faster in dd- than in tap water, and addition of salts to dd-water prolonged L. pneumophila culturability and enhanced viability. However, MIFs retained higher viability in dd- and tap water (85% and 51%, respectively) than SPFs (5% and 20%, respectively) as determined by the BacLight vital stain. Only ~1 VBNC cell out of 105 of those produced from SPFs in tap water regained culturability via infection of Acanthamoeba. All VBNC cells, except for those produced from SPFs in dd-water, resisted both digestion inside Tetrahymena spp. and detergent-mediated lysis. SDS-PAGE analysis and shotgun proteomics revealed a number of VBNC cell specific proteins; one of these was 3-hydroxybutyrate dehydrogenase (BdhA), which is involved in the metabolism of poly 3-hydroxybutyrate inclusion bodies. A bdhA mutant showed an early loss of culturability and a dramatic decrease in viability as compared to the parent strain, and complementing the mutant with a functional bdhA gene restored the parent's strain phenotypes. In conclusion, VBNC L. pneumophila has a distinct morphology and physiology that varies according to the developmental stage and the environmental conditions used to produce such VBNC cells. VBNC cells have a different protein profile and morphology than the culturable cells, suggesting that this state constitutes a distinct differentiated form within the developmental cycle of L. pneumophila. BdhA seems to influence L. pneumophila survival and hence VBNC cell formation. Collectively, the results from this study provide a better understanding of L. pneumophila VBNC form and the factors influencing its formation.
2	Transport of viable but non-culturable Escherichia coli O157:H7 in soil and groundwater Kartz, Cory Unknown Date No description available. E.coli O157:H7 VBNC Transport Soil Groundwater
3	Transport of viable but non-culturable Escherichia coli O157:H7 in soil and groundwater Kartz, Cory 11 1900 (has links) The influence of the viable but non-culturable (VBNC) state on specific phenotypic traits of Escherichia coli O157:H7 as well as its transport behaviour in porous media was examined in this study. E.coli O157:H7 is a human pathogen capable of entering a VBNC state following exposure to sublethal stress. In the VBNC state, E.coli O157:H7 is not detectable by culture assays; yet, is able to retain its ability to cause human illness. This study examined specific transport-related properties of culturable and VBNC E.coli O157:H7 cells. As well, transport behaviors of the two cellular states were compared using sand-packed columns under steady-state flow. When E.coli O157:H7 cells entered a VBNC state, significant decreases in the hydrophobicity and lengths/widths of the cells, and a significant increase in extracellular polymeric substances on the cell surfaces were measured. Transport experiments indicated significantly (p<0.05) greater mass transport of VBNC cells through unwashed sand compared to culturable cells. This research contributes to the current knowledge describing VBNC E.coli O157:H7 cells, raises questions concerning the accuracy of culture-based E.coli O157:H7 identification protocols, and suggests that bacteria transport in the subsurface is a truly dynamic process. / Soil Science E.coli O157:H7 VBNC Transport Soil Groundwater
4	Caractérisation d’une phase de persistance intracellulaire du pathogène Listeria monocytogenes / Characterization of an intracellular persistence stage on the pathogen Listeria monocytogenes Kortebi, Mounia 21 November 2018 (has links) Listeria monocytogenes est une bactérie pathogène intracellulaire facultative responsable d’une pathologie grave, la listériose. Si de très nombreux travaux ont permis de caractériser les mécanismes de virulence de cette bactérie, il existe peu de données sur les mécanismes conduisant au portage asymptomatique de L. monocytogenes dans les hôtes mammifères. L’un de ces mécanismes pourrait être une phase de persistance intracellulaire. Lors d’infections prolongées de cellules épithéliales humaines en culture, comme des hépatocytes et des cellules de trophoblastes, L. monocytogenes change de mode de vie intracellulaire. Après la phase active de dissémination de cellule en cellule, les bactéries arrêtent de polymériser l’actine et se retrouvent piégées dans des vacuoles à simple membrane marquées par la protéine endosomale LAMP1. L’objectif de ma thèse était de caractériser ces « Listeria-Containing Vacuoles » (LisCVs). Nous avons montré que les LisCVs sont des compartiments acides, partiellement-dégradatifs, marquées par la protéase lysosomale cathépsine D. Leur formation coïncide avec la disparition du