Search results for "host-parasite"

showing 10 items of 355 documents

Water temperature, not fish morph, determines parasite infections of sympatric Icelandic threespine sticklebacks (Gasterosteus aculeatus)

2013

Parasite communities of fishes are known to respond directly to the abiotic environment of the host, for example, to water quality and water temperature. Biotic factors are also important as they affect the exposure profile through heterogeneities in parasite distribution in the environment. Parasites in a particular environment may pose a strong selection on fish. For example, ecological differences in selection by parasites have been hypothesized to facilitate evolutionary differentiation of freshwater fish morphs specializing on different food types. However, as parasites may also respond directly to abiotic environment the parasite risk does not depend only on biotic features of the hos…

0106 biological sciencesstickleback morphotypeseducationZoologyhabitat specializationGasterosteus010603 evolutionary biology01 natural sciencesADAPTIVE RADIATIONSCENTRAL FINLANDEcological speciation03 medical and health sciencesCATARACT FORMATIONecological speciation14. Life underwaterPERCH PERCA-FLUVIATILISSPATIAL VARIATION3-SPINED STICKLEBACKSEcology Evolution Behavior and SystematicsOriginal Research030304 developmental biologyNature and Landscape ConservationTREMATODE PARASITESAbiotic componentAdaptive radiationHELMINTH COMMUNITIES0303 health sciencesARCTIC CHARRBiotic componentEcologybiologyEcologyCOMPONENT COMMUNITYSticklebackbiology.organism_classification6. Clean waterDiplostomumhost-parasite interactionsHabitatSympatric speciation1181 Ecology evolutionary biologyFreshwater fishta1181lajiutuminenAdaptive radiation; Diplostomum; Ecological speciation; Habitat specialization; Stickleback morphotypes; Host-parasite interactionsEcology and Evolution
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Allee effect in a manipulative parasite within poikilothermic host under temperature change

2022

AbstractTemperature and intraspecific competition are important factors influencing the growth of all organisms, including parasites. The temperature increase is suggested to stimulate the development of parasites within poikilothermic hosts. However, at high parasite densities, this effect could be diminished, due to stronger intraspecific competition. Our study, for the first time, addressed the joint effects of warming and parasite abundances on parasite growth in poikilothermic hosts. The growth of the common fish parasite larvae (trematode Diplostomum pseudospathaceum) within the rainbow trout at different infection intensities and temperatures (15°C and 18°C) was experimentally invest…

0106 biological sciencesthermal responsecrowding effectZoologyDiplostomum pseudospathaceumTrematode InfectionsBiology010603 evolutionary biology01 natural sciencesHost-Parasite InteractionsFish Diseases03 medical and health sciencessymbols.namesakeeye flukekirjolohiloisetmetacercariaeAnimalsParasite hostingParasitessize variationEcosystem030304 developmental biologyAllee effect0303 health sciencesHost (biology)imumadotTemperatureparasite growthpopulaatiodynamiikkaInfectious DiseasesPoikilotherminfection intensitiesOncorhynchus mykisssymbolslämpötilaAnimal Science and ZoologyParasitologyTrematodaympäristönmuutoksetParasitology
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Aggregation patterns of helminth populations in the introduced fish, Liza haematocheilus (Teleostei: Mugilidae): disentangling host–parasite relation…

2018

International audience; A number of hypotheses exist to explain aggregated distributions, but they have seldom been used to investigate differences in parasite spatial distribution between native and introduced hosts. We applied two aggregation models, the negative binomial distribution and Taylor's power law, to study the aggregation patterns of helminth populations from Liza haematocheilus across its native (Sea of Japan) and introduced (Sea of Azov) distribution ranges. In accordance with the enemy release hypothesis, we predicted that parasite populations in the introduced host range would be less aggregated than in the native host area, because aggregation is tightly constrained by abu…

0301 basic medicineAquatic Organisms030231 tropical medicinePopulationZoologyAbundance–variance relationshipsBiologySpatial distributionHost-Parasite InteractionsRussia03 medical and health sciencesFish Diseases0302 clinical medicineJapanAbundance (ecology)HelminthsParasite hostingAnimalsSeawater[SDV.MP.PAR]Life Sciences [q-bio]/Microbiology and Parasitology/Parasitology14. Life underwaterTaxonomic rankeducationComputingMilieux_MISCELLANEOUSPopulation DensityEnemy release hypothesiseducation.field_of_studyResistance (ecology)Host (biology)Repeatability analysisBiodiversitySmegmamorpha030104 developmental biologyInfectious DiseasesTaxonTaylor’s power law.ParasitologyNegative binomial distributionHelminthiasis Animal[SDV.EE.IEO]Life Sciences [q-bio]/Ecology environment/Symbiosis
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The joint evolution of the Myxozoa and their alternate hosts: A cnidarian recipe for success and vast biodiversity

