Current Search: Ricin (x)
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Title
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AB Toxins: Recovery from Intoxication and Relative Potencies.
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Creator
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Cherubin, Patrick, Teter, Kenneth, Naser, Saleh, Jewett, Travis, Zervos, Antonis, University of Central Florida
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Abstract / Description
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AB-type protein toxins have a catalytic A subunit attached to a cell-binding B subunit. Ricin, Shiga toxin (Stx), exotoxin A, and diphtheria toxin are AB toxins that act within the host cytosol and kill the host cell through pathways involving the inhibition of protein synthesis. Our overall goal is to help elucidate the cellular basis of intoxication for therapeutic development. According to the current model of intoxication, the effect of AB toxins is irreversible. To test this model, we...
Show moreAB-type protein toxins have a catalytic A subunit attached to a cell-binding B subunit. Ricin, Shiga toxin (Stx), exotoxin A, and diphtheria toxin are AB toxins that act within the host cytosol and kill the host cell through pathways involving the inhibition of protein synthesis. Our overall goal is to help elucidate the cellular basis of intoxication for therapeutic development. According to the current model of intoxication, the effect of AB toxins is irreversible. To test this model, we developed a system that uses flow cytometry and a fluorescent reporter to examine the cellular potency of toxins that inhibit protein synthesis. Our data show that cells can recover from intoxication: cells with a partial loss of protein synthesis will, upon removal of the toxin, increase the level of protein production and survive the toxin exposure. This work challenges the prevailing model of intoxication by suggesting ongoing toxin delivery to the cytosol is required to maintain the inhibition of protein synthesis and ultimately cause apoptosis. We also used our system to examine the basis for the greater cellular potency of Stx1 in comparison to Stx2. We found that cells intoxicated with Stx1a behave differently than those intoxicated with Stx2: cells exposed to Stx1a exhibited a population-wide loss of protein synthesis, while cells exposed to Stx2a or Stx2c exhibited a dose-dependent bimodal response in which one subpopulation of cells was unaffected (i.e., no loss of protein synthesis). Additional experiments indicated the identity of the Stx B subunit is a major factor in determining the uniform vs. bimodal response to Stx subtypes. This work provides evidence explaining, in part, the differential toxicity between Stx1 and Stx2. Overall, our collective observations provide experimental support for the development of inhibitors and post-exposure therapeutics that restrict, but not necessarily block, toxin delivery to the host cell.
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Date Issued
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2019
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Identifier
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CFE0007613, ucf:52523
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Format
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Document (PDF)
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PURL
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http://purl.flvc.org/ucf/fd/CFE0007613
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Title
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Unraveling PDI and its Interaction with AB Toxins.
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Creator
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Guyette, Jessica, Teter, Kenneth, Self, William, Jewett, Travis, Tatulian, Suren, University of Central Florida
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Abstract / Description
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Protein disulfide isomerase (PDI) is an essential endoplasmic reticulum (ER) protein that acts as both an oxidoreductase and chaperone. It exhibits substantial flexibility and undergoes cycles of unfolding and refolding in its interaction with cholera toxin (Ctx), which is a unique property of PDI. This unfolding allows PDI to disassemble the Ctx holotoxin, which is required for Ctx activity. Here, we investigated the unfolding and refolding property of PDI and how this affects its...