facteur de polymérisation d’actine ActA de la surface bactérienne et la capture des bactéries cytosoliques dépourvues d’actine par des membranes cellulaires. Dans ces compartiments, les bactéries entrent en croissance ralentie ; une sous-population résiste aux stress et peut survivre au-delà de trois jours d’infection. L’utilisation de la gentamicine lors du protocole d’infection n’est pas responsable de la formation des LisCVs. Cependant, cet antibiotique permet la sélection des bactéries vacuolaires, en inhibant spécifiquement la croissance des bactéries cytosoliques. La formation des LisCVs n’est pas spécifique des souches de laboratoire. Toutefois l’efficacité du phénomène pourrait diverger selon les séquençotypes des souches de L. monocytogenes. Les bactéries vacuolaires ont la capacité de sortir des vacuoles et de retourner vers un état motile et réplicatif, après le passage des cellules infectées. Lorsque l’expression du gène actA reste inactive, comme dans les mutants ∆actA, des formes de Listeria vacuolaires persistent dans les cellules hôtes dans un état viable mais non cultivable (VBNC). Ces formes VBNC peuvent être transmises au cours des divisions des cellules hôtes. L’ensemble de ces résultats révèle une nouvelle phase de persistance dans le processus infectieux intracellulaire de L. monocytogenes lors des infections prolongées de certaines cellules épithéliales. Cette propriété pourrait contribuer au portage asymptomatique de ce pathogène dans les tissus épithéliaux, allonger la période d'incubation de la listériose, et rendre les bactéries tolérantes à l’antibiothérapie. / Listeria monocytogenes is a facultative intracellular pathogenic bacterium responsible for a serious disease, listeriosis. Although much work has been done to characterize the virulence mechanisms of this bacterium, there is little data on the mechanisms leading to the asymptomatic carriage of L. monocytogenes in mammalian hosts. One of these mechanisms could be a phase of intracellular persistence. During prolonged infections of human epithelial cells in culture, such as hepatocytes and trophoblast cells, L. monocytogenes changes its intracellular lifestyle. After the active phase of cell-to-cell spread, the bacteria stop polymerizing actin and become trapped in single-membrane vacuoles labeled with the endosomal protein LAMP1.The aim of my thesis was to characterize these "Listeria-Containing Vacuoles" (LisCVs). We have shown that LisCVs are acidic, partially degradative compartments, labeled by the lysosomal protease cathepsin D. Their formation coincides with the disappearance of actin polymerization factor ActA from the bacterial surface and the capture of actin-free cytosolic bacteria by cell membranes. In these compartments, bacterial growth is slowed; a subpopulation is resistant to stress and can survive beyond three days of infection. The use of gentamicin during the infection protocol is not responsible for the formation of LisCVs. However, this antibiotic allows selection of vacuolar bacteria, by specifically inhibiting the growth of cytosolic bacteria. The formation of LisCVs is not specific to laboratory strains. However, the efficacy of the phenomenon could diverge according to the sequence types of L. monocytogenes strains. Vacuolar bacteria have the ability to exit the vacuoles and return to a motile and replicative state during the subculture of infected cells. When expression of the actA gene remains inactive, as in ΔactA mutants, vacuolar Listeria forms persist in host cells in a viable but non-culturable (VBNC) state. These VBNC forms can be transmitted during host cell divisions. All these results reveal a new phase of persistence in the intracellular infectious process of L. monocytogenes during prolonged infections of a subset of epithelial cells. This property could contribute to asymptomatic carriage of this pathogen in epithelial tissues, extend the incubation period of listeriosis, and make bacteria tolerant to antibiotic therapy. Listeria monocytogenes Persistance VBNC Vacuoles Pathogène intracellulaire Listériose Listeria monocytogenes Persistence VBNC Vacuoles Intracellular pathogen Listeriosis
