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From Department of Medical Biochemistry and Biophysics, Division of Medical Inflammation Research,
Karolinska Institutet, Stockholm, Sweden
IDENTIFICATION OF GENETIC VARIANTS AND THEIR IMPLICATIONS IN
AUTOIMMUNITY
Ulrika Norin
Stockholm 2017
All previously published papers were reproduced with permission from the publisher. Published by Karolinska Institutet. Printed by Eprint AB 2017 © Ulrika Norin, 2017 ISBN 978-91-7676-561-6
Identification of genetic variants and their implications in autoimmunity
THESIS FOR DOCTORAL DEGREE (Ph.D.)
By
Ulrika Norin
Principal Supervisor: Professor Rikard Holmdahl Karolinska Institutet Department of Medical Biochemistry and Biophysics Division of Medical Inflammation Research Co-supervisor(s): Dr Liselotte Bäckdahl Karolinska Institutet Department of Medical Biochemistry and Biophysics Division of Medical Inflammation Research Docent Johan Bäcklund Karolinska Institutet Department of Medical Biochemistry and Biophysics Division of Medical Inflammation Research
Opponent: Professor Marie Malissen Centre d'Immunologie de Marseille-Luminy Examination Board: Professor Helena Erlandsson Harris Karolinska Institutet Department of Medicine, Solna Division of Rheumatology Professor Göran Andersson Sveriges lantbruksuniversitet Department of Animal Breeding and Genetics Division of Molecular Genetics Professor Mikael Karlsson Karolinska Institutet Department of Microbiology, Tumor and Cell Biology
Pulling the puzzles apart Questions of science Science and progress Nobody said it was easy No one ever said it would be so hard The Scientist by Coldplay
ABSTRACT Autoimmunedisordersstarttodevelopwhenthebody’simmunesystemrecognizesorgansandtissuesasforeignandinitiatesuncontrolledimmunereactionsagainstthem.Mostofthesedisordersareregardedascomplexwithbothenvironmentalandgeneticfactorscontributingtodiseasedevelopment.CurrenttreatmentofautoimmunedisorderssuchasRheumatoidarthritis(RA)isassociatedwithlackofefficacy,developmentofresistanceandseriousside-effectsandaccentuatestheneedfordevelopmentofnewtherapeutics.Improvedunderstandingoftheunderlyinggeneticpathwaysthatconveypathogenicityinarthritisiskeytodiscovermoreefficientandsafetherapies.Theheterogeneticnatureofautoimmunediseasesandtheinteractionwithenvironmentalfactorsdelaysthediscoveryofsusceptibilitygenesinhumans,whichsuggeststheuseofanimalmodelswherebothgeneticbackgroundandenvironmentcanbecontrolled.Inthisthesiswehaveusedratmodelstoidentifygenesthatregulatetheinductionofautoimmunearthritis.Instudyone,weidentifythegeneencodingEndophilinA2asamajordeterminantinregulatingtheinductionofautoimmunityandshowthattheEndophilinA2mediatedprotectionisregulatedviaTcellresponsiveness.Instudytwo,weinvestigatetheroleoftheVav1gene,previouslyassociatedtomultiplesclerosis,foritsroleinarthritisinratsandhumansandshowthatnaturalvariantsintheVav1generegulateTcelldependentarthritis.Instudythree,wedeterminebyfunctionalstudiesthattheincreaseinreactiveoxygenspeciesconveyedbytheNcf1gene,isresponsibleforreducedarthritisseverityseeninNcf1congenicrats.InstudyIV,weusehighresolutionmappinginaratheterogeneousstocktoidentifygenesregulatingexpressionofcellsurfacemoleculesandfrequencyofdifferentleukocytesinblood.Bycombininganimalstudiesandhumandatawehaveinthisthesisidentifiednewgenesinvolvedinthepathogenesisofarthritis,whichfurtherillustratestheheterogenicnatureofRAandthesharedperipheraltolerancepathwaysregulatingdifferentautoimmunedisorders.Furthermore,theresultsinthisthesishavedemonstratedthevalueofusinganimalstudiestoidentifygenesandpathwaysrelevanttohumandisorders.
LIST OF SCIENTIFIC PAPERS I. SpontaneousmutationrevealsEndophilinA2asamajorregulatorof
autoreactiveTcellsandapotentialnewtargetinautoimmunedisease.UlrikaNorin,CarolaRintisch,FlorianForster,LiesuMeng,DianaEkman,JonatanTuncel,KatrinKlocke,JohanBäcklund,MinYang,KlementyShchetynsky,HannaAxelsson,MartinHaraldsson,ThomasLundbäck,MariaBergquist,LeonidPadykov,IngerGjertsson,PietrodeCamilli,NorbertHubner,LiselotteBäckdahl,RikardHolmdahlManuscript
II. VAV1regulatesexperimentalautoimmunearthritisandisassociatedwithanti-CCPnegativerheumatoidarthritisAndréOrtliebGuerreiro-Cacais,UlrikaNorin,AlexandraGyllenberg,RasmusBerglund,AmennaiDanielBeyeen,RheumatoidArthritisConsortiumInternational,ElisabethPetit-Teixeira,FrançoisCornélis,AbdelhadiSaoudi,GilbertJ.Fournié,RikardHolmdahl,LarsAlfredsson,LarsKlareskog,MajaJagodic,TomasOlsson,IngridKockum,LeonidPadyukovGenesImmun.2017Jan;18(1):48-56
III. PositioningofaPolymorphicQuantitativeTraitNucleotideintheNcf1GeneControllingOxidativeBurstResponseandArthritisSeverityinRatsMalinHultqvist,OutiSareila,FredrikVilhardt,UlrikaNorin,LinaM.Olsson,PeterOlofsson,UlfHellman,RikardHolmdahlAntioxidantsandredoxsignaling,2011,14,2373-2383