Show moreProtein disulfide isomerase (PDI) is an essential endoplasmic reticulum (ER) protein that acts as both an oxidoreductase and chaperone. It exhibits substantial flexibility and undergoes cycles of unfolding and refolding in its interaction with cholera toxin (Ctx), which is a unique property of PDI. This unfolding allows PDI to disassemble the Ctx holotoxin, which is required for Ctx activity. Here, we investigated the unfolding and refolding property of PDI and how this affects its interaction with bacterial toxins. PDI showed remarkable redox-linked conformational resilience that allows it to refold after being thermally stressed. Deletion constructs of PDI showed that both active domains play opposing roles in stability, and can both refold from an unfolded state, indicating that either domain could unfold during its interaction with Ctx. Its ability to refold suggests that the cycle of unfolding and refolding with Ctx is a normal mechanism that prevents protein aggregation. Disruption of this cycle with the polyphenol, quercetin-3-rutinoside, prevented the disassembly of Ctx, which blocked Ctx intoxication of cultured cells. Loss of PDI function was also found to inhibit intoxication with Escherichia coli heat-labile toxin but not with ricin and Shiga toxins. Toxin structure also contributes to efficiency of PDI binding and disassembly, which may explain the differential potencies between toxins. While Ctx and Ltx share similar structures, Ctx is more potent and efficiently disassembled compared to Ltx. We believe that PDI-mediated disassembly is the rate-limiting step in intoxication, thus dictating toxin potency. Overall, PDI can be targeted for a potential therapeutic for many bacterial toxins because of its unique unfolding properties and its key role in cell intoxication.
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Date Issued
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2019
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Identifier
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CFE0007646, ucf:52511
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Format
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Document (PDF)
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PURL
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http://purl.flvc.org/ucf/fd/CFE0007646
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Title
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ROLE OF MEMBRANE LIPIDS IN MODULATING PROTEIN STRUCTURE & FUNCTION.
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Creator
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Ray, Supriyo, Tatulian, Suren, University of Central Florida
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Abstract / Description
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A-B family of toxins consists of plant toxins such as ricin and bacterial toxins such as cholera. The A subunit is the enzymatic domain and the B subunit is the receptor binding domain. Commonly, these toxins bind to the target cell plasma membrane receptors through their B subunit followed by endocytosis and a transport to the endoplasmic reticulum (ER). Inside the ER, the A subunit dissociates from the rest of the toxin, unfolds and triggers the ER quality control mechanism of ER-associated...
Show moreA-B family of toxins consists of plant toxins such as ricin and bacterial toxins such as cholera. The A subunit is the enzymatic domain and the B subunit is the receptor binding domain. Commonly, these toxins bind to the target cell plasma membrane receptors through their B subunit followed by endocytosis and a transport to the endoplasmic reticulum (ER). Inside the ER, the A subunit dissociates from the rest of the toxin, unfolds and triggers the ER quality control mechanism of ER-associated degradation (ERAD). Most ERAD substrates are purged out of the ER into the cytosol for proteasomal degradation. However, the low content of lysine amino acid residues allows the toxin to evade polyubiquitination and subsequent proteasomal degradation. The toxin A subunit refolds into an active conformation in the cytosol, setting off downstream toxic events. In the first part of my thesis, the hypothesis was tested that inhibiting the unfolding of the toxin A subunit inside the ER will prevent ERAD activation, toxin export to the cytosol and intoxication. The chemical chaperones glycerol and sodium 4-phenyl butyrate (PBA) were used to inhibit the toxin A chain unfolding. In vitro biophysical experiments indicated that both chemical chaperones indeed stabilize the cholera toxin A subunit and prevent cytotoxicity. In case of ricin, both chaperones stabilized the toxin A chain but only glycerol prevented cytotoxicity. Additional experiments showed that PBA-treated ricin A chain is destabilized when exposed to anionic lipid membranes mimicking the properties of the ER membrane. In contrast, anionic lipid did not prevent ricin A chain stabilization by glycerol. This explains why glycerol but not PBA blocked ricin intoxication, as only glycerol stabilizes ricin A chain in the presence of ER membranes. Cholera toxin in contrast, remained either unaffected or slightly stabilized in presence of anionic lipids both in presence and absence of PBA. This shows that destabilization by anionic lipids is a toxin-specific rather than a general effect. In the second part of my thesis, the effect of inner leaflet of plasma membrane on the