Search results for "Clostridium difficile toxin A"

showing 10 items of 23 documents

The Monoclonal Antitoxin Antibodies (Actoxumab–Bezlotoxumab) Treatment Facilitates Normalization of the Gut Microbiota of Mice with Clostridium diffi…

2016

Antibiotics have significant and long-lasting impacts on the intestinal microbiota and consequently reduce colonization resistance against Clostridium difficile infection (CDI). Standard therapy using antibiotics is associated with a high rate of disease recurrence, highlighting the need for novel treatment strategies that target toxins, the major virulence factors, rather than the organism itself. Human monoclonal antibodies MK-3415A (actoxumab–bezlotoxumab) to C. difficile toxin A and toxin B, as an emerging non-antibiotic approach, significantly reduced the recurrence of CDI in animal models and human clinical trials. Although the main mechanism of protection is through direct neutraliza…

0301 basic medicinelcsh:QR1-502gut microbiomeGut floralcsh:MicrobiologyantibioticsMiceLactobacillusLongitudinal StudiesOriginal Researchbiologyactoxumab and bezlotoxumabMK-3415AAntibodies MonoclonalClostridium difficile3. Good healthAnti-Bacterial AgentsInfectious DiseasesTreatment Outcome16S rDNA amplicon sequencingVancomycinmedicine.drugMicrobiology (medical)030106 microbiologyImmunologyClostridium difficile toxin AColonisation resistanceC. difficile toxin antibodyMicrobiologyMicrobiology03 medical and health sciencesVancomycinClostridium difficile infectionimmune therapymedicineAnimalsClostridioides difficileAkkermansiabiology.organism_classificationAntibodies NeutralizingSurvival AnalysisGastrointestinal MicrobiomeDisease Models Animal030104 developmental biologyBayesian networksBezlotoxumabImmunologyClostridium InfectionsAntitoxinsBroadly Neutralizing AntibodiesFrontiers in Cellular and Infection Microbiology
researchProduct

Induction of antitoxin responses in Clostridium-difficile-infected patients compared to healthy blood donors

2016

According to the literature Clostridium difficile antitoxins are present in up to 66% of humans. In a survey of ∼400 plasma samples from healthy blood donors we found that less than 6% were positive for anti-TcdA or anti-TcdB antitoxins. Using the same standard immunoassay protocol, we looked for IgG and IgA antitoxins in the blood and stool samples from 25 patients with C. difficile infection (CDI). Some patients with CDI had no antitoxin detected at all, while others had high levels of specific IgG- and IgA-antitoxins against both TcdA and TcdB in blood and IgA-anti-TcdA and -anti-TcdB antibodies in stool. Systemic responses to TcdB and mucosal responses to TcdA predominated. Among patien…

AdultMale0301 basic medicineAdolescentBacterial ToxinsClostridium difficile toxin ABlood DonorsBiologyMicrobiologyMicrobiologyYoung Adult03 medical and health sciences0302 clinical medicineImmune systemmedicineHumans030212 general & internal medicineEnterocolitis PseudomembranousAgedAntigens Bacterialmedicine.diagnostic_testClostridioides difficileCase-control studyMiddle AgedClostridium difficileAntibodies BacterialMolecular TypingTreatment Outcome030104 developmental biologyInfectious DiseasesCase-Control StudiesImmunoassayImmunologyHumoral immunitybiology.proteinFemaleAntitoxinAntibodyAnaerobe
researchProduct

Clostridium difficile Toxins Disrupt Epithelial Barrier Function by Altering Membrane Microdomain Localization of Tight Junction Proteins

2001

ABSTRACT The anaerobic bacterium Clostridium difficile is the etiologic agent of pseudomembranous colitis. C. difficile toxins TcdA and TcdB are UDP-glucosyltransferases that monoglucosylate and thereby inactivate the Rho family of GTPases (W. P. Ciesla, Jr., and D. A. Bobak, J. Biol. Chem. 273:16021–16026, 1998). We utilized purified reference toxins of C. difficile , TcdA-10463 (TcdA) and TcdB-10463 (TcdB), and a model intestinal epithelial cell line to characterize their influence on tight-junction (TJ) organization and hence to analyze the mechanisms by which they contribute to the enhanced paracellular permeability and disease pathophysiology of pseudomembranous colitis. The increase i…