IV. Combinedsequence-basedandgeneticmappinganalysisofcomplextraitsinoutbredratsAmelieBaud,RoelHermsen,VictorGuryev,PernillaStridh,DelythGraham,MartinWMcBride,TatianaForoud,SophieCalderari,MargaritaDiez,JohanOckinger,AmennaiDBeyeen,AlanGillett,NadaAbdelmagid,AndreOrtliebGuerreiro-Cacais,MajaJagodic,JonatanTuncel,UlrikaNorin,ElisabethBeattie,NganHuynh,WilliamHMiller,DanielLKoller,ImranulAlam,SamreenFalak,MaryOsborne-Pellegrin,EstherMartinez-Membrives,ToniCanete,GloriaBlazquez,EliaVicens-Costa,CarmeMont-Cardona,SiraDiaz-Moran,AdolfTobena,OliverHummel,DianaZelenika,KathrinSaar,GianninoPatone,AnjaBauerfeind,Marie-ThereseBihoreau,MatthiasHeinig,Young-AeLee,CarolaRintisch,HerbertSchulz,DavidAWheeler,KimCWorley,DonnaMMuzny,RichardAGibbs,MarkLathrop,NicoLansu,PimToonen,FransPaulRuzius,EwartdeBruijn,HeidiHauser,DavidJAdams,ThomasKeane,SantoshSAtanur,TimJAitman,PaulFlicek,TomasMalinauskas,EYvonneJones,DianaEkman,ReginaLopez-Aumatell,AnnaFDominiczak,MartinaJohannesson,RikardHolmdahl,TomasOlsson,DominiqueGauguier,NorbertHubner,AlbertoFernandez-Teruel,EdwinCuppen,RichardMott&JonathanFlint.NatureGenetics.2013Jul;45(7):767-75
ADDITIONAL PUBLICATIONS
Publicationsnotincludedinthethesis.Effectsbyperiodontitisonpristane-inducedarthritisinrats.ErikssonK,LönnblomE,TourG,KatsA,MydelP,GeorgssonP,HultgrenC,KharlamovaN,NorinU,JönssonJ,LundmarkA,HellvardA,LundbergK,JanssonL,HolmdahlR,Yucel-LindbergT.JTranslMed.2016Nov3;14(1):311.Genomesandphenomesofapopulationofoutbredratsanditsprogenitors.BaudA,GuryevV,HummelO,JohannessonM;RatGenomeSequencingandMappingConsortium.FlintJ.SciData.2014Jun10;1:140011NaturalpolymorphismsinTap2influencenegativeselectionandCD4:CD8lineagecommitmentintherat.TuncelJ,HaagS,YauAC,NorinU,BaudA,LönnblomE,MaratouK,YtterbergAJ,EkmanD,ThordardottirS,JohannessonM,GillettA;EURATRANSConsortium.,StridhP,JagodicM,OlssonT,Fernández-TeruelA,ZubarevRA,MottR,AitmanTJ,FlintJ,HolmdahlR.PLoSGenet.2014Feb20;10(2):e1004151FinemappingofthearthritisQTLPia7revealsco-localizationwithOia2andtheAPLEClocus.RintischC,KelkkaT,NorinU,LorentzenJC,OlofssonP,HolmdahlR.GenesImmun.2010Apr;11(3):239-45.
CONTENTS
1 Introduction……………………………………………………………………………………………12 Autoimmunedisorders…………………………………………………………………………..22.1Tolerancemechanismstopreventtheinductionofautoimmunity………….42.1.1Centraltolerance………………………………………………………………………………….52.1.2Peripheraltolerance…………………………………………………………………………….63 RheumatoidArthritis……………………………………………………………………………..83.1Clinicalfeaturesanddiagnosis…………………………………………………………………83.2Treatment……………………………………………………………………………………………....93.3PredisposinggeneticfactorsinRA…………………………………………………………103.4PredisposingenvironmentalfactorsinRA……………………………………………..113.5ExperimentalmodelsofRA……………………………………………………………………113.5.1Collagen-inducedarthritis…………………………………………………………………..123.5.2Pristane-inducedarthritis……………………………………………………………………123.5.3Glucose-6-phosphateisomerase-inducedarthritis…………………………….134 Geneticdissectionofcomplexdisorders………………………………………………144.1Identifyingdiseasecausinggenesinexperimentalcrosses…………………….144.2Identifyingdiseasecausinggenesinhumans…………………………………………165 PresentInvestigations………………………………………………………………………….175.1PaperI…………………………………………………………………………………………………..175.2PaperII………………………………………………………………………………………………….185.3PaperIII…………………………………………………………………………………………………195.4PaperIV…………………………………………………………………………………………………206 Concludingremarks………………………………………………………………………………217 Futureperspectives………………………………………………………………………………228 Acknowledgement……………………………………………………………………………….239 References……………………………………………………………………………………………26
LIST OF ABBREVIATIONS RA RheumatoidArthritisMS MultipleSclerosisMHC Majorhistocompabilitycomplex TCR TcellreceptorPTM Post-translationalmodificationsROS Reactive-oxygenspeciesmTEC medullarythymicepithelialcellsDC dendriticcellMQ macrophageAPC antigen-presentingcellAIRE autoimmuneregulatorTRA Tissue-restrictedantigenTGFb TransforminggrowthfactorbetaIL-10 Interleukin10GI gastrointestinalRF RheumatoidfactorACPA anti-citrullinatedproteinantibodyDMARD Disease-modifyingantirheumaticdrugPIA pristane-inducedarthrtitisCIA collagen-inducedarthrtitisGPIA glucose-6-phosphateisomerase-inducedarthritisQTL quantitativetraitlociSNP singlenucleotidepolymorphismCNV copynumbervariationGWA genome-wideassociationHS heterogeneousstockMb MegabasepairsKb Kilobasepairs
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1 INTRODUCTION Tokeepussafefrominfectionsandcancerourimmunesystemhasevolvedtorecognizeandneutralizeantigensforeigntous,suchaspathogensandalteredself-antigenspresentincancercells.Firstlineofdefenseincludestheskinbarrierandthemucousmembranesthatpreventpathogensfromenteringourbodiesandtheinnateimmunesystem.Theinnateimmunesystemisarapidactingdefensesystemthatcontainscellsliketheneutrophils,macrophagesanddendriticcellsandthecomplementsystem.Thesehaveevolutionaryconservedmoleculesandreceptorsthatrecognizestructuresforeigntous,likeinfectiousagentsfrombacteriaorviruses,toensureimmediateneutralizationandclearanceofthepathogens.Thesecondlineofdefenseistheadaptiveimmunesystem,whichincludesthelymphocytes,BcellsandTcells.Unliketheinnateimmunesystem,thelymphocytesfunctionlikeanimmunologicalmemoryanduponrecognitionofapathogentheywouldbecomeactivatedandasubsetofthecellswillbecomelong-livedmemorycellsthatcanrespondquicklyiftheinfectionwastohappenagain.Becausetheyarelong-livedtheresponseneedstobetightlyregulatedsinceawrongfullydirectedresponsetowardsforexampleaself-antigencouldhavedetrimentalconsequencesasseeninindividualswithautoimmunity.Toensurethattheresponsetoacertainantigeniscorrect,theinnateandtheadaptiveimmunesystemcommunicateviasurfacemoleculesandcytokinesinordertodistinguishbetweenpotentialharmfulandsafeevents.
