Search results for "Interactions"

showing 10 items of 1963 documents

Rodent host population dynamics drive zoonotic Lyme Borreliosis and Orthohantavirus infections in humans in Northern Europe

2021

Zoonotic diseases, caused by pathogens transmitted between other vertebrate animals and humans, pose a major risk to human health. Rodents are important reservoir hosts for many zoonotic pathogens, and rodent population dynamics affect the infection dynamics of rodent-borne diseases, such as diseases caused by hantaviruses. However, the role of rodent population dynamics in determining the infection dynamics of rodent-associated tick-borne diseases, such as Lyme borreliosis (LB), caused by Borrelia burgdorferi sensu lato bacteria, have gained limited attention in Northern Europe, despite the multiannual abundance fluctuations, the so-called vole cycles, that characterise rodent population d…

jyrsijätSciencePopulation DynamicsDiseaseszoonoositinfektiotModels BiologicalPuumala virusArticlePuumala-virusZoonosesLymen borrelioosiisäntäeläimetAnimalsHumansFinlandDisease ReservoirsLyme DiseaseEcologyHost Microbial InteractionsIxodesArvicolinaeIncidenceQRpopulaatiodynamiikkaBorrelia-bakteerittaudinaiheuttajatborrelioosiHemorrhagic Fever with Renal SyndromeLinear ModelsMedicineArachnid VectorsScientific Reports
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Synthesis and Solid-State X-ray Structure of the Mononuclear Palladium(II) Complex Based on 1,2,3-Triazole Ligand

2022

Herein, we described the synthesis and X-ray crystal structure of the new [Pd(3)2Cl2] complex with 1,2,3-triazole-based ligand (3). In the unit cell, there are two [Pd(3)2Cl2] molecules, and the asymmetric unit comprised half of this formula due to the presence of an inversion symmetry element at the Pd(II) center. The monoclinic unit cell volume is 1327.85(6) Å3, with crystal parameters of a = 10.7712(2) Å, b = 6.8500(2) Å, and c = 18.2136(6) Å, while β = 98.851(2)°. The structure comprised two trans triazole ligand units coordinated to the Pd(II) ion via one of the N-atoms of the triazole moiety. In addition, the Pd(II) is further coordinated with two tran…

kemiallinen synteesiintermolecular interactionsGeneral Chemical EngineeringPd(II)-complexkompleksiyhdisteetCondensed Matter PhysicspalladiumHirshfeldInorganic ChemistryX-ray123-triazole ligandGeneral Materials Science123-triazole ligand; Pd(II)-complex; Hirshfeld; X-ray; intermolecular interactionsröntgenkristallografia
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Inter-domain interactions in filamins

2014

kristallografiaCrystallographyrakennevuorovaikutusproteiineihin sitoutuminenfilamiinitimmunoglobulin-like domainssmall angle x-ray scatteringrakenneanalyysifilaminskiderakenteetinter-domain interactionsdomeenitproteiinitsitoutumispaikatmechanosensorröntgensironta
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Antipredatory function of head shape for vipers and their mimics.

2011

Most research into the adaptive significance of warning signals has focused on the colouration and patterns of prey animals. However, behaviour, odour and body shape can also have signal functions and thereby reduce predators' willingness to attack defended prey. European vipers all have a distinctive triangular head shape; and they are all venomous. Several non-venomous snakes, including the subfamily Natricinae, commonly flatten their heads (also known as head triangulation) when disturbed. The adaptive significance of this potential behavioural mimicry has never been investigated. We experimentally tested if the triangular head shape typical of vipers offers protection against predation.…

kyykäärmeetModels AnatomicScience PolicyAnimal TypesPopulation Dynamicslcsh:MedicineZoologyBiologybehavioural mimicryHead shapePredationkäärmeetBehavioral EcologyNatrix mauraPredator-Prey DynamicsViperaSubfamily NatricinaeViperidaeAnimalsaposematismAnimal behaviorlcsh:ScienceBiologyAnimal ManagementsnakeEvolutionary BiologyMultidisciplinaryAnimal BehaviorEcologyPopulation BiologyEcologyta1184lcsh:RAgricultureBioethicsTriangular head shapeSpecies InteractionsCommunity EcologyEvolutionary EcologyPredatory BehaviorMimicryAnimal Studiesta1181lcsh:QVeterinary ScienceZoologyResearch ArticlePloS one
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Explaining users' critical incidents of physical mobile interactions