Bacterial ToxinsImmunologyClostridium difficile toxin ABiologyZonula Occludens-2 ProteinOccludinMicrobiologyCell junctionPermeabilityTight JunctionsMicrobiologyAdherens junctionEnterotoxinsMembrane MicrodomainsBacterial ProteinsIntestinal MucosaClostridioides difficileCell PolarityMembrane ProteinsPseudomembranous colitisClostridium difficilePhosphoproteinsMolecular PathogenesisActinsCell biologyInfectious DiseasesMembrane proteinGlucosyltransferasesParacellular transportZonula Occludens-1 ProteinParasitologyInfection and Immunity
researchProduct

Autocatalytic cleavage of Clostridium difficile toxin B.

2007

Clostridium difficile, the causative agent of nosocomial antibiotic-associated diarrhoea and pseudomembranous colitis, possesses two main virulence factors: the large clostridial cytotoxins A and B. It has been proposed that toxin B is cleaved by a cytosolic factor of the eukaryotic target cell during its cellular uptake. Here we report that cleavage of not only toxin B, but also all other large clostridial cytotoxins, is an autocatalytic process dependent on host cytosolic inositolphosphate cofactors. A covalent inhibitor of aspartate proteases, 1,2-epoxy-3-(p-nitrophenoxy)propane, completely blocked toxin B function on cultured cells and was used to identify its catalytically active prote…

Cell ExtractsProteasesPhytic AcidSwineVirulence Factorsmedicine.medical_treatmentBacterial ToxinsClostridium difficile toxin AVirulenceClostridium difficile toxin Bmedicine.disease_causeCatalysisMicrobiologyCell LineNitrophenolsBiological FactorsBacterial ProteinsmedicineAnimalsAspartic Acid EndopeptidasesMultidisciplinaryProteaseBinding SitesToxinChemistryClostridioides difficilePseudomembranous colitisClostridium difficileProtein TransportBiochemistryEpoxy CompoundsProtein Processing Post-TranslationalSpleenNature
researchProduct

Identification of acetyl-T-2 toxin, a trichothecene, in moldy rice by HPLC and FDMS

1982

ChromatographyChemistryClinical BiochemistryTrichotheceneClostridium difficile toxin AGeneral Materials ScienceIdentification (biology)General MedicineHigh-performance liquid chromatographyAnalytical ChemistryFresenius' Zeitschrift für analytische Chemie
researchProduct

Nucleotide sequence of Clostridium difficile toxin A.

1990

ClostridiumBase SequenceToxinBacterial ToxinsMolecular Sequence DataNucleic acid sequenceClostridium difficile toxin AEnterotoxinBiologyClostridium difficilebiology.organism_classificationmedicine.disease_causeVirologyMicrobiologyEnterotoxinsClostridiumGenes BacterialGeneticsmedicineClostridiaceaeGene
researchProduct

Cloning and Characterization of Overlapping DNA Fragments of the Toxin A Gene of Clostridium difficile

1989

Clostridium difficile, a human pathogen, produces two very large protein toxins, A and B (250-600 kDa), which resist dissociation into subunits. To clone the toxin A gene, a genomic library of 3-8 kb chromosomal DNA fragments of C. difficile strain VPI 10463 established in pUC12 was screened with a rabbit polyclonal toxin A antiserum. Thirty-five clones were isolated which carried 2.5-7.0 kb inserts representing a 10 kb region of the C. difficile genome. All the inserts were oriented in the same direction, suggesting that toxin A gene expression was under control of the lac promoter of the pUC12 vector. Western blot experiments revealed the presence of low amounts of fusion proteins of vari…

ClostridiumDNA BacterialRecombinant Fusion ProteinsBacterial ToxinsBlotting WesternRestriction MappingClostridium difficile toxin ABiologyMolecular cloningmedicine.disease_causeMicrobiologyMolecular biologyMicrobiologyGene productEnterotoxinsPlasmidSubcloningGenes BacterialmedicineGenomic libraryCloning MolecularGeneEscherichia coliMicrobiology
researchProduct

Characterization of polymorphisms in the toxin A and B genes of Clostridium difficile.