InthisthesisIhavestudiedsomeofthegenesinvolvedininthisintricateinterplayoftheimmunesystem.UsinganimalmodelsforcommonautoimmunedisorderssuchasRheumatoidarthritisandmultiplesclerosiswehavedeterminedthefunctionalimplicationthegeneshaveinregulatingtheimmuneresponseandhowdisturbancesinthisregulationcanleadtoautoimmunity.InpaperIandIIweinvestigatethefunctionalimpactthatTcellshaveonautoimmunityandinpaperIIIhowreactiveoxygenspeciescanaltertheautoimmuneresponse.Understandingthemechanismsofthesepathwaysiskeytodevelopbetterandsafertherapiesforautoimmunedisorders.
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2 AUTOIMMUNE DISORDERS Autoimmunityisaconditionwherethebodymountsanattackagainstthebody’sowntissuesandorgansandischaracterizedbythepresenceofautoantibodiesandTcellsreactivetoself-antigens.AutoimmunityaffectsalargeproportionoftheWesternpopulationwithanestimatedprevalenceof7.6–9.4%1.Autoimmunedisorderscanbeorganrestrictedasinthyroiditis,typeIdiabetesandmultiplesclerosisorsystemic,affectingseveralorgans,suchassystemiclupuserythematosusandrheumatoidarthritis.Thereisastronggeneticcomponenttoautoimmunedisordersseenasfamilialaggregationofautoimmunityinaffectedindividuals.However,predispositionisnotonlydeterminedbythegeneticmake-upofanindividualbutincludeenvironmentalfactorsaswell.Thus,theyareconsideredcomplexdisorderswheremanyfactorsdetermineifanindividualwilldevelopautoimmunity.Theinductionofcomplexdisorderscanbeillustratedusingthethresholdliabilitymodel2.Hereasetofgeneticfactorsandenvironmentalfactorswillcontributetothediseasepathogenesisandthesubsequentcontributionofallfactorswilldetermineifanindividualwillcrossthethresholdandmanifestwithaclinicaldisease3,Fig.1.
Figure1.Thresholdmodelforautoimmunedisorders.A)Normallydistributedgeneticliabilityforanautoimmunedisorderinapopulation.AdaptedfromHaegert3B)Expandedmodelofsusceptibilityincludingenvironmentalfactorswhichinfluencediseasesusceptibilityinindividuals..
Geneticandenvironmentalfactorscanincreasetherelativeriskofdevelopingdiseasebuttheycanalsohaveaprotectiveeffect4.Thephenomenonthatautoimmunedisordersarecomplexisfurtherillustratedbythefactthatmonozygotictwins,althoughsharinganidenticalgenome,donotnecessarilyhavethesameriskofdevelopingautoimmunity.Ratherthanbeing100%,theconcordancerateforautoimmunedisordersinmonozygotictwinsrangefrom12%inRAto75%inAnkylosingspondylitis5.Still,therelativeriskofdevelopingautoimmunityishigherinrelativestoaffectedindividualsthanthegeneralpopulation.Thus,thereisastronggeneticlinkinpredisposingindividualstoautoimmunityhoweveradditionalexternaltriggers/factorsarealsoneeded.
Individual A Individual B Individual C Individual D
Dis
ease
sus
ecpt
ibili
ty
Genetic factorsEnvironmentals factors
Symptomatic
Asymptomatic
Indi
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in p
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Disease liability
Thre
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A B
3
Althoughthetargetedorganandsubsequentfunctionaloutcomeisdifferentbetweendifferentautoimmunedisorderstheysharecommonpredisposinggeneticpathwaysandautoimmunedisordersaggregatewithinfamilies6.Themostdominategeneticcontributoristhemajorhistocompatibilitycomplex(MHC).GenesencodingMHCmoleculesarebyfarthemostassociatedgenestoautoimmunedisorders.ThepurposeoftheMHCmoleculesistopresentpeptidestoTcells,eitherbypresentingextracellularantigensasisthecaseoftheMHCclassIImoleculesorintracellularantigensasintheMHCclassImolecules.DifferentMHCgenesassociatetodifferentautoimmunedisordersandcouldindicatethatthepresentationofaspecificantigenonacertainMHCmoleculeortheexpressionofacertainMHCmoleculesinfluencethetargetedresponsetoaspecificorgan7.Othersharedlociregulatingpredispositiontoautoimmunityhasalsobeenidentified.NotablymanyofthemaffectingTcellmediatedimmunefunctions,implicatingTcellsasmajordeterminantofautoimmunepredisposition8.Directtargetingofoneofthesegenes,theCTLA4gene,encodingthecytotoxicT-lymphocyte-associatedprotein4iscurrentlybeingusedinthetreatmentofautoimmunedisorders9.
Astheenvironmentaroundusshapestheimmunesystemanditsresponse,thefactthatenvironmentalfactorscaninfluencethepredispositiontoautoimmunedisordersislogical10.Thisnotionismaybebestexemplifiedinceliacdiseasewheretheadditionofgluteninthedietofgeneticallysusceptibleindividualsleadstoanautoreactiveresponsetotransglutaminase-2andinductionofTcelldrivendestructionofthesmallintestines.Exclusionofglutenleadstoanimmediatecessationoftheautoreactiveresponseandthelesionsoftheintestinesheal11.
Latelytheimportanceofimmunesystemhomeostasisinfluencedbythemicrobiota12,andparticularlythemicroflorainthegastrointestinal(GI)tract,hasbeengettingmuchattention.IncreasingevidenceshowsthatthepresenceofdifferentcommensalbacteriacanshiftthebalancebetweenregulatoryanddiseasedrivingTcells.Thedirectinfluenceofthegutmicroflorainthedevelopmentofautoimmunityhasbeenshownbyuseofthesegmentedfilamentousbacteria(SFB)intheK/BxNmousemodel.HeretheyshowedthatintroductionofasinglepathogenintogermfreemiceincreasedthenumberofdiseasedrivingTh17cellsandledtotheinductionofautoreactiveresponses13.Anothermechanismbywhichinfectionscancauseautoimmunitycanbeexplainedbymolecularmimicry14.Hereanantigenfromapathogenisstructurallysimilartoanantigenpresentintheendogenousbodyandthusuponinfectiontheimmunereactionwillbemisguidedtowardsaself-antigenandleadtodestructionofthetargettissue.
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Molecularmimicryhasbeensuggestedtotriggerautoimmunityinavarietyofdisordersforexamplecytomegalovirusleadingtocross-reactivityinType-Idiabetes15andcross-reactiveimmuneresponsetostreptococcalMproteinandcardiacmyosininrheumaticheartdisease16.
Insummary,theoverallinductionofautoimmunityisdeterminedbygeneticandenvironmentalfactorsanddependentofimmune-reactivity,antigenrecognitionandtissuemodulationoftheimmuneresponse.Theautoimmuneresponsecanbeseenyearsbeforeanysignsofclinicaldisease17andtheidentificationofthedysregulatedimmuneresponseearlyoniskeytoimprovetheoutcomeforthepatients.
