2018
An Invariant Arginine in Common with MHC Class II Allows Extension at the C-Terminal End of Peptides Bound to Chicken MHC Class I
Xiao J, Xiang W, Zhang Y, Peng W, Zhao M, Niu L, Chai Y, Qi J, Wang F, Qi P, Pan C, Han L, Wang M, Kaufman J, Gao G, Liu W. An Invariant Arginine in Common with MHC Class II Allows Extension at the C-Terminal End of Peptides Bound to Chicken MHC Class I. The Journal Of Immunology 2018, 201: 3084-3095. PMID: 30341185, DOI: 10.4049/jimmunol.1800611.Peer-Reviewed Original ResearchConceptsClassical class I moleculesC-terminusNonmammalian vertebratesChicken MHC class IC-terminal endExpressed class I moleculeClass I moleculesPeptide-binding groovePeptides to T lymphocytesJawed vertebratesClass II moleculesArg residuesChicken MHCI moleculesMHC class I allelesRepertoire of peptidesVertebratesPeptide C-terminusII moleculesMammalsClassical class II moleculesClass I allelesPeptideArgI alleles
2016
Genetics and Genomic Organization of the Major Histocompatibility Complex (MHC)
Kaufman J. Genetics and Genomic Organization of the Major Histocompatibility Complex (MHC). 2016, 166-173. DOI: 10.1016/b978-0-12-374279-7.06001-x.Peer-Reviewed Original ResearchClass II regionMolecular arms raceClass III regionExtended class III regionExtended class II regionClass I regionClassical class IClass I genesGenome organizationTumor necrosis familyClass II genesNonimmune genesGraft rejectionGenetic regionsGene familyI geneGenetic studiesMHC polymorphismPeptides to T cellsClass III genesNonmammalian vertebratesGenesIII region
2010
β4-Subunit increases Slo responsiveness to physiological Ca2+ concentrations and together with β1 reduces surface expression of Slo in hair cells
Bai JP, Surguchev A, Navaratnam D. β4-Subunit increases Slo responsiveness to physiological Ca2+ concentrations and together with β1 reduces surface expression of Slo in hair cells. American Journal Of Physiology - Cell Physiology 2010, 300: c435-c446. PMID: 21178105, PMCID: PMC3063969, DOI: 10.1152/ajpcell.00449.2010.Peer-Reviewed Original ResearchMeSH KeywordsAnimalsCalciumCalcium SignalingCell MembraneChickensCochleaDown-RegulationHair Cells, AuditoryIon Channel GatingLarge-Conductance Calcium-Activated Potassium Channel beta SubunitsLarge-Conductance Calcium-Activated Potassium ChannelsMechanotransduction, CellularMembrane PotentialsOocytesXenopus laevisConceptsLow-frequency hair cellsHair cellsLarge-conductance potassium channelsBK channelsSurface expressionBK channel functionNonmammalian vertebratesAccessory subunitsΑ-subunitMolecular underpinningsΒ-subunitChannel functionSubunitsΒ4 subunitPhysiological Ca2Critical rolePotassium channelsCellsBK currentsAdditional mechanismExpressionVertebratesDramatic increaseChicksIntracellular
2003
Calcitonin‐like immunoreactivity in serum and tissues of the bonnethead shark, Sphyrna tiburo
Nichols S, Gelsleichter J, Manire C, Cailliet G. Calcitonin‐like immunoreactivity in serum and tissues of the bonnethead shark, Sphyrna tiburo. Journal Of Experimental Zoology Part A Ecological And Integrative Physiology 2003, 298A: 150-161. PMID: 12884277, DOI: 10.1002/jez.a.10271.Peer-Reviewed Original ResearchConceptsS. tiburoSphyrna tiburoBonnethead sharksHeterologous enzyme-linked immunosorbent assaySerum calcitonin concentrationEnzyme-linked immunosorbent assayMature femalesSphyrnaBonnetheadSharksYolk dependenceElasmobranchsNonmammalian vertebratesReproductionEmbryonic developmentAnimal reproductionEarly stages of gestationRegulate certain aspectsPeptide hormonesStages of gestationYolk digestionCalcium homeostasisCalcitonin-like immunoreactivityMaternal sources
1991
Using Chicken Class I Sequences to Understand How Xenoantibodies Crossreact with MHC-like Molecules in Nonmammalian Vertebrates1
KAUFMAN J, SALOMONSEN J, RIEGERT P, SKJØDT K. Using Chicken Class I Sequences to Understand How Xenoantibodies Crossreact with MHC-like Molecules in Nonmammalian Vertebrates1. Integrative And Comparative Biology 1991, 31: 570-579. DOI: 10.1093/icb/31.3.570.Peer-Reviewed Original ResearchPatches of invariant residuesContent of guanineRate of evolutionClass I sequencesSurface residuesInterdomain contact sitesInvariant residuesHomology domainEvolutionary historyIntradomain contactsI sequencesContact sitesImmunoglobulin lociMHC-like moleculesNonmammalian vertebratesMHC moleculesMicrochromosomesAmphibiansAntigenic similarityReptilesRabbit antiserumResiduesMammalsChickenInterdomainEvolution of MHC Molecules in Nonmammalian Vertebrates
Kaufman J, Salomonsen J, Skjødt K. Evolution of MHC Molecules in Nonmammalian Vertebrates. NATO ASI Series 1991, 329-341. DOI: 10.1007/978-3-642-84622-9_28.Peer-Reviewed Original Research
1990
Evolution of the MHC: Lessons from the nonmammalian vertebrates
Kaufman J. Evolution of the MHC: Lessons from the nonmammalian vertebrates. Immunologic Research 1990, 9: 123. PMID: 2189935, DOI: 10.1007/bf02918203.Peer-Reviewed Original ResearchMHC-like molecules in some nonmammalian vertebrates can be detected by some cross-reactive monoclonal antibodies.
