John C. Freedman scite author profile

Clostridium perfringens uses its arsenal of >16 toxins to cause histotoxic and intestinal infections in humans and animals. It has been unclear why this bacterium produces so many different toxins, especially since many target the plasma membrane of host cells. However, it is now established that C. perfringens uses chromosomally encoded alpha toxin (a phospholipase C) and perfringolysin O (a pore-forming toxin) during histotoxic infections. In contrast, this bacterium causes intestinal disease by employing toxins encoded by mobile genetic elements, including C. perfringens enterotoxin, necrotic enteritis toxin B-like, epsilon toxin and beta toxin. Like perfringolysin O, the toxins with established roles in intestinal disease form membrane pores. However, the intestinal disease-associated toxins vary in their target specificity, when they are produced (sporulation vs vegetative growth), and in their sensitivity to intestinal proteases. Producing many toxins with diverse characteristics likely imparts virulence flexibility to C. perfringens so it can cause an array of diseases.

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Clostridium perfringens Enterotoxin: Action, Genetics, and Translational Applications

Freedman

Shrestha

McClane

2016

Toxins

167

120

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Clostridium perfringens enterotoxin (CPE) is responsible for causing the gastrointestinal symptoms of several C. perfringens food- and nonfood-borne human gastrointestinal diseases. The enterotoxin gene (cpe) is located on either the chromosome (for most C. perfringens type A food poisoning strains) or large conjugative plasmids (for the remaining type A food poisoning and most, if not all, other CPE-producing strains). In all CPE-positive strains, the cpe gene is strongly associated with insertion sequences that may help to assist its mobilization and spread. During disease, CPE is produced when C. perfringens sporulates in the intestines, a process involving several sporulation-specific alternative sigma factors. The action of CPE starts with its binding to claudin receptors to form a small complex; those small complexes then oligomerize to create a hexameric prepore on the membrane surface. Beta hairpin loops from the CPE molecules in the prepore assemble into a beta barrel that inserts into the membrane to form an active pore that enhances calcium influx, causing cell death. This cell death results in intestinal damage that causes fluid and electrolyte loss. CPE is now being explored for translational applications including cancer therapy/diagnosis, drug delivery, and vaccination.

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Identification and molecular characterization of a cyclic-di-GMP effector protein, PlzA (BB0733): additional evidence for the existence of a functional cyclic-di-GMP regulatory network in the Lyme disease spirochete,Borrelia burgdorferi

Freedman

Rogers

Kostick

et al. 2010

FEMS Immunol Med Microbiol

109

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The Borrelia burgdorferi Rrp1 protein is a diguanylate cyclase that controls a regulon consisting of ~10% of the total genome. Because Rrp1 lacks a DNA-binding domain, its regulatory capability is most likely mediated through the production of bis-(3′–5′)-cyclic dimeric GMP (c-di-GMP). C-di-GMP binds to and activates the regulatory activity of proteins that harbor a PilZ domain. The occurrence of a PilZ domain within a protein is not in and of itself sufficient to convey c-di-GMP binding, as other structural aspects of the protein are important in the interaction. In this study, we have assessed the expression and c-di-GMP binding ability of the sole PilZ domain-containing protein of B. burgdorferi B31, PlzA. PlzA was determined to be upregulated by tick feeding and to be expressed during mammalian infection. The gene is highly conserved and present in all Borrelia species. Analyses of recombinant PlzA demonstrated its ability to bind c-di-GMP and site-directed mutagenesis revealed that this interaction is highly specific and dependent on Arg residues contained within the PilZ domain. In summary, this study is the first to identify a c-di-GMP effector molecule in a spirochete and provides additional evidence for the existence of a complete c-di-GMP regulatory network in the Lyme disease spirochete, B. burgdorferi.

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First Selective 12-LOX Inhibitor, ML355, Impairs Thrombus Formation and Vessel Occlusion In Vivo With Minimal Effects on Hemostasis

Adili

Tourdot

Mast

et al. 2017

ATVB

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Objective Adequate platelet reactivity is required for maintain hemostasis. However, excessive platelet reactivity can also lead to the formation of occlusive thrombi. 12-lipoxygenase (12-LOX), an oxygenase highly expressed in the platelet, has been demonstrated to regulate platelet function and thrombosis ex vivo, supporting a key role for 12-LOX in the regulation of in vivo thrombosis. However, the ability to pharmacologically target 12-LOX in vivo has not been established to date. Here, we studied the effect of the first highly selective 12-LOX inhibitor, ML355, on in vivo thrombosis and hemostasis. Approach and Results ML355 dose-dependently inhibited human platelet aggregation and 12-LOX oxylipin production, as confirmed by mass spectrometry. Interestingly, the antiplatelet effects of ML355 were reversed following exposure to high concentrations of thrombin in vitro. Ex vivo flow chamber assays confirmed that human platelet adhesion and thrombus formation at arterial shear over collagen were attenuated in whole blood treated with ML355 comparable to aspirin. Oral administration of ML355 in mice showed reasonable plasma drug levels by pharmacokinetic assessment. ML355 treatment impaired thrombus growth and vessel occlusion in FeCl3-induced mesenteric and laser-induced cremaster arteriole thrombosis models in mice. Importantly, hemostatic plug formation and bleeding following treatment with ML355 was minimal in mice in response to laser ablation on the saphenous vein or in a cremaster microvasculature laser-induced rupture model. Conclusions Our data strongly supports 12-LOX as a key determinant of platelet reactivity in vivo and inhibition of platelet 12-LOX with ML355 may represent a new class of antiplatelet therapy.

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John C. Freedman

Towards an Understanding of the Role of Clostridium Perfringens Toxins in Human and Animal Disease

Clostridium perfringens Enterotoxin: Action, Genetics, and Translational Applications

Identification and molecular characterization of a cyclic-di-GMP effector protein, PlzA (BB0733): additional evidence for the existence of a functional cyclic-di-GMP regulatory network in the Lyme disease spirochete,Borrelia burgdorferi

First Selective 12-LOX Inhibitor, ML355, Impairs Thrombus Formation and Vessel Occlusion In Vivo With Minimal Effects on Hemostasis

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