Figure2Developmentofautoimmunity.Environmentalexposureingeneticallypredisposedindividualleadtoanalteredimmunereactivitytowardsself.Subsequenttissuedamageleadsclinicaldiagnosis.AdaptedfromChoandFeldman18
2.1Tolerancemechanismstopreventtheinductionofautoimmunity
Inordertopreventanaberrantautoreactiveimmuneresponse,theimmunesystemhasdevelopedanumberofmeanstoinducetolerancetowardsself-antigens.InthisthesisweshowthatT-cells(papersIandII)haveaspecificroleinregulatingthedevelopmentofautoimmunity.Toeliminateself-reactingTcellstwodistinctprocesseshaveevolved,centraltolerancethatoccursinthethymusduringTcelldevelopmentandperipheraltolerancewhichoccuroutinthetissues.Disruptionineitherofthepathwayscanleadtoautoimmunity.
Dis
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Time
Clinical diagnosis
Genetic architecture
Environmental factors
Altered immune response
Auto-antibody production
Tissue damage
Cumulative structural damage
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2.1.1Centraltolerance
Mostoftheself-reactingandpotentiallydangerousTcellsaredeletedduringdevelopmentinthethymus.Thisprocessneedstobecarefullybalancedtoincludedeletionofhighaffinityself-reactingTcellswhileensuringthereisenoughvariation(Tcellclones)toallowfordetectionofforeignpathogens.ItisestimatedthatoutofalltheTcellprogenitorsinthethymusonly5%eventuallymatureintoTcellsandentertheperiphery19.
ThematurationstagesofthedevelopingTcellaredividedintotwostagestermedpositiveandnegativeselection.Duringpositiveselection,immaturethymocytesareselectedfortheirabilitytoproduceaTcellreceptor(TCR)thatcanrecognizepeptideboundtoMHCmolecules.AfunctionalTCRwillledtoinductionoffurthersurvivalandmaturationsignalswhileaninabilitytoexpressafunctionalTCRwillleadtodeathbyneglect20.Maturethymocytesarethennegativelyselectediftheyrecognizeself-peptides:MHCwithhighaffinity21.TheseprocessesensurethattheTcellsenteringintotheperipheryareabletorecognizeself-MHC(andthuspossiblepathogenicpeptidespresentedonthem)butnotMHCmoleculesbearingself-antigens.
Thepresentationofself-antigensduringnegativeselectionisdependentonmedullarythymicepithelialcells(mTECs)expressingtissue-restrictedself-antigens(TRAs)andantigen-presentingcells(APCs)loadedwithantigensfromtheperipherymigratingintothethymus22,23.Theimportanceofexpressionofself-antigensduringnegativeselectioninpreventingautoimmunityisillustratedinhumansandmicewithmutationsintheautoimmuneregulator(AIRE)gene.AIREisatranscriptionfactorandregulatestheexpressionofTRAsinmTECsandlossoffunctionofAIREleadstomulti-organautoimmunity24.
Thepresenceofauto-reactiveTcellsinhealthyindividualsimpliesthatnegativeselectionisincomplete25andcouldexplainwhysomeindividualsdevelopautoimmunedisorders.Theincompletenegativeselectioncouldbeduethelackofspecificpost-translationalmodificationofcertainproteinsinthethymus26.Forexample,anincreasedTcellresponsetowardthecitrullinatedversionofcollagentypeIIcomparedtoit’snativeformcanbeseeninRApatients27.Additionally,restrictionsinthepresentationofonlyonesegmentofaproteininthymuswillleadtoanincompletetolerancetowardstotheentireproteinandcanleadtosusceptibilitytoautoimmunity28.
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2.1.2Peripheraltolerance
Duetothelimitedexpressionofself-peptidesinthymustheescapeofself-reactingTcellsisinevitable.Thereforemechanismstokeepself-reactingTcellsundercontrolintheperipheryarecrucial.ThisprocessisregulatedwithintheTcellitselfthroughignoranceandanergyandextrinsicallybyimmunesuppression.FirsttheTcellneedtorecognizetheantigenandthusiftheabundanceofantigenistoolow29oriftheTcellisphysicallyseparatedfromaparticularantigen,liketheantigensinanimmuneprivilegedsiteliketheeye30itwillnotbeactivated.Second,ifanantigenispresentedtoaTcell,theTcellwillalsorequireco-stimulatorymolecules31tobeactivatedoritwillgointoanunresponsivestatecalledanergy.Additionally,ligationofmoleculeslikeCTLA-432orPD-133ontheTcellscanactivelyinduceanergybyinhibitingcelldivisionandcytokinesecretion.Thethirdimportantpathwayoflimitinganautoimmuneresponseisimmunesuppression.SpecializedTcells,calledregulatoryTcells(Tregs),haveacriticalpartinimmunesuppression.ThesearecharacterizedbytheexpressionoftheFOXP3transcriptionfactorandhighlevelsoftheanti-inflammatorycytokinesIL-10andTGFβandareimportantininhibitingautoimmunity34.TheimportantroleofTregshasbeenshowntobeevidentinhumanswiththeIPEX(immunedysregulation,polyendocrinopathy,enteropathy,X-linked)disorder.Here,mutationsthatcausealossoffunctionintheFOXP3transcriptionfactorcausesaggressiveautoimmunityasaresultofdefectsinthefunctionoftheregulatoryTcells35.OthercellssuchastolerogenicAPCsarealsoimportantmediatorsofimmunosuppressionandcanlimitTcellproliferationandactivity36.Highlevelsofanti-inflammatorycytokinesintissuescanalsosuppressofTcellresponses.Forexample,presenceofhighlevelsofIL-10intheGItractkeepstheimmunesystemincheckevenwithahighamountofcommensalbacteriaandblockadeofIL-10leadstocolitisinmice37.
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Inthisthesiswefoundthreedifferentwaysbywhichperipheraltolerancemechanismslimitautoimmunity.InpaperI,areducedantigen-specificresponseoftheperipheralTcellsisdisplayedasaconsequenceofdecreasedsignalingfromtheTCRcomplex,leadingtoprotectionagainstautoimmunity.InpaperIIapolymorphismintheTcellsignalingmoleculeVAV1leadsdecreaseinTcelleffectorfunctionswhichsubsequentlyleadstoareductioninseverityofarthritis.InpaperIIIanincreasedproductionofreactive-oxygenspecies(ROS)byAPCschangethearthritogenicTcellresponse38andleadprotectionofarthritis.
