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283 results on '"Knodler, Leigh A."'

1. Pathogenic diversification of the gut commensal Providencia alcalifaciens via acquisition of a second type III secretion system.

Author

Klein, Jessica, Predeus, Alexander, Greissl, Aimee, Clark-Herrera, Mattie, Cruz, Eddy, Cundiff, Jennifer, Haeberle, Amanda, Howell, Maya, Lele, Aaditi, Robinson, Donna, Westerman, Trina, Wrande, Marie, Wright, Sarah, Green, Nicole, Vallance, Bruce, Mcclelland, Michael, Mejia, Andres, Goodman, Alan, Elfenbein, Johanna, and Knodler, Leigh

Subjects
diarrhea, enteric bacteria, pathogenesis, type III secretion, virulence, Providencia, Type III Secretion Systems, Animals, Humans, Cattle, Virulence Factors, Enterobacteriaceae Infections, Bacterial Proteins, Inflammasomes
Abstract

Providencia alcalifaciens is a Gram-negative bacterium found in various water and land environments and organisms, including insects and mammals. Some P. alcalifaciens strains encode gene homologs of virulence factors found in pathogenic Enterobacterales members, such as Salmonella enterica serovar Typhimurium and Shigella flexneri. Whether these genes are pathogenic determinants in P. alcalifaciens is not known. In this study, we investigated P. alcalifaciens-host interactions at the cellular level, focusing on the role of two type III secretion systems (T3SS) belonging to the Inv-Mxi/Spa family. T3SS1b is widespread in Providencia spp. and encoded on the chromosome. A large plasmid that is present in a subset of P. alcalifaciens strains, primarily isolated from diarrheal patients, encodes for T3SS1a. We show that P. alcalifaciens 205/92 is internalized into eukaryotic cells, lyses its internalization vacuole, and proliferates in the cytosol. This triggers caspase-4-dependent inflammasome responses in gut epithelial cells. The requirement for the T3SS1a in entry, vacuole lysis, and cytosolic proliferation is host cell type-specific, playing a more prominent role in intestinal epithelial cells than in macrophages or insect cells. In a bovine ligated intestinal loop model, P. alcalifaciens colonizes the intestinal mucosa and induces mild epithelial damage with negligible fluid accumulation in a T3SS1a- and T3SS1b-independent manner. However, T3SS1b was required for the rapid killing of Drosophila melanogaster. We propose that the acquisition of two T3SS has allowed P. alcalifaciens to diversify its host range, from a highly virulent pathogen of insects to an opportunistic gastrointestinal pathogen of animals.

Published
2024

2. Pathogenic diversification of the gut commensal Providencia alcalifaciens via acquisition of a second type III secretion system

Author

Klein, Jessica A., primary, Predeus, Alexander V., additional, Greissl, Aimee, additional, Clark-Herrera, Mattie, additional, Cruz, Eddy, additional, Cundiff, Jennifer A., additional, Haeberle, Amanda L., additional, Howell, Maya, additional, Lele, Aaditi, additional, Robinson, Donna J., additional, Westerman, Trina L., additional, Wrande, Marie, additional, Wright, Sarah J., additional, Green, Nicole M., additional, Vallance, Bruce A., additional, McClelland, Michael, additional, Mejia, Andres, additional, Goodman, Alan G., additional, Elfenbein, Johanna R., additional, and Knodler, Leigh A., additional

Published
2024
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3. Genetic Determinants of Salmonella enterica Serovar Typhimurium Proliferation in the Cytosol of Epithelial Cells

Author

Wrande, Marie, Andrews-Polymenis, Helene, Twedt, Donna J, Steele-Mortimer, Olivia, Porwollik, Steffen, McClelland, Michael, and Knodler, Leigh A

Subjects
Biological Sciences, Biomedical and Clinical Sciences, Microbiology, Clinical Sciences, Medical Microbiology, Biodefense, Digestive Diseases, Emerging Infectious Diseases, Foodborne Illness, Prevention, Vaccine Related, Infectious Diseases, Genetics, 2.1 Biological and endogenous factors, 2.2 Factors relating to the physical environment, Aetiology, Infection, Good Health and Well Being, Animals, Cell Line, Cell Proliferation, Cytosol, Epithelial Cells, Humans, Mice, Mutation, Salmonella typhimurium, Agricultural and Veterinary Sciences, Medical and Health Sciences, Immunology, Medical microbiology
Abstract