2018

The relationships between parasites and their hosts are intimate, dynamic and complex; the evolution of one is inevitably linked to the other. Despite multiple origins of parasitism in the Cnidaria, only parasites belonging to the Myxozoa are characterized by a complex life cycle, alternating between fish and invertebrate hosts, as well as by high species diversity. This inspired us to examine the history of adaptive radiations in myxozoans and their hosts by determining the degree of congruence between their phylogenies and by timing the emergence of myxozoan lineages in relation to their hosts. Recent genomic analyses suggested a common origin of Polypodium hydriforme, a cnidarian parasit…

0301 basic medicineCnidariaTime FactorsParasitismPolypodium hydriformeHost-Parasite InteractionsCnidaria03 medical and health sciencesPhylogeneticsbiology.animalGeneticsAnimals14. Life underwaterMyxozoaPhylogenyEcology Evolution Behavior and SystematicsInvertebrateLikelihood FunctionsMyxozoaPhylogenetic treebiologyVertebrateBiodiversitybiology.organism_classificationBiological Evolution030104 developmental biologyEvolutionary biologyVertebratesMolecular Ecology
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Network Analysis: Ten Years Shining Light on Host–Parasite Interactions

2020

Biological interactions are key drivers of ecological and evolutionary processes. The complexity of such interactions hinders our understanding of ecological systems and our ability to make effective predictions in changing environments. However, network analysis allows us to better tackle the complexity of ecosystems because it extracts the properties of an ecological system according to the number and distribution of links among interacting entities. The number of studies using network analysis to solve ecological and evolutionary questions in parasitology has increased over the past decade. Here, we synthesise the contribution of network analysis toward disentangling host-parasite proces…

0301 basic medicineComputer scienceEcology (disciplines)030231 tropical medicineEcological systems theoryModels BiologicalData scienceHost-Parasite Interactions03 medical and health sciences030104 developmental biology0302 clinical medicineInfectious DiseasesAnimalsParasitologyHost (network)Social Network AnalysisNetwork analysisTrends in Parasitology
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Microevolutionary response of a gut nematode to intestinal inflammation.

2017

7 pages; International audience; Parasitic helminths interfere with the immune response of their hosts to establish long-lasting, chronic infections. While favorable to the parasite, the capacity to dampen the immune response can also provide a benefit to the host in terms of reduced risk of immune disorders and immunopathology. The immunomodulatory role of nematodes has been exploited in clinical trials to treat a number of inflammatory and immune diseases. However, how parasites adapt to an inflammatory environment remains a poorly explored question. Here, we conducted a serial passage experiment where the gut nematode Heligmosomoides polygyrus was maintained for nine generations in mice …

0301 basic medicineGastrointestinal DiseasesInflammationHost-Parasite InteractionsRodent Diseases03 medical and health sciencesMice0302 clinical medicineImmune systemSerial passageImmunopathology[ SDV.EE.IEO ] Life Sciences [q-bio]/Ecology environment/Symbiosismedicine[ SDV.IMM ] Life Sciences [q-bio]/ImmunologyAnimalsAdaptationStrongylida InfectionsInflammationExperimental evolutionNematospiroides dubiusbiologyHost (biology)Life history traitsbiology.organism_classificationColitisBiological Evolution3. Good health030104 developmental biologyInfectious DiseasesNematodeExperimental evolutionImmunologybacteria[SDV.IMM]Life Sciences [q-bio]/ImmunologyParasitologyHeligmosomoides polygyrusmedicine.symptomSerial passage030215 immunology[SDV.EE.IEO]Life Sciences [q-bio]/Ecology environment/Symbiosis
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Exploiting Helminth–Host Interactomes through Big Data

2017

Helminths facilitate their parasitic existence through the production and secretion of different molecules, including proteins. Some helminth proteins can manipulate the host's immune system, a phenomenon that is now being exploited with a view to developing therapeutics for inflammatory diseases. In recent years, hundreds of helminth genomes have been sequenced, but as a community we are still taking baby steps when it comes to identifying proteins that govern host-helminth interactions. The information generated from genomic, immunomic, and proteomic studies, as well as from cutting-edge approaches such as proteogenomics, is leading to a substantial volume of big data that can be utilised…

0301 basic medicineGenome HelminthVaccinesHost (biology)business.industryHelminth proteinBig dataComputational BiologyHelminth ProteinsComputational biologyBiologyProteogenomicsHelminth GenomesProteomicsBioinformaticsHost-Parasite Interactions03 medical and health sciences030104 developmental biologyInfectious Diseasesparasitic diseasesAnimalsHumansParasitologybusinessTrends in Parasitology
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In vivo fluorescent cercariae reveal the entry portals of Cardiocephaloides longicollis (Rudolphi, 1819) Dubois, 1982 (Strigeidae) into the gilthead …