Figure3.PathwaysofcentralandperipheralTcelltolerance.HematopoieticprogenitorsmigratefromthebonemarrowtothethymuswheretheymaturetoTcellsandundergopositiveandnegativeselectionbasedontheirinteractionswithpeptide-MHCmolecules.Self-reactiveTcellsthatfailtoundergodeletionarecontrolledintheperipherybyintrinsicandextrinsicperipheralmechanisms.AdaptedfromWalkerandAbbas39.
Positive selection of self-restricted T cells
Negative selection of self-reacting T cells
XX X
Thymus Periphery
Escape of self-reactive T cells
T cell intrinsic mechanism of peripheral tolerance:• Ignorance• Anergy
T cell extrinsic mechanism of peripheral tolerance:• Tolerogenic APCs• Regulatory T cells• Tissue modulation
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3 RHEUMATOID ARTHRITIS Rheumatoidarthritis(RA)isaninflammatoryautoimmunedisease,characterizedbychronicdestructionofsynovialjointssubsequentlyleadingtolossoffunctionofthejoints.ThetermRheumatoidarthritiswascoinedbySirAlfredGarrodin1850sandisnotadiseaseofthemodernsocietybuthasaffectedhumansforhundredstothousandsofyears40,41.RAaffectsapproximately0.5-1%ofthehumanpopulationtodayandaffectsfemalesthreetimesmoreoftenthanmalesanddiseaseonsetisataround30-60yearsofage.AsinotherautoimmunedisordersbothgeneticandenvironmentalfactorspredisposeindividualstoRAbuttheprecisecauseofRAisstillnotknown.RAprimarilyaffectsthesynovialjointsbutsystemicimmuneresponsesleadtootherextra-articularmanifestationssuchasrheumatoidnodules,pulmonaryandcardiovasculardiseasesandisregardedasystemicdisorder42.IndividualssufferingfromRAhasgreatlyreducedqualityoflifeandtheyhaveashorterlifeexpectancycomparedtothegeneralpopulation43.Asofyetthereisnocureandthuscurrenttreatmentisfocusedontreatingthesymptoms.
3.1Clinicalfeaturesanddiagnosis
RAisdiagnosedaccordingtotheACR/EULARclassificationcriteria(Table1)44andischaracterizedbyleukocyteinfiltrationintothesynovialjointwithsubsequentinflammatoryresponseresultingincartilageandbonedestruction45.Thejointofthehands,thewrists,andsmalljointsofthefeetaremostcommonlyaffectedwithsubsequentinvolvementofthejointsinthehipsandshouldersasthediseaseprogress.RApatientsareroutinelydividedintoserologicalpositiveandnegativepatientsbasedonthepresenceofRheumatoidfactors(RFs)andanti-citrullinatedproteinantibodies(ACPAs).DuetothehighlypredictivevalueofthepresenceofACPAsindiagnosisRAwithasensitivityofaround60%46,ACPApositiveRApatientsareoftendiagnosedandtreatedearliercomparedtoACPAnegativepatients.ThepathogenesisofthetwosubtypesofRApatientsappeartobedifferentintermsofpredisposinggeneticandenvironmentalfactors,discussedinmoredetailbelow,andACPApositivepatientsareoftendescribedtohaveamoreerosivediseasecourse47.
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Co-morbiditiesarecommoninRAandincludeinfections,cardiovasculardisease,malignancies(mostoftenlymphomas)anddepression48.Someareaconsequenceoftheongoingchronicinflammationbutcanalsobepresentbeforeorinconjugationwithclinicalonset.TheincreaseinprematuredeathinRApatientshasbeenlinkedtoco-morbiditiesandespeciallyinfectionsandcardiovasculardisease49.
3.2Treatment
ThereiscurrentlynocureforRAandavailabletherapyforreversingthedestructionofthecartilageandboneismissing.Thus,thestandardtreatmentisfocusedonlimitingtheinflammatoryresponse(Table2)50.Earlyandaggressivetreatmentstrategyforagoodoutcomeisnecessary51andforbettermanagementofthediseaseaschemefortreatmenthasbeenformed52.Initialtreatmentisinitiatedwithdisease-modifyingantirheumaticdrugs(DMARDs)suchashydroxychloroquine,leflunomideandmethotrexateanddependingondiseaseactivityissupplementedwithbiologicalagentssuchasTNFblockersoranti-CD20.Thefirstlineoftreatmentmostcommonlyusedisthefolateantagonist,methotrexate.Itisthoughttoinhibitproliferationofcellsbyinhibitingthesynthesisofpyrimidineandpurine,thebuildingblocksofDNAandRNA.Methotrexatehasalsobeenshowntoinhibitcytokineproductionanddecreaseexpressionofadhesionmolecules53.ThemostcommonlyusedbiologicalagentsaretheTNFαblockers.TNFαcanbefoundinhighlevelsintherheumaticjointsandregulatestheexpressionofothercytokinessuchasIL-1andIL-654.TNFαseemsparticularlyimportantinarthritispathogenesisandtransgenicmiceexpressingcontinuouslevelsofhumanizedTNFαdevelopsspontaneousandchronicarthritis55.TNFαblockadeiseffectiveinamajorityofRApatientsbuthasshowntoincreasetheriskofinfections56.