structure of cholera toxin A chain (CTA1) was studied. Since CTA1 refolds into an active conformation in the cytosol in association with unidentified host factors, I hypothesized that inner leaflet of the plasma membrane might play a role to stabilization and/or refolding of CTA1. CTA1 was shown to be a membrane interacting protein, and membranes mimicking lipid rafts had a significant stabilizing effect on its structure. Lipid rafts helped in the regaining of the tertiary and secondary structure of CTA1, while non-raft lipids had a smaller stabilizing effect on CTA1 structure. In the next part of my thesis, I studied the effect of membrane binding on the structure and function of human pancreatic phospholipase A2 (PLA2). Lipid thermal phase transition was found to have a dramatic effect on PLA2 activity. It was also established that although membrane binding and insertion was essential for of PLA2 activity, lipid structural heterogeneity was more important than the depth of membrane insertion for enzyme activation. Most importantly, significant changes in PLA2 secondary and tertiary structures were identified that evidently contribute to the interfacial activation of PLA2. Overall, we conclude that the function of membrane binding enzymes can be significantly modulated via conformational changes induced by interactions with membranes. Thus, we have elucidated various roles of membrane lipids from unfolding and refolding to activation and modulation of membrane binding enzymes. Physical properties of lipids help in regulating various aspects of protein structure and function and their analysis helped us in appreciating the influence wielded by the membrane lipids in the enzyme's surrounding environment.
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Date Issued
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2011
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Identifier
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CFE0004035, ucf:49184
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Format
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Document (PDF)
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PURL
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http://purl.flvc.org/ucf/fd/CFE0004035
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Title
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The Anti-toxin Properties of Grape Seed Phenolic Compounds.
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Creator
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Cherubin, Patrick, Teter, Kenneth, Zervos, Antonis, Roy, Herve, Phanstiel, Otto, University of Central Florida
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Abstract / Description
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Corynebacterium diphtheriae, Pseudomonas aeruginosa, Ricinus communis, Shigella dysentariae, and Vibrio cholerae produce AB toxins which share the same basic structural characteristics: a catalytic A subunit attached to a cell-binding B subunit. All AB toxins have cytosolic targets despite an initial extracellular location. AB toxins use different methods to reach the cytosol and have different effects on the target cell. Broad-spectrum inhibitors against these toxins are therefore hard to...
Show moreCorynebacterium diphtheriae, Pseudomonas aeruginosa, Ricinus communis, Shigella dysentariae, and Vibrio cholerae produce AB toxins which share the same basic structural characteristics: a catalytic A subunit attached to a cell-binding B subunit. All AB toxins have cytosolic targets despite an initial extracellular location. AB toxins use different methods to reach the cytosol and have different effects on the target cell. Broad-spectrum inhibitors against these toxins are therefore hard to develop because they use different surface receptors, entry mechanisms, enzyme activities, and cytosolic targets.We have found that grape seed extract provides resistance to five different AB toxins: diphtheria toxin (DT), P. aeruginosa exotoxin A (ETA), ricin, Shiga toxin, and cholera toxin (CT). To identify individual compounds in grape seed extract that are capable of inhibiting the activities of these AB toxins, we screened twenty common phenolic compounds of grape seed extract for anti-toxin properties. Three compounds inhibited DT, four inhibited ETA, one inhibited ricin, and twelve inhibited CT. Additional studies were performed to determine the mechanism of inhibition against CT. Two compounds inhibited CT binding to the cell surface and even stripped bound CT off the plasma membrane of a target cell. Two other compounds inhibited the enzymatic activity of CT. We have thus identified individual toxin inhibitors from grape seed extract and some of their mechanisms of inhibition against CT. This work will help to formulate a defined mixture of phenolic compounds that could potentially be used as a therapeutic against a broad range of AB toxins.
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Date Issued
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2014
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Identifier
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CFE0005315, ucf:50510
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Format
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Document (PDF)
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PURL
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http://purl.flvc.org/ucf/fd/CFE0005315