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35 results on '"Glomski, Ian J."'

9. Benzoxazoles, Phthalazinones, and Arylurea-Based Compounds with IMP Dehydrogenase-Independent Antibacterial Activity against Francisella tularensis

Author

Gorla, Suresh Kumar, primary, Zhang, Yan, additional, Rabideau, Meaghan M., additional, Qin, Aiping, additional, Chacko, Shibin, additional, House, Amanda L., additional, Johnson, Corey R., additional, Mandapati, Kavitha, additional, Bernstein, Hannah M., additional, McKenney, Elizabeth S., additional, Boshoff, Helena, additional, Zhang, Minjia, additional, Glomski, Ian J., additional, Goldberg, Joanna B., additional, Cuny, Gregory D., additional, Mann, Barbara J., additional, and Hedstrom, Lizbeth, additional

Published
2017
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10. The Listeria monocytogenes hemolysin has an acidic pH optimum to compartmentalize activity and prevent damage to infected host cells.

Author

Glomski, Ian J, Glomski, Ian J, Gedde, Margaret M, Tsang, Albert W, Swanson, Joel A, Portnoy, Daniel A, Glomski, Ian J, Glomski, Ian J, Gedde, Margaret M, Tsang, Albert W, Swanson, Joel A, and Portnoy, Daniel A

Abstract

Listeria monocytogenes is a facultative intracellular bacterial pathogen that escapes from a phagosome and grows in the host cell cytosol. The pore-forming cholesterol-dependent cytolysin, listeriolysin O (LLO), mediates bacterial escape from vesicles and is approximately 10-fold more active at an acidic than neutral pH. By swapping dissimilar residues from a pH-insensitive orthologue, perfringolysin O (PFO), we identified leucine 461 as unique to pathogenic Listeria and responsible for the acidic pH optimum of LLO. Conversion of leucine 461 to the threonine present in PFO increased the hemolytic activity of LLO almost 10-fold at a neutral pH. L. monocytogenes synthesizing LLO L461T, expressed from its endogenous site on the bacterial chromosome, resulted in a 100-fold virulence defect in the mouse listeriosis model. These bacteria escaped from acidic phagosomes and initially grew normally in cells and spread cell to cell, but prematurely permeabilized the host membrane and killed the cell. These data show that the acidic pH optimum of LLO results from an adaptive mutation that acts to limit cytolytic activity to acidic vesicles and prevent damage in the host cytosol, a strategy also used by host cells to compartmentalize lysosomal hydrolases.

Published
2002

11. Correction to Repurposing Cryptosporidium Inosine 5′-Monophosphate Dehydrogenase Inhibitors as Potential Antibacterial Agents

Author

Mandapati, Kavitha, primary, Gorla, Suresh Kumar, additional, House, Amanda L., additional, McKenney, Elizabeth S., additional, Zhang, Minjia, additional, Rao, Suraj Nagendra, additional, Gollapalli, Deviprasad R., additional, Mann, Barbara J., additional, Goldberg, Joanna B., additional, Cuny, Gregory D., additional, Glomski, Ian J., additional, and Hedstrom, Lizbeth, additional

Published
2014
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12. Repurposing Cryptosporidium Inosine 5′-Monophosphate Dehydrogenase Inhibitors as Potential Antibacterial Agents

Author

Mandapati, Kavitha, primary, Gorla, Suresh Kumar, additional, House, Amanda L., additional, McKenney, Elizabeth S., additional, Zhang, Minjia, additional, Rao, Suraj Nagendra, additional, Gollapalli, Deviprasad R., additional, Mann, Barbara J., additional, Goldberg, Joanna B., additional, Cuny, Gregory D., additional, Glomski, Ian J., additional, and Hedstrom, Lizbeth, additional

Published
2014
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14. The cell biology of Listeria monocytogenes infection: the intersection of bacterial pathogenesis and cell-mediated immunity

Author

Portnoy, Daniel A, Auerbuch, Victoria, and Glomski, Ian J

Subjects
Bacterial Toxins, macrophage, Medical and Health Sciences, Host-Parasite Interactions, Vaccine Related, Hemolysin Proteins, Cell Movement, Models, Biodefense, 2.1 Biological and endogenous factors, 2.2 Factors relating to the physical environment, Animals, Humans, Listeriosis, Aetiology, Heat-Shock Proteins, actins, Prevention, Immunity, Biological Sciences, Foodborne Illness, Biological, phagosome, Listeria monocytogenes, virulence, Infectious Diseases, Emerging Infectious Diseases, Eukaryotic Cells, Cellular, Digestive Diseases, Infection, hemolysins, Developmental Biology
Abstract