Table1.ACR/EULAR2010criteriafordiagnosing RA
Score points areshown inparentheses.Ascoreofsix orhigher isrequired forRAdiagnosis
1.Jointinvolvement(0–5)
• Onemedium-to-largejoint(0)• Twototenmedium-to-largejoints(1)• Onetothreesmalljoints(largejointsnotcounted) (2)• Fourtotensmalljoints(largejointsnotcounted)(3)• Morethantenjoints(atleastonesmalljoint)(5)
2. Serology(0–3)
• NegativeRFandnegativeACPA (0)• LowpositiveRForlowpositiveACPA(2)• HighpositiveRFor highpositiveACPA (3)
3.Acute-phasereactants(0–1)
• NormalCRPandnormalESR(0)• AbnormalCRPorabnormalESR(1)
4. Durationofsymptoms(0–1)
• Lessthan6weeks(0)• 6weeksormore(1)
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TableadaptedfromSmolenetal57,AllanGibofsky50andSardarandAndersson58
3.3PredisposinggeneticfactorsinRA
UsingfamilialstudiestheheritabilityforRAhasbeenestimatedtoabout~65%59andsuggestastronggeneticcomponenttoRA.ThesharedgeneticpredispositionbetweenRApatientswasfirstdescribedin1976byPeterStatsny60.ThroughmixedlymphocytereactionsStasnyshowedthatcellsfromRApatientsproducedalowresponsetowardRAstimulatorycellswhereasanormalallogenicresponsewasobservedtowardsnon-RAcontrols.StastnybelievedthatthisreflectedanassociationtotheMHCmoleculeandshowedthatthefrequencyoftheMHCgeneHLA-DR4wasincreasedinRApatients.TheassociationwasindeedlaterconfirmedtobetheHLA-DR461,62.ManyHLA-DRalleleshavebeenassociatedtoRAandledtothesharedepitopehypothesis63suggestingasharedmolecularstructureinTcellrecognitionoftheMHCmolecule.TheassociatedHLA-DRB1,HLA-BandHLA-DPinRAhavesubsequentlybeenshowntoshareaparticularfiveaminoacidsequence,inthepeptidebindinggroveoftheoftheassociatedmolecules64andexplainmostofthegeneticassociationinACPApositivepatients.ItwouldtakemanyyearsaftertheidentificationoftheHLA-DRgenesbeforeanothergenecouldbeconvincinglylinkedandassociatedtoRA,
Table 2. Frequently used therapeutics in RA
Conventional DMARDs Mechanism of actionMethotrexate
Folate antagonist, inhibits cell proliferation, cytokine
production
LeflunomideDihydroorotate dehydrogenase inhibitor, inhibits
pyrimidine synthesis, NFkB activation,TNFa and
matrix metalloproteinases production
Hydroxychloroquine Inhibits B- and T cells activity and cytokine release
SulfasalazineFolate antagonist, inhibits acachidonic acid cascade
TofacitinibJAK1/2/3 inhibitor, inhibits cytokine production
Biological DMARDsAdalimumab- Human monoclonal antibody TNF inhibitor
Certolizumab pegol- F(ab’) fragment of a humanised monoclonal
antibodyTNF inhibitor
Etanercept- IgG–Fc-receptor construct (fusion protein) TNF inhibitor
Golimumab- Human monoclonal antibody TNF inhibitor
Infliximab- Chimeric monoclonal antibody TNF inhibitor
Rituximab- Chimeric monoclonal antibody against CD20 B- cell depletion
Abatacept- IgG–Fc-receptor construct (fusion protein)-CTLA4 Anti-T-cell co-stimulation
Tocilizumab IL-6 inhibitor
Corticosteroids prednisolone Inhibits acachidonic acid cascade
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namelythePTPN22gene65.Sincethenmanylocihavebeenidentifiedusingwholegenomeassociationsstudies(GWAS)66withmostgenesdirectlylinkedtoimmuneregulatoryfunctions.
WhiletheconcordanceratesbetweentwinsinbothACPApositiveandnegativeRApatientshavebeenreportedtobeequal59,manyotherstudiesreportalowerheritabilityintheACPAnegativeindividuals67.Additionally,differentgenetic68andenvironmental69associationssuggeststhatthepredispositioninthetwodifferentsubtypesmightbedifferent.OurstudiesinpaperIIseemstoagreewiththisnotion.HereanassociationwithVAV1isfoundwiththeACPAnegativesubgroupbutnotintheACPApositivegroup.Additionally,wecouldshowthatthegeneregulatesthearthritisseverityinaB-cellindependentarthritismodelbutnotaB-celldependentmodel.
3.4PredisposingenvironmentalfactorsinRA
Smokingisbyfarthemostwell-knownenvironmentalfactorinRA.ThepresenceofACPAs,sharedepitopeallelesandsmokingincreasetherelativeriskbyupto40%indevelopingRA70.NosuchassociationhasbeenfoundinACPAnegativeRApatientssuggestingthatthetwosubtypesmayhavedifferentenvironmentaltriggers.SomeadditionalfactorshavebeenassociatedtoincreasedriskofRAincludeperiodontitis71andmicrobiotainthegut72whileothersuchasalcoholintakeandhighbirth-weightmightdecreasetheriskofdevelopingRA73.Interestingly,occupationalexposuretomineraloils,andinparticularhydraulicoil,havebeenshowntobeassociatedtoRA74.Aknownconstituentofhydraulicoilispristane75thesameoilusedtoinducearthritisinrats.
3.5ExperimentalmodelsofRA
RAisaheterogeneousdiseaseandtherearemanyanimalmodelsformimickingdifferentaspectsofthediseasedevelopmentandtheycanbespontaneousorinduced58,76.Animalmodelsaregreattoolsforinvestigatingthecauseandconsequenceofdifferentgeneticandenvironmentalfactorsinarthritispathogenesis.Pathwaysthatregulatearthritisdevelopmentaresharedamongspeciesandarthritisregulatinggeneticlocifoundinrodentsoverlapwithregionsfoundinhumanstudies,liketheMHCregion,provingtheirusefulnessinidentifyingnewtargetsfortherapeutics.Forexample,thedevelopmentofthenewIL23/12bi-specificantibodyintreatingautoimmunedisordersisbasedonafindinginmice77.Theneedforanimalmodelsintestingnewtherapeuticsisalsoofimportance78.InthisthesiswehaveusedthreedifferentanimalmodelsforRA;collagen-inducedarthritis(CIA),pristane-inducedarthritis(PIA)andglucose-6-phosphateisomerase-inducedarthritis(GPIA).
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3.5.1Collagen-inducedarthritis
CIAisbyfarthemostcommonlyusedmodelforRAandcanbeinducedinmice79,rats80andnon-humanprimates81.ImmunizationwiththecartilagerestrictedproteincollagentypeIIemulsifiedineitherincompleteorcompleteFreundsadjuvantleadtoimmuneresponsedirectedtowardsthejointsandsubsequentarthritis.InductionofCIAelicitsleukocyteinfiltrationtothesynovium,whichleadstosynovitisandpannusformationandcartilageandbonedestruction.BothB-andTcellsarerequiredfordiseaseinduction,reviewedin82andserumtransfercaninducearthritisinbothmiceandratsindicatingastrongcontributionofantibodiesinCIApathogenesis8384.LikeinRA,CIAisalsohighlydependentoftheMHC85butalsonon-MHCgenes86.ImmunereactivitytocollagentypeIIisalsofoundinRApatientsbothwithantibodyresponsesandauto-reactiveTcells87,88.
3.5.2Pristane-inducedarthritis
Asingleinjectionatthebaseofthetailofthemineraloilpristane((2,6,10,14tetramethylpentadecane))induceachronicrelapsingarthritisinrats.LikeinRA,immunizationcauseasymmetricaljointinflammationwithintwelvedayswithinfiltratingleukocytesintothesynoviumsubsequentsynovialinflammationandproductionofrheumatoidfactors89.Whyimmunizationwithpristaneinducesarthritisisnotknownbutisthoughttobedependentonthepolyclonalactivationofself-reactiveCD4+Tcells.ContrarytoCIA,PIAcannotbetransferredbyserumandisthoughttobelessdependentonBcells90.However,auto-antibodyresponsestowardshnRNP-A2andcollagentypeIXhavebeenidentified91,92.Auto-reactiveresponsestotheseantigenshavealsobeenfoundinRApatientsandcouldindicatecommonmechanisticpathwaysinthetwodisease93,94.VerylowamountsofpristanecausearthritisandtheincidenceisonehundredpercentintheDArats95.UsingblockingantibodiesPIAhasbeenshowntobedependentofTcellsandcanbeadoptivelytransferredbyMHCclassIIrestrictedCD4+Tcells96.PIAcanalsobeinducedinmicehoweveritappearstohaveadifferentinductionpathway.Toinducearthritis,theoilmustbeinjectedintraperitonealandthearthritisstartsmuchlaterataround50daysandincludeslupuslikesymptoms97,98.
