Search results for "Cnidarian Venom"

showing 4 items of 4 documents

The Anemonia viridis Venom: Coupling Biochemical Purification and RNA-Seq for Translational Research

2018

Blue biotechnologies implement marine bio-resources for addressing practical concerns. The isolation of biologically active molecules from marine animals is one of the main ways this field develops. Strikingly, cnidaria are considered as sustainable resources for this purpose, as they possess unique cells for attack and protection, producing an articulated cocktail of bioactive substances. The Mediterranean sea anemone Anemonia viridis has been studied extensively for years. In this short review, we summarize advances in bioprospecting of the A. viridis toxin arsenal. A. viridis RNA datasets and toxin data mining approaches are briefly described. Analysis reveals the major pool of neurotoxi…

0301 basic medicineNeurotoxinsPharmaceutical ScienceRNA-SeqVenomReviewComputational biologyCnidarian VenomAnemoniaTranslational Research Biomedicaltranscriptomics03 medical and health sciencescomputational biologyCnidarian VenomsDrug DiscoveryAnimalsData MiningMarine ToxinTranslational Medical Researchlcsh:QH301-705.5Pharmacology Toxicology and Pharmaceutics (miscellaneous)Sea AnemoneBioprospectingbiologyAnimalSequence Analysis RNASustainable resourcesDrug Discovery3003 Pharmaceutical ScienceRNAAnemonebio-prospectingbiology.organism_classificationSea Anemones030104 developmental biologyTranscriptomiclcsh:Biology (General)RNAMarine ToxinsNeurotoxinMarine toxinMarine Drugs
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The Mucus of Actinia equina (Anthozoa, Cnidaria): An Unexplored Resource for Potential Applicative Purposes

2015

The mucus produced by many marine organisms is a complex mixture of proteins and polysaccharides forming a weak watery gel. It is essential for vital processes including locomotion, navigation, structural support, heterotrophic feeding and defence against a multitude of environmental stresses, predators, parasites, and pathogens. In the present study we focused on mucus produced by a benthic cnidarian, the sea anemone Actinia equina (Linnaeus, 1758) for preventing burial by excess sedimentation and for protection. We investigated some of the physico-chemical properties of this matrix such as viscosity, osmolarity, electrical conductivity, protein, carbohydrate, and total lipid contents. Som…

CnidariaErythrocytesCarbohydratesPharmaceutical ScienceSea anemonePolysaccharideActinia equina; Antibacterial activity; Cytotoxicity; Hemolytic activity; Mucus; Tumor cell line K562; Drug Discovery3003 Pharmaceutical ScienceArticleActinia equinaBiological FactorsCnidarian Venomsantibacterial activityDry weightCell Line TumorAnthozoaDrug DiscoveryAnimalsHumanshemolytic activitylcsh:QH301-705.5Pharmacology Toxicology and Pharmaceutics (miscellaneous)chemistry.chemical_classification<i>Actinia equina</i>tumor cell line K562biologyCytotoxinsHemolytic AgentsEcologyDrug Discovery3003 Pharmaceutical SciencemucuAnthozoabiology.organism_classificationInvertebratesMucusAnti-Bacterial AgentsMucusSea Anemoneslcsh:Biology (General)chemistryBiochemistryMucucytotoxicityRabbitsK562 CellsAntibacterial activityActiniaMarine Drugs
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Old Weapons for New Wars: Bioactive Molecules From Cnidarian Internal Defense Systems

2016

The renewed interest in the study of genes of immunity in Cnidaria has led to additional information to the scenario of the first stages of immunity evolution revealing the cellular processes involved in symbiosis, in the regulation of homeostasis and in the fight against infections. The recent study with new molecular and functional approach on these organisms have therefore contributed with unexpected information on the knowledge of the stages of capturing activities and defense mechanisms strongly associated with toxin production. Cnidarians are diblastic aquatic animals with radial symmetry; they represent the ancestral state of Metazoa, they are the simplest multicellular organisms tha…

CnidariaImmune defenseMicrobial toxinsbiologyPhylumEcologyGeneral NeuroscienceBioactive moleculesNeurotoxinsDefence mechanismsbiology.organism_classificationCnidariaMulticellular organismCnidarian VenomsNeuropsychology and Physiological PsychologyAnti-Infective AgentsAntimicrobial peptide Cnidaria Cytolysins Immune defense Neurotoxin ToxinsImmunityEvolutionary biologyAnimalsHumansMolecular MedicinePeptidesSodium Channel Blockers
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2NH and 3OH are crucial structural requirements in sphingomyelin for sticholysin II binding and pore formation in bilayer membranes.

2013

AbstractSticholysin II (StnII) is a pore-forming toxin from the sea anemone Stichodactyla heliantus which belongs to the large actinoporin family. The toxin binds to sphingomyelin (SM) containing membranes, and shows high binding specificity for this lipid. In this study, we have examined the role of the hydrogen bonding groups of the SM long-chain base (i.e., the 2NH and the 3OH) for StnII recognition. We prepared methylated SM-analogs which had reduced hydrogen bonding capability from 2NH and 3OH. Both surface plasmon resonance experiments, and isothermal titration calorimetry measurements indicated that StnII failed to bind to bilayers containing methylated SM-analogs, whereas clear bind…

Models MolecularPore Forming Cytotoxic ProteinsMembrane permeabilizationLipid BilayersBiophysicsCalorimetryta3111Biochemistrychemistry.chemical_compoundCnidarian VenomsAnimalsComputer SimulationLipid bilayerta116Binding selectivityUnilamellar LiposomesPhosphocholineBinding SitesMolecular StructureChemistryHydrogen bondVesicleta1182Isothermal titration calorimetryHydrogen BondingCell BiologySurface Plasmon ResonanceProtein Structure TertiarySphingomyelinsKineticsMembraneSea AnemonesBiochemistryMolecular dockingIsothermal titration calorimetryBiophysicsPhosphatidylcholinesSphingomyelinProtein BindingBiochimica et biophysica acta
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