Listeria monocytogenes has emerged as a remarkably tractable pathogen to dissect basic aspects of cell biology, intracellular pathogenesis, and innate and acquired immunity. In order to maintain its intracellular lifestyle, L. monocytogenes has evolved a number of mechanisms to exploit host processes to grow and spread cell to cell without damaging the host cell. The pore-forming protein listeriolysin O mediates escape from host vacuoles and utilizes multiple fail-safe mechanisms to avoid causing toxicity to infected cells. Once in the cytosol, the L. monocytogenes ActA protein recruits host cell Arp2/3 complexes and enabled/vasodilator-stimulated phosphoprotein family members to mediate efficient actin-based motility, thereby propelling the bacteria into neighboring cells. Alteration in any of these processes dramatically reduces the ability of the bacteria to establish a productive infection in vivo.

Published
2002

29. Circulating lethal toxin decreases the ability of neutrophils to respond to B acillus anthracis.

Author

Weiner, Zachary P., Ernst, Stephen M., Boyer, Anne E., Gallegos‐Candela, Maribel, Barr, John R., and Glomski, Ian J.

Subjects
NEUTROPHILS, BACILLUS anthracis, ANTHRAX, MICROBIAL virulence, INFLAMMATION, LABORATORY mice, IN vitro studies
Abstract

Polymorphonuclear leucocytes ( PMNs) play a protective role during B acillus anthracis infection. However, B . anthracis is able to subvert the PMN response effectively as evidenced by the high mortality rates of anthrax. One major virulence factor produced by B . anthracis, lethal toxin ( LT), is necessary for dissemination in the BSL2 model of mouse infection. While human and mouse PMNs kill vegetative B . anthracis, short in vitro half-lives of PMNs have made it difficult to determine how or if LT alters their bactericidal function. Additionally, the role of LT intoxication on PMN's ability to migrate to inflammatory signals remains controversial. LF concentrations in both serum and major organs were determined from mice infected with B . anthracis Sterne strain at defined stages of infection to guide subsequent administration of purified toxin. Bactericidal activity of PMNs assessed using ex vivo cell culture assays showed significant defects in killing B . anthracis. In vivo PMN recruitment to inflammatory stimuli was significantly impaired at 24 h as assessed by real-time analysis of light-producing PMNs within the mouse. The observations described above suggest that LT serves dual functions; it both attenuates accumulation of PMNs at sites of inflammation and impairs PMNs bactericidal activity against vegetative B . anthracis. [ABSTRACT FROM AUTHOR]

Published
2014
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30. In Trans Complementation of Lethal Factor Reveal Roles in Colonization and Dissemination in a Murine Mouse Model.

Author

Lowe, David E., Ya, Jason, and Glomski, Ian J.

Subjects
LABORATORY mice, BACILLUS anthracis, BACTERIAL colonies, EXOTOXIN, LETHAL mutations, IMMUNOREGULATION, MICROBIAL virulence
Abstract

Lethal factor (LF) is a component of the B. anthracis exotoxin and critical for pathogenesis. The roles of LF in early anthrax pathogenesis, such as colonization and dissemination from the initial site of infection, are poorly understood. In mice models of infection, LF-deficient strains either have altered dissemination patterns or do not colonize, precluding analysis of the role of LF in colonization and dissemination from the portal of entry. Previous reports indicate rabbit and guinea pig models infected with LF-deficient strains have decreased virulence, yet the inability to use bioluminescent imaging techniques to track B. anthracis growth and dissemination in these hosts makes analysis of early pathogenesis challenging. In this study, the roles of LF early in infection were analyzed using bioluminescent signature tagged libraries of B. anthracis with varying ratios of LF-producing and LF-deficient clones. Populations where all clones produced LF and populations where only 40% of clones produce LF were equally virulent. The 40% LF-producing clones trans complimented the LF mutants and permitted them to colonize and disseminate. Decreases of the LF producing strains to 10% or 0.3% of the population led to increased host survival and decreased trans complementation of the LF mutants. A library with 10% LF producing clones could replicate and disseminate, but fewer clones disseminated and the mutant clones were less competitive than wild type. The inoculum with 0.3% LF producing clones could not colonize the host. This strongly suggests that between 10% and 0.3% of the population must produce LF in order to colonize. In total, these findings suggest that a threshold of LF must be produced in order for colonization and dissemination to occur in vivo. These observations suggest that LF has a major role in the early stages of colonization and dissemination. [ABSTRACT FROM AUTHOR]