5	A study of the coccoid form and the autolysins of <i>Campylobacter upsaliensis</i> Santiwatanakul, Somchai 13 May 1998 (has links) Conversion of <i>Campylobacter upsaliensis</i> to the nonculturable but viable coccoid form was characterized. Chloramphenicol did not prevent the conversion. Severe decreases in isocitrate dehydrogenase activity and oxygen uptake and extensive degradation of ribosomal RNA suggest that the coccoid form is a degenerative form rather than part of a life cycle. The autolysins of spiral and coccoid forms of <i>C. upsaliensis</i> were also studied. Autolytic activity in the soluble and sediment fractions of sonicates of the spiral and the coccoid form of <i>C. upsaliensis</i> could not be demonstrated by native (nondenaturing) PAGE. Autolysins were detected, however, by using denaturing SDS-PAGE gels containing either purified <i>E. coli </i> peptidoglycan or whole cells of <i>Micrococcus luteus</i> as the turbid substrate, with subsequent renaturation by treatment with Triton X-100 buffer. In renaturing gels that contained <i>E. coli</i> peptidoglycan, 14 autolytic bands were detected ranging from 200 kDa to 12 kDa. In similar gels containing whole cells of <i>M. luteus</i> , only a single band appeared having a molecular weight of 34 kDa. This band corresponded to one of the bands present in the gels containing <i>E. coli </i> peptidoglycan. This common autolysin was isolated by adsorbing it from <i>C. upsaliensis</i> lysates onto <i>M. luteus</i> cells and then subjecting these cells to renaturing SDS-PAGE in gels containing <i>E. coli</i> peptidoglycan. The 34 kDa autolysin differed from a single 51 kDa autolysin unique to the <i>M. luteus cells</i>. The 34 kDa autolysin was isolated from an SDS-PAGE gel and was pure when tested by isoelectric focusing. The N-terminal amino acid sequence analysis showed the first 15 amino acids of the 34 kDa autolysin to have 67% identity with a part of antigenic protein PEB4 of <i>Campylobacter jejuni</i>. The purified autolysin was used to immunize rabbits and the antibodies produced precipitated autolytic activity from cell lysates. The specificity of the antibodies was shown by Western blotting: only a single specific band occurred, with a molecular weight of 34 kDa, and thus it seems unlikely that the 34 kDa autolysin was derived from any of the other autolysins that were detected. / Ph. D. zymogram murein hydrolase VIABLE BUT NONCULTURABLE VBNC Campylobacter upsaliensis autolysin
6	A Study of the Coccoid Bodies of Prolinoboborus fasciculus (Aquaspirillum fasciculus) Koechlein, David Jacob 11 November 1998 (has links) Following active growth, the aquatic gram-negative rod Prolinoborus fasciculus (Aquaspirillum fasciculus) exhibited a mass conversion from its culturable rod form to a nonculturable coccoid form. Chloramphenicol did not prevent the conversion. Attempts to obtain variants that would not convert to the coccoid form were unsuccessful. Although the coccoid form fluoresced with acridine orange, agarose gel electrophoresis revealed extensive ribosomal RNA degradation. Poly-Ã -hydroxybutyrate, abundant in the vegetative rods, was not detectable in the coccoid cells. The results suggest that the coccoid form of A. fasciculus is a degenerative form rather than part of a life cycle. / Master of Science RNA acridine orange Viable but nonculturable coccoid bodies VBNC
7	Étude de la survie et de la viabilité de Listeria monocytogenes dans les effluents d’élevages porcins / Study of the survival and viability of Listeria monocytogenes in effluent from pig farms Desneux, Jérémy 07 December 2015 (has links) La listériose est une maladie rare mais grave d’origine alimentaire provoquée par Listeria monocytogenes. En raison de sa capacité de survie importante dans les sols, la présence de cette bactérie dans les effluents d’élevages porcins destinés à être épandus constitue un problème de santé publique. L’un des facteurs pouvant expliquer la persistance de L. monocytogenes dans l’environnement est sa capacité à entrer dans un état viable mais non cultivable (VNC). Nos travaux avaient pour objectif, d’une part de suivre le comportement de L. monocytogenes dans les effluents d'élevages porcins (lisier et effluent de lagune) et notamment les formes VNC, et d’autre part d’étudier son adaptation lors de son transfert dans les effluents de lagune et dans le sol. Dans un premier temps, nous avons optimisé les conditions de la qPCR couplée au propidium monoazide (qPCR-PMA) afin d’adapter cette méthode au dénombrement des formes VNC de L. monocytogenes dans le lisier et l’effluent de lagune. Dans un second temps, nous avons comparé par méthode culturale, qPCR-PMA et qPCR, la survie de deux souches de L. monocytogenes RifR de sérogroupes IIb et IVb inoculées dans deux lisiers et dans deux effluents de lagune incubés à 8°C et 20°C. Malgré leur origine et leur sérotype différents, les deux souches ont présenté une survie similaire dans toutes les conditions testées. La survie des deux souches a été affectée par la température (une persistance plus élevée a été observée à 8°C) et par l’origine des