Intestinal epithelial cells provide an important colonization niche for Salmonella enterica serovar Typhimurium during gastrointestinal infections. In infected epithelial cells, a subpopulation of S Typhimurium bacteria damage their internalization vacuole, leading to escape from the Salmonella-containing vacuole (SCV) and extensive proliferation in the cytosol. Little is known about the bacterial determinants of nascent SCV lysis and subsequent survival and replication of Salmonella in the cytosol. To pinpoint S Typhimurium virulence factors responsible for these steps in the intracellular infectious cycle, we screened a S Typhimurium multigene deletion library in Caco-2 C2Bbe1 and HeLa epithelial cells for mutants that had an altered proportion of cytosolic bacteria compared to the wild type. We used a gentamicin protection assay in combination with a chloroquine resistance assay to quantify total and cytosolic bacteria, respectively, for each strain. Mutants of three S Typhimurium genes, STM1461 (ydgT), STM2829 (recA), and STM3952 (corA), had reduced cytosolic proliferation compared to wild-type bacteria, and one gene, STM2120 (asmA), displayed increased cytosolic replication. None of the mutants were affected for lysis of the nascent SCV or vacuolar replication in epithelial cells, indicating that these genes are specifically required for survival and proliferation of S Typhimurium in the epithelial cell cytosol. These are the first genes identified to contribute to this step of the S Typhimurium infectious cycle.

Published
2016

4. Multicopy Single-Stranded DNA Directs Intestinal Colonization of Enteric Pathogens.

Author

Elfenbein, Johanna R, Knodler, Leigh A, Nakayasu, Ernesto S, Ansong, Charles, Brewer, Heather M, Bogomolnaya, Lydia, Adams, L Garry, McClelland, Michael, Adkins, Joshua N, and Andrews-Polymenis, Helene L

Subjects
Intestines, Animals, Mice, Escherichia coli, Salmonella typhimurium, DNA, Single-Stranded, Anaerobiosis, Developmental Biology, Genetics
Abstract

Multicopy single-stranded DNAs (msDNAs) are hybrid RNA-DNA molecules encoded on retroelements called retrons and produced by the action of retron reverse transcriptases. Retrons are widespread in bacteria but the natural function of msDNA has remained elusive despite 30 years of study. The major roadblock to elucidation of the function of these unique molecules has been the lack of any identifiable phenotypes for mutants unable to make msDNA. We report that msDNA of the zoonotic pathogen Salmonella Typhimurium is necessary for colonization of the intestine. Similarly, we observed a defect in intestinal persistence in an enteropathogenic E. coli mutant lacking its retron reverse transcriptase. Under anaerobic conditions in the absence of msDNA, proteins of central anaerobic metabolism needed for Salmonella colonization of the intestine are dysregulated. We show that the msDNA-deficient mutant can utilize nitrate, but not other alternate electron acceptors in anaerobic conditions. Consistent with the availability of nitrate in the inflamed gut, a neutrophilic inflammatory response partially rescued the ability of a mutant lacking msDNA to colonize the intestine. These findings together indicate that the mechanistic basis of msDNA function during Salmonella colonization of the intestine is proper production of proteins needed for anaerobic metabolism. We further conclude that a natural function of msDNA is to regulate protein abundance, the first attributable function for any msDNA. Our data provide novel insight into the function of this mysterious molecule that likely represents a new class of regulatory molecules.

Published
2015

6. Sensing of Bacterial Type IV Secretion via the Unfolded Protein Response

Author

de Jong, Maarten F, Starr, Tregei, Winter, Maria G, Hartigh, Andreas B den, Child, Robert, Knodler, Leigh A, van Dijl, Jan Maarten, Celli, Jean, and Tsolis, Renée M

Subjects
Biochemistry and Cell Biology, Biomedical and Clinical Sciences, Biological Sciences, Biodefense, Infectious Diseases, Emerging Infectious Diseases, 2.1 Biological and endogenous factors, Animals, Bacterial Secretion Systems, Brucella abortus, Cytokines, Endoplasmic Reticulum, Endoplasmic Reticulum Chaperone BiP, Female, HeLa Cells, Humans, Inflammation Mediators, Macrophages, Mice, Mice, Inbred C57BL, Unfolded Protein Response, Virulence Factors, Hela Cells, Microbiology, Biochemistry and cell biology, Medical microbiology
Abstract