2013

käytettävyysuser behaviorcritical incidentsmobile applicationsmobiililaitteettäydennetty todellisuususer experienceinformation system usagemobiilipalvelutkokemuksetmobile servicesmobiilisovelluksetphysical mobile interactionsCritical incident technique (CIT)käyttäjäkokemustietojärjestelmät
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The transcriptome analysis of Strongyloides stercoralis L3i larvae reveals targets for intervention in a neglected disease.

2012

Background: Strongyloidiasis is one of the most neglected diseases distributed worldwide with endemic areas in developed countries, where chronic infections are life threatening. Despite its impact, very little is known about the molecular biology of the parasite involved and its interplay with its hosts. Next generation sequencing technologies now provide unique opportunities to rapidly address these questions. Principal Findings: Here we present the first transcriptome of the third larval stage of S. stercoralis using 454 sequencing coupled with semi-automated bioinformatic analyses. 253,266 raw sequence reads were assembled into 11,250 contiguous sequences, most of which were novel. 8037…

lcsh:Arctic medicine. Tropical medicineSequence analysisHaemonchus-contortuslcsh:RC955-962Molecular Sequence DataComputational biologyBiologyBioinformaticsDNA sequencingStrongyloides stercoralisTranscriptomeParasitic DiseasesmedicineAnimalsHumansDictyocaulus-viviparusGene Expression Profilinglcsh:Public aspects of medicinePublic Health Environmental and Occupational HealthNeglected DiseasesFunctional genomicslcsh:RA1-1270Sequence Analysis DNADNA Protozoanmedicine.diseasebiology.organism_classificationGene expression profilingInfectious DiseasesStrongyloidiasisLarvaHost-Pathogen InteractionsStrongyloidesStrongyloidiasisMedicineHelminth-parasitesStrongyloides stercoralisFunctional genomicsResearch ArticleNeglected Tropical DiseasesPLoS Neglected Tropical Diseases
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2018

Tetraspanins (Tspans) are a family of four-span transmembrane proteins, known as plasma membrane “master organizers.” They form Tspan-enriched microdomains (TEMs or TERMs) through lateral association with one another and other membrane proteins. If multiple microdomains associate with each other, larger platforms can form. For infection, viruses interact with multiple cell surface components, including receptors, activating proteases, and signaling molecules. It appears that Tspans, such as CD151, CD82, CD81, CD63, CD9, Tspan9, and Tspan7, coordinate these associations by concentrating the interacting partners into Tspan platforms. In addition to mediating viral attachment and entry, these …

lcsh:Immunologic diseases. Allergy0301 basic medicineCell signalingTetraspaninsMini ReviewreceptorImmunology610 MedizinbuddingvirusBiologyVirusStructure-Activity Relationship03 medical and health sciencesMembrane MicrodomainsTetraspanintrafficking610 Medical sciencesAnimalsHumansendocytosisImmunology and Allergy030102 biochemistry & molecular biologymicrodomainLipid microdomainMembrane ProteinsVirus InternalizationTransmembrane proteinCell biologytetraspanin030104 developmental biologyMembrane proteinViral replicationVirus DiseasesHost-Pathogen Interactionsentrylcsh:RC581-607BiomarkersCD81Frontiers in Immunology
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Baseline Gut Microbiota Composition Is Associated With Schistosoma mansoni Infection Burden in Rodent Models