Published
2014
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31. Bacillus anthracisHas Two Independent Bottlenecks That Are Dependent on the Portal of Entry in an Intranasal Model of Inhalational Infection

Author

Lowe, David E., Ernst, Stephen M. C., Zito, Christine, Ya, Jason, and Glomski, Ian J.

Abstract

ABSTRACTBacillus anthraciscan cause inhalational anthrax. Murine inhalational B. anthracisinfections have two portals of entry, the nasal mucosa-associated lymphoid tissue (NALT) and the lumen of the lungs. Analysis of the dissemination from these sites is hindered because infections are asynchronous and asymptomatic until the hosts near death. To further understand and compare how B. anthracisdisseminates from these two different environments, clonal analysis was employed using a library of equally virulent DNA-tagged clones of a luminescent Sterne strain. Luminescence was used to determine the origin of the infection and monitor the dissemination in vivo. The number of clones and their proportions in the portals of entry, lymph nodes draining the portals, and kidneys were analyzed. Clonal analysis indicated a bottleneck for both portals of entry, yet the extent and location of the reduction in represented clones differed between the routes. In NALT-based infections, all clones were found to germinate in the NALT, but they underwent a bottleneck as the infection spread to the cervical lymph node. However, lung-based infections underwent a bottleneck in a focal region of growth within the lung lumen and did not need to spread through the mediastinal lymph nodes to cause a systemic infection. Further, the average number of clones found in the kidney and the rate at which genetic drift was affecting the disseminated populations were significantly higher in lung-based infections. Collectively, the data suggested that differences in the host environment alter dissemination of B. anthracisdepending on the site of initial colonization and growth.

Published
2013
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32. Updating Perspectives on the Initiation of Bacillus anthracisGrowth and Dissemination through Its Host

Author

Weiner, Zachary P. and Glomski, Ian J.

Abstract

ABSTRACTSince 1957, it has been proposed that the dissemination of inhalational anthrax required spores to be transported from the lumena of the lungs into the lymphatic system. In 2002, this idea was expanded to state that alveolar macrophages act as a “Trojan horse” capable of transporting spores across the lung epithelium into draining mediastinal lymph nodes. Since then, the Trojan horse model of dissemination has become the most widely cited model of inhalational infection as well as the focus of the majority of studies aiming to understand events initiating inhalational anthrax infections. However, recent observations derived from animal models of Bacillus anthracisinfection are inconsistent with aspects of the Trojan horse model and imply that bacterial dissemination patterns during inhalational infection may be more similar to the cutaneous and gastrointestinal forms than previously thought. In light of these studies, it is of significant importance to reassess the mechanisms of inhalational anthrax dissemination, since it is this form of anthrax that is most lethal and of greatest concern when B. anthracisis weaponized. Here we propose a new “jailbreak” model of B. anthracisdissemination which applies to the dissemination of all common manifestations of the disease anthrax. The proposed model impacts the field by deemphasizing the role of host cells as conduits for dissemination and increasing the role of phagocytes as central players in innate defenses, while moving the focus toward interactions between B. anthracisand lymphoid and epithelial tissues.

Published
2012
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33. Noncapsulated Toxinogenic Bacillus anthracisPresents a Specific Growth and Dissemination Pattern in Naive and Protective Antigen-Immune Mice

Author

Glomski, Ian J., Corre, Jean-Philippe, Mock, Michèle, and Goossens, Pierre L.