2006

We have used six independent polymerase chain reactions (A1–A3 and B1–B3) for amplification of the entire sequence of the two toxin genes tcdA and tcdB of several Clostridium difficile strains. With this approach we have detected (1) restriction site polymorphisms which are distributed all over the genes, and (2) deletions that could be found only in tcdA. Characteristic differences between strains were mainly focused to the 5′ third of tcdB (B1 fragment) and/or the 3′ third of tcdA (A3 fragment). The possible use of our approach for typing of C. difficile toxin genes is discussed.

GeneticsPolymorphism GeneticClostridioides difficileBacterial ToxinsClostridium difficile toxin AClostridium difficile toxin BBiologyClostridium difficileMicrobiologyMolecular biologyPolymerase Chain Reactionlaw.inventionRestriction siteEnterotoxinsBacterial ProteinslawGenes BacterialGenotypeGeneticsTypingRestriction fragment length polymorphismMolecular BiologyPolymerase chain reactionPolymorphism Restriction Fragment LengthFEMS microbiology letters
researchProduct

Rho protein inhibition blocks protein kinase C translocation and activation.

1998

Small GTP-binding proteins of the Ras and Rho family participate in various important signalling pathways. Large clostridial cytotoxins inactivate GTPases by UDP-glucosylation. Using Clostridium difficile toxin B-10463 (TcdB) for inactivation of Rho proteins (RhoA/Rac/Cdc42) and Clostridium sordellii lethal toxin-1522 (TcsL) for inactivation of Ras-proteins (Ras/Rac/Ral, Rap) the role of these GTPases in protein kinase C (PKC) stimulation was studied. Phorbol-myristate-acetate (PMA) induced a rapid PKC translocation to and activation in the particulate cell fraction as determined by PKC-activity measurements and Western blots for PKC alpha. These effects were blocked by TcdB inhibiting Rho …

LipopolysaccharidesRHOASwineBiophysicsClostridium difficile toxin ABronchiCell Cycle ProteinsGTPaseCDC42PKC alphaBiochemistryGTP-Binding ProteinsRHO protein GDP dissociation inhibitorAnimalsHumanscdc42 GTP-Binding ProteinMolecular BiologyProtein kinase CCells CulturedProtein Kinase CbiologyEpithelial CellsCell BiologyMolecular biologyCell biologyEnzyme ActivationCdc42 GTP-Binding Proteinbiology.proteinras ProteinsTetradecanoylphorbol AcetateEndothelium VascularrhoA GTP-Binding ProteinBiochemical and biophysical research communications
researchProduct

Variant toxin B and a functional toxin A produced by Clostridium difficile C34.

2001

A particular property of Clostridium difficile strain C34 is an insertion of approximately 2 kb in the tcdA-C34 gene that does not hinder expression of a fully active TcdA-C34 molecule. Intoxication with TcdA-C34 induced an arborized appearance in eukaryotic cells (D-type cytopathic effect); intoxication with TcdB-C34 induced a spindle-like appearance of cells (S-type cytopathic effect). Inactivation of GTPases with purified toxins revealed that Rho, Rac, Cdc42, and Rap are substrates of TcdA-C34. The variant cytotoxin TcdB-C34 inactivated Rho, Rac, Cdc42, Rap, Ral, and R-Ras. Hence, this is the first ‘S-type’ cytotoxin which inactivates both Rho and R-Ras, and is coexpressed with a ‘D-type…

MaleCell SurvivalBacterial ToxinsClostridium difficile toxin AClostridium difficile toxin BGTPaseEnterotoxinCHO CellsBiologymedicine.disease_causeMicrobiologyMicrobiologyEnterotoxinsBacterial ProteinsCricetinaeGeneticsmedicineAnimalsHumansMolecular BiologyCells CulturedCytopathic effectSkinToxinClostridioides difficileCytotoxinsGenetic VariationClostridium difficileMolecular biologyCdc42 GTP-Binding ProteinDNA Transposable ElementsMicroscopy Electron ScanningFEMS microbiology letters
researchProduct