effluents. Cette étude a mis en évidence que L. monocytogenes était capable d’entrer dans l’état VNC dans les lisiers et les effluents de lagune indépendamment de la température. Les formes VBNC qui représentaient 83 à 99,8% des bactéries viables après 60 jours d’incubation, sont apparues dès les premières heures de contact avec les effluents. Leur proportion, plus élevée en début d’expérience dans les lisiers que dans les effluents de lagune, était cependant du même ordre de grandeur dans les deux types de matrices après 60 jours. Afin de mieux comprendre l’adaptation de L. monocytogenes lors de son transfert dans l’effluent de lagune et dans le sol, nous avons comparé le transcriptome par la technologie RNA-seq de la souche CIP 110868, isolée d’un lisier, inoculée dans des extraits stériles d’effluent de lagune et de sol. L’analyse du transcriptome a été réalisée à T0 (génome de référence), après 20 minutes et 20 heures d’incubation. L’analyse par enrichissement fonctionnel a révélé des modifications transcriptomiques dès les 20 premières minutes d’incubation dans les deux matrices. Une augmentation du taux de transcrit de gènes impliqués dans le transport de protéines et de sucres a été observée. Le taux de transcrit des gènes contrôlés par le facteur sigmaB est augmenté indiquant la mise en place d’une réponse aux stress osmotiques et thermiques. De plus, l’adaptation de la souche CIP 110868 dans les extraits de sol et d’effluent de lagune s’est accompagnée d’une augmentation au cours du temps des taux de transcrit des gènes impliqués dans la virulence et des gènes sous le contrôle du régulateur prfA. / Listeriosis is a rare but serious illness caused by foodborne Listeria monocytogenes. Because of its important survival capacity in the soil, the presence of this bacteria in effluent from pig farms intended to be spread is a public health problem. One factor that may explain the persistence of L. monocytogenes in the environment is its ability to enter a viable but non-culturable state (VNC). Our studies were aimed, firstly to monitor the behavior of L. monocytogenes in effluent from pig farms (manure and lagoon effluent) including VNC forms, and also to study its adaptation at transfer to the lagoon effluent and soil. First, we have optimized the conditions of qPCR coupled with propidium monoazide (qPCR-LDCs) to adapt this method to count VNC forms of L. monocytogenes in the manure and lagoon effluent. Secondly, we compared by cultivation method, qPCR and qPCR-LDCs, the survival of two strains of L. monocytogenes RifR IIb and IVb serogroups manure inoculated in two and two lagoon effluent incubated at 8 ° C and 20 ° C. Despite their origin and different serotype, the two strains showed a similar survival in all conditions tested. The survival of both strains was affected by the temperature (higher persistence was observed at 8 ° C) and the origin of the effluent. This study showed that L. monocytogenes was able to enter the VNC state in manure and lagoon effluent regardless of temperature. VBNC forms which accounted for 83 99.8% of viable bacteria after 60 days of incubation, appeared in the early hours of contact with effluent. Their proportion, higher at the beginning of experience in the manure lagoon in the effluent, however, was of the same order of magnitude in the two types of matrices after 60 days. To better understand the adaptation of L. monocytogenes when transferred into the lagoon effluent and soil, we compared the transcriptome by RNA-Seq technology CIP 110868 strain, isolated from a slurry inoculated in sterile effluent lagoon and extracts of soil. Transcriptome analysis was performed at T0 (reference genome), after 20 minutes and 20 hours of incubation. Functional enrichment analysis revealed transcriptomic changes during the first 20 minutes of incubation in both matrices. An increase in the gene transcript levels involved in the transport of proteins and sugars was observed. The rate of transcribed genes controlled by the sigmaB factor is increased indicating the establishment of a response to osmotic and thermal stress. In addition, the adaptation of the CIP 110868 strain in soil extracts and lagoon effluent was accompanied by an increase in time of transcript levels of genes involved in virulence and gene under the control the prfA regulator. L. monocytogenes Persistance Effluents d’élevages porcins Vbnc Régulation transcriptionnelle L. monocytogenes Persistance Effluents d’élevages porcins Vbnc Régulation transcriptionnelle