Kaufman J, Ferrone S, Flajnik M, Kilb M, Völk H, Parisot R. MHC-like molecules in some nonmammalian vertebrates can be detected by some cross-reactive monoclonal antibodies. The Journal Of Immunology 1990, 144: 2273-80. PMID: 1690241, DOI: 10.4049/jimmunol.144.6.2273.Peer-Reviewed Original ResearchConceptsMHC-like moleculesClass II moleculesClass IIII moleculesMHC moleculesNonmammalian vertebratesWestern blottingCross-reactivityCross-reactive monoclonal antibodiesHuman MHC moleculesMouse MHC moleculesVertebrate cellsSpleen cellsMAbs cross-reactedFlow cytometryMonoclonal antibodiesRadioactive bandsBlood cellsMAbBinding cellsLinear epitopesVertebratesXenoantiseraCross-reactive moleculesMiceMHC-like molecules in some nonmammalian vertebrates can be detected by some cross-reactive xenoantisera.
Kaufman J, Skjoedt K, Salomonsen J, Simonsen M, Du Pasquier L, Parisot R, Riegert P. MHC-like molecules in some nonmammalian vertebrates can be detected by some cross-reactive xenoantisera. The Journal Of Immunology 1990, 144: 2258-72. PMID: 2313093, DOI: 10.4049/jimmunol.144.6.2258.Peer-Reviewed Original ResearchConceptsMHC-like moleculesAntibodies to classBeta 2-microglobulinCross-reactive antibodiesCross-reactivityRepresentative vertebrate speciesCryptic determinantsNonspecific cross-reactivityAntibodies cross-reactedMHC moleculesB-G moleculesII alphaBlood cellsClass II alphaVertebrate speciesAntibodiesChicken cellsBiosynthetic intermediatesNonmammalian speciesNonmammalian vertebratesCross-reactive moleculesII betaRabbit antiserumE homodimersAlpha chainThe MHC Molecules of Nonmammalian Vertebrates
Kaufman J, Skjoedt K, Salomonsen J. The MHC Molecules of Nonmammalian Vertebrates. Immunological Reviews 1990, 113: 83-117. PMID: 2180813, DOI: 10.1111/j.1600-065x.1990.tb00038.x.Peer-Reviewed Original ResearchConceptsLevel of MHC polymorphismMHC-like moleculesMolecular evidenceFunctional evidenceAssociated with beta 2mVertebrate immune systemMammalian immune systemDisulfide-linked homodimerImmune systemAllorecognition systemClass I alpha chainMHC polymorphismCartilagenous fishBony fishesImmune responsePolymorphic class INonmammalian vertebratesIg genesFrog XenopusMammalsXenopus tadpolesReptilesVertebratesMHC moleculesXenopus
1985
DNA Synthesis and Cell Division in the Adult Primate Braina
RAKIC P. DNA Synthesis and Cell Division in the Adult Primate Braina. Annals Of The New York Academy Of Sciences 1985, 457: 193-211. PMID: 3913364, DOI: 10.1111/j.1749-6632.1985.tb20806.x.Peer-Reviewed Original ResearchConceptsPostembryonic neurogenesisNonmammalian vertebratesCell divisionDNA precursorsPrimate central nervous systemStable populationDNA synthesisNonprimate mammalsCentral nervous systemMature primatesNeuronal additionGlial cellsNervous systemAdult monkeysRetention of memoryAutoradiographic analysisMultiple injectionsVertebratesDevelopmental periodMammalsVariable degreesNeuronsJuvenilesNeurogenesisTurnover
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