2019

Background Despite their complex life-cycles involving various types of hosts and free-living stages, digenean trematodes are becoming recurrent model systems. The infection and penetration strategy of the larval stages, i.e. cercariae, into the fish host is poorly understood and information regarding their entry portals is not well-known for most species. Cardiocephaloides longicollis (Rudolphi, 1819) Dubois, 1982 (Digenea, Strigeidae) uses the gilthead seabream (Sparus aurata L.), an important marine fish in Mediterranean aquaculture, as a second intermediate host, where they encyst in the brain as metacercariae. Labelling the cercariae with in vivo fluorescent dyes helped us to track the…

0301 basic medicineGillCardiocephaloides longicollis030231 tropical medicineSuccinimidesZoologyAquacultureTrematode InfectionsCarboxyfluorescein diacetate succinimidyl esterDigeneaHost-Parasite Interactionslcsh:Infectious and parasitic diseasesFish Diseases03 medical and health scienceschemistry.chemical_compound0302 clinical medicineCercarial penetration patternCercarial survival and activityMetacercarial encystmentAnimalsHelminthsMetacercariaelcsh:RC109-216CercariaCardiocephaloides longicollisFluorescent DyesInfectivityLife Cycle StagesbiologyResearchIntermediate hostAquatic animalFluoresceinsbiology.organism_classificationSea Bream030104 developmental biologyInfectious DiseaseschemistryLarvaBenzimidazolesParasitologyTrematodaDigeneaParasites & Vectors
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Disentangling the effect of host genetics and gut microbiota on resistance to an intestinal parasite

2019

11 pages; International audience; Resistance to infection is a multifactorial trait, and recent work has suggested that the gut microbiota can also contribute to resistance. Here, we performed a fecal microbiota transplant to disentangle the contribution of the gut microbiota and host genetics as drivers of resistance to the intestinal nematode Heligmosomoides polygyrus. We transplanted the microbiota of a strain of mice (SJL), resistant to H. polygyrus, into a susceptible strain (CBA) and vice-versa. We predicted that if the microbiota shapes resistance to H. polygyrus, the FMT should reverse the pattern of resistance between the two host strains. The two host strains had different microbi…

0301 basic medicineHeligmosomoides polygyrusGut floramedicine.disease_causeFecal microbiota transplant0302 clinical medicinefluids and secretionsMESH: Fecal Microbiota TransplantationParasite hostingColonizationMESH: AnimalsMESH: Strongylida InfectionsDisease ResistanceGeneticsNematospiroides dubiusbiology[SDV.BA]Life Sciences [q-bio]/Animal biologyFecal Microbiota Transplantation3. Good healthInfectious DiseasesMESH: Nematospiroides dubiusGenetic Background030231 tropical medicineIntestinal parasiteHeterologousMice Inbred StrainsMESH: Disease ResistanceMESH: Host-Parasite InteractionsMESH: Mice Inbred Strainsdigestive systemMESH: Gastrointestinal MicrobiomeHost-Parasite Interactions03 medical and health sciencesImmunityparasitic diseasesmedicineAnimals[SDV.MP.PAR]Life Sciences [q-bio]/Microbiology and Parasitology/ParasitologyStrongylida InfectionsHost (biology)ImmunityLife history traitsMESH: Genetic Backgroundbiology.organism_classificationGastrointestinal MicrobiomeDisease Models Animalstomatognathic diseases030104 developmental biologyParasitologyHeligmosomoides polygyrusMESH: Disease Models Animal[SDV.AEN]Life Sciences [q-bio]/Food and Nutrition
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Gut-microbiota-derived extracellular vesicles: Overlooked mediators in host–helminth interactions?

2021

Helminth infections impact the composition of the mammalian gut microbiota; however, the mechanisms underpinning these interactions are, thus far, unknown. In this article, we propose that microbiota-derived extracellular vesicles might represent key players in host-helminth-microbiome crosstalk, and outline future directions to elucidate their role(s) in host-parasite relationships.

0301 basic medicineHelminth infectionsHost (biology)030231 tropical medicineHelminthiasisBiologyGut florabiology.organism_classificationdigestive systemExtracellular vesiclesGastrointestinal MicrobiomeHost-Parasite InteractionsCell biologyExtracellular Vesicles03 medical and health sciencesCrosstalk (biology)fluids and secretions030104 developmental biology0302 clinical medicineInfectious DiseasesHelminthsparasitic diseasesAnimalsHumansParasitologyTrends in Parasitology
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