Host cytokine responses to Brucella abortus infection are elicited predominantly by the deployment of a type IV secretion system (T4SS). However, the mechanism by which the T4SS elicits inflammation remains unknown. Here we show that translocation of the T4SS substrate VceC into host cells induces proinflammatory responses. Ectopically expressed VceC interacted with the endoplasmic reticulum (ER) chaperone BiP/Grp78 and localized to the ER of HeLa cells. ER localization of VceC required a transmembrane domain in its N terminus. Notably, the expression of VceC resulted in reorganization of ER structures. In macrophages, VceC was required for B. abortus-induced inflammation by induction of the unfolded protein response by a process requiring inositol-requiring transmembrane kinase/endonuclease 1. Altogether, these findings suggest that translocation of the T4SS effector VceC induces ER stress, which results in the induction of proinflammatory host cell responses during B. abortus infection. IMPORTANCE Brucella species are pathogens that require a type IV secretion system (T4SS) to survive in host cells and to maintain chronic infection. By as-yet-unknown pathways, the T4SS also elicits inflammatory responses in infected cells. Here we show that inflammation caused by the T4SS results in part from the sensing of a T4SS substrate, VceC, that localizes to the endoplasmic reticulum (ER), an intracellular site of Brucella replication. Possibly via binding of the ER chaperone BiP, VceC causes ER stress with concomitant expression of proinflammatory cytokines. Thus, induction of the unfolded protein response may represent a novel pathway by which host cells can detect pathogens deploying a T4SS.

Published
2013

7. Salmonella and the Inflammasome: Battle for Intracellular Dominance

Author

Crowley, Shauna M., Knodler, Leigh A., Vallance, Bruce A., Compans, Richard W, Series editor, Honjo, Tasuku, Series editor, Oldstone, Michael B. A., Series editor, Vogt, Peter K., Series editor, Malissen, Bernard, Series editor, Aktories, Klaus, Series editor, Kawaoka, Yoshihiro, Series editor, Rappuoli, Rino, Series editor, Galan, Jorge E., Series editor, Ahmed, Rafi, Series editor, Palme, Klaus, Series editor, Casadevall, Arturo, Series editor, and Backert, Steffen, editor

Published
2016
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18. Global mapping of Salmonella enterica-host protein-protein interactions during infection

Author

Walch, Philipp, primary, Selkrig, Joel, additional, Knodler, Leigh A., additional, Rettel, Mandy, additional, Stein, Frank, additional, Fernandez, Keith, additional, Viéitez, Cristina, additional, Potel, Clément M., additional, Scholzen, Karoline, additional, Geyer, Matthias, additional, Rottner, Klemens, additional, Steele-Mortimer, Olivia, additional, Savitski, Mikhail M., additional, Holden, David W., additional, and Typas, Athanasios, additional

Published
2021
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19. Intracellular niche-specific profiling reveals transcriptional adaptations required for the cytosolic lifestyle of Salmonella enterica

Author

Powers, TuShun R., Haeberle, Amanda L., Predeus, Alexander, V, Larsson Hammarlof, Disa, Cundiff, Jennifer A., Saldana-Ahuactzi, Zeus, Hokamp, Karsten, Hinton, Jay C. D., Knodler, Leigh A., Powers, TuShun R., Haeberle, Amanda L., Predeus, Alexander, V, Larsson Hammarlof, Disa, Cundiff, Jennifer A., Saldana-Ahuactzi, Zeus, Hokamp, Karsten, Hinton, Jay C. D., and Knodler, Leigh A.

Abstract

Salmonella enterica serovar Typhimurium (S. Typhimurium) is a zoonotic pathogen that causes diarrheal disease in humans and animals. During salmonellosis, S. Typhimurium colonizes epithelial cells lining the gastrointestinal tract. S. Typhimurium has an unusual lifestyle in epithelial cells that begins within an endocytic-derived Salmonella-containing vacuole (SCV), followed by escape into the cytosol, epithelial cell lysis and bacterial release. The cytosol is a more permissive environment than the SCV and supports rapid bacterial growth. The physicochemical conditions encountered by S. Typhimurium within the epithelial cytosol, and the bacterial genes required for cytosolic colonization, remain largely unknown. Here we have exploited the parallel colonization strategies of S. Typhimurium in epithelial cells to decipher the two niche-specific bacterial virulence programs. By combining a population-based RNA-seq approach with single-cell microscopic analysis, we identified bacterial genes with cytosol-induced or vacuole-induced expression signatures. Using these genes as environmental biosensors, we defined that Salmonella is exposed to oxidative stress and iron and manganese deprivation in the cytosol and zinc and magnesium deprivation in the SCV. Furthermore, iron availability was critical for optimal S. Typhimurium replication in the cytosol, as well as entC, fepB, soxS, mntH and sitA. Virulence genes that are typically associated with extracellular bacteria, namely Salmonella pathogenicity island 1 (SPI1) and SPI4, showed increased expression in the cytosol compared to vacuole. Our study reveals that the cytosolic and vacuolar S. Typhimurium virulence gene programs are unique to, and tailored for, residence within distinct intracellular compartments. This archetypical vacuole-adapted pathogen therefore requires extensive transcriptional reprogramming to successfully colonize the mammalian cytosol., QC 20220119