Abstract

ABSTRACTBacillus anthracisis a spore-forming bacterium that causes anthrax. B. anthracishas three major virulence factors, namely, lethal toxin, edema toxin, and a poly-γ-d-glutamic acid capsule. The toxins modulate host immune responses, and the capsule inhibits phagocytosis. With the goal of increasing safety, decreasing security concerns, and taking advantage of mammalian genetic tools and reagents, mouse models of B. anthracisinfection have been developed using attenuated bacteria that produce toxins but no capsule. While these models have been useful in studying both toxinogenic infections and antitoxin vaccine efficacy, we questioned whether eliminating the capsule changed bacterial growth and dissemination characteristics. Thus, the progression of infection by toxinogenic noncapsulated B. anthraciswas analyzed and compared to that by previously reported nontoxinogenic capsulated bacteria, using in vivo bioluminescence imaging. The influence of immunization with the toxin component protective antigen (PA) on the development of infection was also examined. The toxinogenic noncapsulated bacteria were initially confined to the cutaneous site of infection. Bacteria then progressed to the draining lymph nodes and, finally, late in the infection, to the lungs, kidneys, and frequently the gastrointestinal tract. There was minimal colonization of the spleen. PA immunization reduced bacterial growth from the outset and limited infection to the site of inoculation. These in vivo observations show that dissemination by toxinogenic noncapsulated strains differs markedly from that by nontoxinogenic capsulated strains. Additionally, PA immunization counters bacterial growth and dissemination in vivo from the onset of infection.

Published
2007
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34. Listeria monocytogenesMutants That Fail To Compartmentalize Listerolysin O Activity Are Cytotoxic, Avirulent, and Unable To Evade Host Extracellular Defenses

Author

Glomski, Ian J., Decatur, Amy L., and Portnoy, Daniel A.

Abstract

ABSTRACTListeria monocytogenesis a facultative intracellular bacterial pathogen that escapes from a phagosome and grows in the host cell cytosol. Escape of the bacterium from the phagosome to the cytosol is mediated by the bacterial pore-forming protein listeriolysin O (LLO). LLO has multiple mechanisms that optimize activity in the phagosome and minimize activity in the host cytosol. Mutants that fail to compartmentalize LLO activity are cytotoxic and have reduced virulence. We sought to determine why cytotoxic bacteria have attenuated virulence in the mouse model of listeriosis. In this study, we constructed a series of strains with mutations in LLO and with various degrees of cytotoxicity. We found that the more cytotoxic the strain in cell culture, the less virulent it was in mice. Induction of neutropenia increased the relative virulence of the cytotoxic strains 100-fold in the spleen and 10-fold in the liver. The virulence defect was partially restored in neutropenic mice by adding gentamicin, an antibiotic that kills extracellular bacteria. Additionally, L. monocytogenesgrew more slowly in extracellular fluid (mouse serum) than within tissue culture cells. We concluded that L. monocytogenescontrols the cytolytic activity of LLO to maintain its nutritionally rich intracellular niche and avoid extracellular defenses of the host.

Published
2003
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35. High-dimensional spectral flow cytometry of activation and phagocytosis by peripheral human polymorphonuclear leukocytes.

Author

Lamb ER, Glomski IJ, Harper TA, Solga MD, and Criss AK

Abstract

Polymorphonuclear lymphocytes (PMNs) are terminally differentiated phagocytes with pivotal roles in infection, inflammation, tissue injury, and resolution. PMNs can display a breadth of responses to diverse endogenous and exogenous stimuli, making understanding of these innate immune responders vital yet challenging to achieve. Here, we report a 22-color spectral flow cytometry panel to profile primary human PMNs on population and single cell levels for surface marker expression of activation, degranulation, phagocytosis, migration, chemotaxis, and interaction with fluorescently labeled cargo. We demonstrate the surface protein response of PMNs to phorbol ester stimulation compared to untreated controls in an adherent PMN model with additional analysis of intra- and inter-subject variability. PMNs challenged with the Gram-negative bacterial pathogen Neisseria gonorrhoeae revealed infectious dose-dependent changes in surface marker expression in bulk, population-level analysis. Imaging flow cytometry complemented spectral cytometry, demonstrating that fluorescence signal from labeled bacteria corresponded with bacterial burden on a per-cell basis. Spectral flow cytometry subsequently identified surface markers which varied with direct PMN-bacterium association as well as those which varied in the presence of bacteria but without phagocytosis. This spectral panel protocol highlights best practices for efficient customization and is compatible with downstream approaches such as spectral cell sorting and single-cell RNA-sequencing for applicability to diverse research questions in the field of PMN biology., Competing Interests: The authors declare no conflicts of interest.

Published
2024
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