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3.5.3Glucose-6-phosphateisomerase-inducedarthritis
InductionofarthritisbyGPIwasdiscoveredasaconsequenceofaTCRtransgenicmouseintrogressedintotheNODmouse99.ThetransgenicmouseproduceslargeamountsofantibodiestowardsGPIandthediseasecanbetransferredbyserum,thismodeliscalledK/BxNmodel100.WhyanimmunereactiontowardsGPI,whichisaubiquitousprotein,leadstoarthritisisthoughttobebecauseGPIisdepositedinlargeamountsinthejointsandantibodiestowardsGPIelicitcomplementactivationandsubsequentimmunereactionlocallyinthejoint101.InourmodelweimmunizemicewithapeptidefromtheorthologoushumanproteinemulsifiedincompleteFreundsadjuvant.Thisleadstomonophasicarthritiswithhighincidence.ItisafastmodelwithdiseaseonsetarounddaytenandhasbeenshowntobedependentonbothBandTcellsasshowninB-andT-cellknockoutmice102.GPIappeartoberelevanttoRApathogenesisandautoantibodiestowardstheproteinandbefoundinRApatients103.
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4 GENETIC DISSECTION OF COMPLEX DISORDERS
ThetheorythatcertaintraitsareinheritedindistinctpatterswereinitiallyillustratedbyGregorMendelin1850swherehecouldshowthatcertainphenotypictraitsofpeaswereinheritedfromparentalplantstodaughterplantsineitherrecessiveordominantform.WhilethetraitsMendelinvestigatedwereduetosinglegenes,thisisnotthecaseforcomplexdisorderslikeRA.Heremanygenesofsmalleffectsizescontributetothephenotype.Identificationofdisease-regulatinggenesarefurthercomplicatedbygene-geneandgene-environmentinteractions.Regionsthatareassociatedwithaparticularphenotype,commonlyentitledquantitativetraitloci(QTL),canbeidentifiedbylinkageandassociationstudies.Inlinkagestudies,co-segregationofaparticulartraitwithgenomiclociinfamiliesofaffectedandunaffectedindividualsareidentified.Inassociationstudies,thefrequencyofanalleleorgenotypeinlargerpopulationsofunrelatedaffectedandnon-affectedindividualsiscompared.Ifthegenotypeisover-representativeinaffectedindividualstheinvestigatedgeneticmarkerisbelievedtobeassociatedtothetrait.Therearedifferenttypesofgeneticvariantsandpolymorphismsthatcanaffectgenesandregulateadiseasephenotype.Inthisthesiswedescribeaninsertionofatransposon,whichreducestheexpressionofageneandcodingsinglenucleotidepolymorphisms(SNPs)thatalterthefunctionoftheencodedproteins.Othergeneticvariantssuchascopynumbervariations(CNVs),asseeninregulationoftheNCF1geneinhumans104,arealsoimportantinregulatinggenefunction.Usingdifferentlinkageandassociationstudies,wehaveidentifiedfourdifferentgenesinvolvedinimmuneregulatoryphenotypes.
4.1Identifyingdiseasecausinggenesinexperimentalcrosses
Experimentalcrossesofinbredstrainsofsusceptibleandresistantstrainscanbeusedtoidentifydisease-regulatinggenes.Asuccessfuloutcomeofusinganimalsforidentificationofdiseaseregulatinggenesthatareimportantinthehumanconditiondependsonboththephenotypiccoherencebetweenhumanandanimalandthephenotyperegulatinggeneticvariabilityintheanimalsused.InpaperI-IIIweusedF2crossestoidentifygenomicregionsthatregulatesusceptibilitytoarthritis.Hereoffspringofonesusceptibleandoneresistantstraincalledfilial1generation(F1)arebredtogethertoproduceasecondfilialgeneration(F2).EachoffspringintheF2generationwillhaveauniquemixofsusceptibleandresistantgenomiclocispreadacrossthegenome,duetorecombinationeventsduringmeiosis.Usingtheinformationofmarkersthatarepolymorphicbetweentheresistantandsusceptiblestrainandbydetectingthephenotypeineachoftheoffspringonecanperformalinkageanalysis.Toidentifylocithatarelinkedtothetraitthelogarithmofodds(LOD)scoremethodisused105.Itiscalculatedbycomparingtheprobabilitythatagivenmarkeris
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inheritedtogetherwiththetrait,andthusarelinked,withtheprobabilityofobservingthesamelinkagebychance.DuetothelimitednumberofrecombinationeventsinaF2cross,thediseaseregulatinggenomiclocicoverlargegenomicregionscontainingmanygenesandthusfurtherisolationofthegeneticlociincongenicstrainsthroughbackcrossingisusuallyneededinordertoidentifythedisease-regulatinggene106.
Figure4.F2crossesandcongenicstrainsusedtoidentifydisease-regulatinggenes.
Nevertheless,toassignaphenotypetoasinglegene,knownaspositionalcloning,usingonlycongenicstrainsisdifficultandtimeconsumingandtheuseoffunctionalstudiesandgeneticallymodifiedanimalsmightbeneeded.Usingthiscombinedapproach,wecouldpositionallyclonetheSH3gl1geneinpaperIandtheROSregulatingnucleotideintheNcf1geneinpaperIII.
AsstandardF2geneticcrossesonlyincludethegeneticvariationoftwoparentalstrainsandhavelowmappingresolution,weutilizedaheterogeneousstock(HS)inpaperIV.TheNIH-ratHSwasestablishedusingeightfoundingratstrains(BN/SsN,MR/N,BUF/N,M520/N,WN/N,ACI/N,WKY/N,andF344/N).ToproduceanHSarandombreedingschemewassetupforabout60generationscreatingamosaicoffoundervariantsallowingthefine-mappingofQTLs.IntheHSratsusedinpaperIVthemappingresolutionforaQTLwasestimatedtolessthan3Mb107andcouldpotentiallyinsomegenomicregionsallowtheidentificationofasinglegeneresponsibleforaphenotype.