Published
2021
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20. Induction of Salmonella pathogenicity island 1 under different growth conditions can affect Salmonella--host cell interactions in vitro

Author

Ibarra, J. Antonio, Knodler, Leigh A., Sturdevant, Daniel E., Virtaneva, Kimmo, Carmody, Aaron B., Fischer, Elizabeth R., Porcella, Stephen F., and Steele-Mortimer, Olivia

Subjects
Bacterial proteins -- Physiological aspects, Bacterial proteins -- Genetic aspects, Bacterial proteins -- Research, Gene expression -- Research, Salmonella -- Physiological aspects, Salmonella -- Genetic aspects, Salmonella -- Research, Biological sciences
Abstract

Salmonella invade non-phagocytic cells by inducing massive actin rearrangements, resulting in membrane ruffle formation and phagocytosis of the bacteria. This process is mediated by a cohort of effector proteins translocated into the host cell by type III secretion system 1, which is encoded by genes in the Salmonella pathogenicity island (SPI) 1 regulon. This network is precisely regulated and must be induced outside of host cells. In vitro invasive Salmonella are prepared by growth in synthetic media although the details vary. Here, we show that culture conditions affect the frequency, and therefore invasion efficiency, of SPI1 -induced bacteria and also can affect the ability of Salmonella to adapt to its intracellular niche following invasion. Aerobically grown late-exponential-phase bacteria were more invasive and this was associated with a greater frequency of SPI1-induced, motile bacteria, as revealed by single-cell analysis of gene expression. Culture conditions also affected the ability of Salmonella to adapt to the intracellular environment, since they caused marked differences in intracellular replication. These findings show that induction of SPI1 under different pre-invasion growth conditions can affect the ability of Salmonella to interact with eukaryotic host cells. DOI 10.1099/mic.0.032896-0

Published
2010

27. Global mapping ofSalmonella enterica-host protein-protein interactions during infection

Author

Walch, Philipp, primary, Selkrig, Joel, additional, Knodler, Leigh A., additional, Rettel, Mandy, additional, Stein, Frank, additional, Fernandez, Keith, additional, Viéitez, Cristina, additional, Potel, Clément M., additional, Scholzen, Karoline, additional, Geyer, Matthias, additional, Rottner, Klemens, additional, Steele-Mortimer, Olivia, additional, Savitski, Mikhail M., additional, Holden, David W., additional, and Typas, Athanasios, additional

Published
2020
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36. L-arginine transport and metabolism in Giardia intestinalis support its position as a transition between prokaryotic and eukaryotic kingdoms

Author

Knodler, Leigh A., Schofield, Philip J., and Edwards, Michael R.

Subjects
Giardia lamblia -- Research, Biological transport -- Research, Biological sciences
Abstract

Arginine is metabolized by the arginine dihydrolase pathway in Giardia intestinalis trophozoites and is an important metabolic fuel for this parasite. Radiolabelled arginine was used to characterize the transport of arginine into Giardia intestinalis trophozoites. The transporter had a high affinity for arginine ([K.sub.m] 15 [mu]M) and a high activity [[V.sub.max] 76 nmol [min.sup.-1] [(mg protein).sup.-1] at 25[degrees]C]. Substrate specificity studies indicated an absolute requirement for the [alpha]-amino and carboxyl groups, but a tolerance for some substitutions in the guanidino group. The use of non-metabolized arginine analogues in combination with HPLC amino acid analysis of intra- and extra-cellular pools demonstrated that the arginine transporter is an arginine-ornithine antiport. investigations of the first step of arginine metabolism, involving arginine deiminase, revealed a relatively high affinity for arginine ([K.sub.m] 0.16 mM) and a large maximal velocity [[V.sub.max] 550 nmol [min.sup.-1] [(mg protein).sup.-1] at 37[degrees]C]. Substrate specificity studies showed that the arginine deiminase had a characteristically different substrate recognition profile to that of the arginine transporter. Overall, the combination of the transporter and the deiminase result in very low intracellular arginine concentrations and their properties are consistent with the rapid transport of arginine for metabolism via the arginine dihydrolase pathway. Keywords: arginine transport, arginine deiminase, Giardia intestinalis

Published
1995

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