8	Suivi de l'état viable non cultivable de souches de Legionella pneumophila soumises à différents stress (thermique ou chloré) : Evaluation de leur pouvoir pathogène / Monitoring state of viable but non culturable legionella pneumophila strains after different stress (heat shock or chlorine treatment) : Evaluation of their pathogenicity Epalle, Thibaut 09 February 2015 (has links) Legionella pneumophila, l’agent responsable de la légionellose est transmissible à l’Homme par les aérosols environnementaux et infecte les macrophages pulmonaires. Après l’exposition à différents stress L. pneumophila est capable de d’entrer dans un état Viable Non Cultivable (VBNC) qui semble être une stratégie de survie. L’objectif de nos travaux était d’étudier l’état VBNC de différentes souches de L. pneumophila après des traitements thermique et chimique et d’évaluer le pouvoir infectieux des formes VBNC envers les macrophages et les cellules épithéliales alvéolaires. Nous avons étudié les profils physiologiques de L. pneumophila de trois souches différentes. Les résultats montrent que pour chaque souche 3 populations peuvent être identifiées, les légionelles viables cultivables, les VBNC et les bactéries mortes. Lorsque soumises aux stress, chaque souche possède un profil physiologique propre et la présence ou non de bactéries VBNC était dépendante du traitement appliqué et de la souche utilisée. La deuxième partie fut relative à l’étude des traitements thermiques de 70°C pendant 30 min et des chocs au dioxyde de chlore de 4, 6 et 7 mg/L pendant 60 min à température ambiante sur ces VBNC. Aucune légionelle VBNC n’est capable de se développer au sein des cellules et aucune croissance sur milieu BCYE n’a été observée après co-culture. La suite de notre étude a été d’étudier le comportement, envers les macrophages, de L. pneumophila revivifiées après culture sur amibes. Les résultats montrent que les légionelles VBNC induites par choc thermique et revivifiées par co-culture sur Acanthamoeba polyphaga sont capables d’infecter de nouveau les macrophages. En conclusion, ces résultats suggèrent que: (i) les formes VBNC de L. pneumophila ne sont pas spontanément infectieuses pour les macrophages et les cellules épithéliales alvéolaires in vitro et (ii) elles peuvent devenir pathogènes pour les cellules humaines après revivification préalable sur A. polyphaga / Legionella pneumophila, the causative agent of legionellosis is transmitted to human through aerosols from environmental sources and invades lung’s macrophages. It also can replicate within various protozoan species in environmental reservoirs. Following exposures to various stresses, L. pneumophila enters a Viable Non Cultivable state (VBNC) which is likely to be a survival strategy. The objective of our work was to study the VBNC forms of several strains of L. pneumophila serogroup 1 obtained after thermal and chemical treatments and to evaluate the infectivity of these VBNC forms against macrophages and alveolar epithelial cells. First we studied the physiological patterns of the three different strains (Philadelphia GFP 008, 044 clinical and environmental RNN). For all strains we observed the presence of VBNC bacteria in the native (non stressed) state. The results show that for each strain, three populations of Legionella can be identified: viable and culturable, VBNC and dead cells. Once submitted to the various stresses, we observed that each strain had its own physiological pattern and the presence (or not) of VBNC bacteria was dependent on the applied treatment and the strain used. The second part was related to the study of the pathogenicity of these VBNC forms against macrophages or epithelial cells. The study focused on heat shock treatment at 70°C for 30 min and chlorine dioxide treatment at 4, 6 and 7 mg/L for 60 min at room temperature. The results show that no Legionella VBNC forms were able to grow within the cells and no growth on BCYE medium was observed after co-culture. Then we investigated the behavior of L. pneumophila resuscitated after culture on ameba within macrophages. The results shows that Legionella VBNC induced by heat shock treatment and resuscitated by Acanthamoeba polyphaga co-culture are able to infect macrophages. In conclusion, these results suggest that: (i) the VBNC forms of L. pneumophila are not infectious for macrophages and alveolar epithelial cells in vitro and; (ii) they can be pathogenic for human cells after revivification by an amoeba (A. polyphaga) VBNC L. pneumophila Choc thermique Choc ClO2 Amibe Macrophage Revivification VBNC L. pneumophila Heat shock Chlorine dioxide treatment Amoeba Macrophage-like cell Resuscitation