2020

In spite of growing evidence supporting the occurrence of complex interactions between Schistosoma and gut bacteria in mice and humans, no data is yet available on whether worm-mediated changes in microbiota composition are dependent on the baseline gut microbial profile of the vertebrate host. In addition, the impact of such changes on the susceptibility to, and pathophysiology of, schistosomiasis remains largely unexplored. In this study, mice colonized with gut microbial populations from a human donor (HMA mice), as well as microbiota-wild type (WT) animals, were infected with Schistosoma mansoni, and alterations of their gut microbial profiles at 50 days post-infection were compared to …

lcsh:Immunologic diseases. Allergy0301 basic medicineRodentImmunologyAntibodies ProtozoanSchistosomiasisGut floradigestive systemParasite LoadHost-Parasite InteractionsMicrobiologyImmunomodulationFecesMice03 medical and health sciences0302 clinical medicineimmune-modulationhuman-microbiota associated mouse modelsRNA Ribosomal 16Sbiology.animalLactobacillusmedicineAnimalsImmunology and AllergySchistosomaBacteriabiologyFOS: Clinical medicineComputational BiologyBiodiversitySchistosoma mansonidysbiosismedicine.diseasebiology.organism_classificationSchistosomiasis mansoniGastrointestinal MicrobiomeDisease Models Animal030104 developmental biologyhelminth-gut microbiota interactionsSchistosomaMetagenomicsSchistosoma mansonigut microbial diversityProteobacterialcsh:RC581-607Dysbiosis030215 immunology
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How the knowledge of interactions between meningococcus and the human immune system has been used to prepare effective Neisseria meningitidis vaccines

2015

In the last decades, tremendous advancement in dissecting the mechanisms of pathogenicity ofNeisseria meningitidisat a molecular level has been achieved, exploiting converging approaches of different disciplines, ranging from pathology to microbiology, immunology, and omics sciences (such as genomics and proteomics). Here, we review the molecular biology of the infectious agent and, in particular, its interactions with the immune system, focusing on both the innate and the adaptive responses. Meningococci exploit different mechanisms and complex machineries in order to subvert the immune system and to avoid being killed. Capsular polysaccharide and lipooligosaccharide glycan composition, in…

lcsh:Immunologic diseases. AllergyImmunologyGenomicsMeningococcal VaccinesMeningococcal vaccineReview ArticleBiologyMeningitis MeningococcalNeisseria meningitidisProteomicsmedicine.disease_causeImmune systemAntigenConjugate vaccineImmunityAnimals; Gram-Negative Bacteria; Host-Pathogen Interactions; Humans; Immunity; Meningitis Meningococcal; Meningococcal Vaccines; Neisseria meningitidis; Immune System; Immunology and Allergy; ImmunologyGram-Negative BacteriamedicineAnimalsHumansImmunology; Immunology and AllergyImmunology and AllergyNeisseria meningitidisImmunityGeneral MedicineVirologyImmune SystemHost-Pathogen Interactionslcsh:RC581-607
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Antigen-specific T cells and cytokines detection as useful tool for understanding immunity against zoonotic infections.

2012

Zoonoses include a broad range of diseases, that are becoming of great interest, due to the climate changing, that cause the adaptation of vectors to new niches and environments. Host immune responses play a crucial role in determining the outcome of infections, as documented by expansion of antigen-specific T cells during several zoonotic infections. Thus, understanding of the contribution of antigen-specific T-cell subsets in the host immune response is a powerful tool to evaluate the different immunological mechanisms involved in zoonotic infections and for the development of effective vaccines. In this paper we discuss the role of T cells in some eukaryotic and prokaryotic infectious mo…

lcsh:Immunologic diseases. AllergyNematodaT-LymphocytesImmunologyReview ArticleAdaptive ImmunityBiologyHost-Parasite InteractionsImmune systemT-Lymphocyte SubsetsAntigen specificImmunityZoonosesAnimalsHumansImmunology and AllergyAntigensTh1-Th2 BalanceZoonoses antigen specific T-cells animal immunology.VaccinesBacteriaZoonotic InfectionGeneral MedicineAcquired immune systemVirologyImmunity InnateHost-Pathogen InteractionsImmunologyCytokinesAdaptationlcsh:RC581-607
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