9	Regulation of starvation and nonculturability in the marine pathogen, Vibrio vulnificus McDougald, S. Diane, School of Microbiology & Immunology, UNSW January 2000 (has links) Vibrio vulnificus is a model environmental organism exhibiting a classical starvation response during nutrient limitation as well as a non-culturable state when exposed to low temperatures. In addition to these classic global responses, this organism is an opportunistic pathogen that exhibits numerous virulence factors. This organism was chosen as the model organism for the identification of regulators of the viable but nonculturable response (VBNC) and the starvation-induced maintenance of culturability (SIMC) that occurs when cells are starved prior to low temperature incubation. In order to accomplish this, three indirect approaches were used; proteomics, investigation of intercellular signalling pathways and genetic analysis of regulators involved in these responses. Two-dimensional gel electrophoresis was used to identify proteins expressed under conditions that induced SIMC. It was determined that carbon and long-term phosphorus starvation were important in the SIMC response. V. vulnificus was shown to possess genes, luxS and smcR, that are homologues of genes involved in signalling system system 2 in Vibrio harveyi. Signal molecules were produced upon starvation and the entry to stationary phase in V. vulnificus. Furthermore, a null mutation in smcR, a transcriptional regulator was shown to have pleiotropic effects in V. vulnificus, including up-regulation of numerous virulence factors and a defect in starvation survival and development of the SIMC response. We propose that V. vulnificus possesses a signalling system analogous to that of system 2 in V. harveyi, and that this system is involved in the regulation of stationary phase and starvation adaptation in this organism. Starvation nonculturability VBNC quorum sensing signalling AI-2 Vibrio. luxR Vibrio vulnificus starvation cold adaptation
10	Characterizing the Impact of Stress Exposure on Survival of Foodborne Pathogens Shah, Manoj Kumar January 2019 (has links) Bacterial pathogens transmitted by the fecal-oral route endure several stresses during survival/growth in host and non-host environments. For foodborne pathogens, understanding the range of phenotypic responses to stressors and the environmental factors that impact survival can provide insights for the development of control measures. For example, the gastrointestinal system presents acidic, osmotic, and cell-envelope stresses and low oxygen levels, but Listeria monocytogenes can withstand these stresses, causing illnesses in humans. Survival/growth characteristics may differ among L. monocytogenes strains under these stressors due to their genetic diversities. Our knowledge of such phenotypic characteristics under bile and salt stresses are inadequate. In this dissertation, variation in growth characteristics was observed among L. monocytogenes strains under bile and osmotic stresses with no evidence of cross-protection, but rather an antagonistic effect was observed with the formation of filaments when pre-exposed to 1% bile and treated with 6% NaCl. This shows that variation in stress adaptability exists among L. monocytogenes strains with the ability to form filaments under these conditions. Similarly, Salmonella survival in soil is dependent on several factors, such as soil, amendment types, moisture, irrigation, and desiccation stress. In this study, the use of HTPP (heat-treated poultry pellets) was investigated as a soil amendment in the survival/growth of Salmonella in soil extracts mimicking runoff events, and in soil cultivated with spinach plants to assess its safety for use for an organic fertilizer. The presence of HTPP in soil increased S. Newport survival with a greater likelihood of its transfer to and survival on spinach plants. Increased microbial loads and rpoS mutant showed decreased growth/survival in soil extracts, however, rpoS was not important for survival in soil under the tested conditions showing possible lack of desiccation stress. These results show that HTPP provided nutrients to the Salmonella for increased growth and survival in soil extracts and soil, respectively, which show that the use of treated BSAAO to soils may still require appropriate mitigation to minimize Salmonella Newport contamination of leafy greens in the pre-harvest environment. Overall, the results in this study increased our understanding of L. monocytogenes and Salmonella phenotypic adaptation to stressful environments. filament formation food safety rpoS salt and bile stresses soil amendments viable but non culturable (VBNC)

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