Resistant Susceptible F2 cross
x
x F1
x F2
Congenic strain Donor Recipient
Generation 1 (50% donor)
Generation 2 (25% donor)
Generation 3 (12.5% donor)
Generation 10 (< 0.5 % donor)
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4.2Identifyingdiseasecausinggenesinhumans
Identificationofgenesregulatingdiseaseinhumanswasoriginallybasedonfamiliallinkagestudieswhereregionslinkedtodiseaseusuallyrangefrom2-10Mbinspan.Duetothelowresolutiontheidentificationofgenesusingfamiliallinkagestudieshasnotbeenefficaciousincomplexdiseases.Thus,genome-wideassociationstudies(GWAs)wherelociof10-100kbcanbeidentifiedhasbeenfavoredinstead108.Here,onetakesadvantageofthefactthatpolymorphismsarenotinheritedindependently,buttogetherinlinkagedisequilibrium(LD)blocks.AroundonemillionSNPscalledtaggedSNPs,representingdifferentLDblocksacrossthegenomeisselectedandgenotypedinaffectedandnon-affectedindividuals.DuetothenumberofmarkersusedandnumberofindividualsinGWASstudies,associationsneedtobecorrectedformultipletestingtoexcludefalsepositives.Thus,highp-valuesof>10^-8isneededforgenome-widesignificans.AlthoughmanylocihavebeenidentifiedusingGWAS,alargepartofheritabilitycalledthemissingheritability,cannotbeaccountedfor109.Forexample,theheritabilityinRAisestimatedtobe~65%fromstudiesintwinshoweverinarecentGWASstudy,theidentifiedlocicanonlyaccountfor50%oftheheritability66.Thiscouldbeduetomissingrarevariantsbutalsothefactthatthegeneticmarkersused,SNPs,mightnotpickupothertypesofimportantvariantssuchasCNVsorinsertionsanddeletions.Correctcategorizationofthephenotypestudiedisalsoimportantasthepossibilityofmixedtypesofdisordersmightmaskapositiveassociation.ThisisillustratedinpaperIIwheretheneedforstratificationbasedonserologyisnecessarytoidentifyassociationtotheVAV1gene.
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5 PRESENT INVESTIGATIONS
5.1PaperI
SpontaneousmutationrevealsEndophilinA2asamajorregulatorofautoreactiveTcellsandapotentialnewtargetinautoimmunedisease
InthisstudyweidentifiedEndophilinA2(EA2),apreviouslyunknownanduniquetarget,fortreatmentofautoimmunediseases.TheimportanceofthegeneinimmuneregulatorypathwaywasdiscoveredasaconsequenceofaspontaneousmutationthatoccurredinourcolonyofratsrenderingthenormallyhighlysusceptibleDAratresistanttoinductionofarthritis.ThemutationinhibitstranscriptionofthegeneencodingEA2makingtheratanaturalknockout.Tocross-speciesconfirmEA2’sroleinprotectionagainstarthritisweusedgeneknockouttechnologyinmouse.ThegeneencodingEA2isexpressedin,andaffects,manydifferentleukocytes.However,thearthritisprotectionseeninEA2deficientanimalsismainlymediatedviaTcells.TheTcelldependencywasshownthroughpristane-primedCD4+TcelltransferexperimentsandthereconstitutionofTcellknockoutmicewithEA2deficientandwildtypethymocytesandsubsequentarthritisinduction.InvestigatingtheEA2effectonTcellsinlightofitsmolecularfunction,wesawthattheEA2deficientTcellsareunabletointernalizetheirTcellreceptortothesameextentandthusareunabletoproliferateatthesameratecomparedtonormalwildtypeTcells.ThereducedTcellfunctionleadstoadecreaseinautoreactiveTcellsandresultsinunsuccessfulinductionandsubsequentblockageofdiseaseprogression.WecouldalsoshowthattheEA2expressionwasincreasedinRApatientsandthusproposeanewinterestingpathwayinRAbywhichtheactivationofTcellscanbemodulatedusinginhibitorsofEA2.
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5.2PaperII
VAV1regulatesexperimentalautoimmunearthritisandisassociatedwithanti-CCPnegativerheumatoidarthritis
TheVav1genehadpreviouslybeendescribedtoregulateseverityinananimalmodelofmultiplesclerosisandfoundtobeassociatedinmultiplesclerosis(MS)110.InthisstudyweusedifferentanimalmodelsforRAandgeneticassociationstudiestoinvestigatetheroleofVav1inarthritis.WeimmunizedDA.BN-R25congenicratsharboringacodingvariantintheVav1geneandDAlittermatesforCIAandPIA.WhilenoeffectcouldbeobservedinCIAasignificantreductioninarthritisseveritywasfoundinPIA.AsdiscussedaboveBcelldependencyinpathogenesisinPIAandCIAseemtodiffer.StudiesondepletionofTcellsbeforeandafterestablisheddiseaseinadjuvantarthritisandCIAfurtherconfirmthisobservation111.WhiledepletionofTcellsduringprimingisbeneficialinbothadjuvantarthritisandCIA,depletionafterestablisheddiseasereducearthritisseverityonlyinadjuvantarthritiswhilenoamelioratingeffectisobservedinCIA.ThissuggeststhataftertheBcellshavebeenprimedbyTcellstheynolongerneedTcellsinordertopropagatethedisease.TheseexperimentstogetherwiththeobservedreductioninTcellproliferationseeninDA.BN-R25rats110explainwhyweonlycouldobserveregulationbyVav1inPIAandnotCIA.IntheRAcase-controlstudiesonlyaweakassociationinthetotalpopulationcouldbeobserved.However,whenstratifyingtheRApatientstoACPApositiveandACPAnegative,astrongerassociationcouldbefoundfortheACPAnegativewhilenoassociationwasfoundinACPApositivepatients.InbothPIAandACPAnegativeRAthediseaseprogressionisthoughtofasbeinglessdependentonantibodiesandinthesediseasesTcellscouldhaveamoreprominentrole.ThustakentogetherourresultsindicatethatVav1regulatesaTelldependentmechanisminarthritis.OurresultsfurtherillustratethecommonpathwayssharedbydifferentautoimmunedisordersandtheheterogeneouspopulationofRApatients.
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5.3PaperIII
PositioningofapolymorphicquantitativetraitnucleotideintheNcf1genecontrollingoxidativeburstresponseandarthritisseverityinrats
TheNcf1generegulatesproductionofROSbythephagocyteNADPHoxidasecomplexandhaspreviouslybeenassociatedwitharthritisseverityinDA.E3-Ncf1congenicrats.InterestinglythearthritisprotectiveallelefromtheE3ratincreasetheproductionofROSwhichmediateprotection.ThreecodingSNPsintheNcf1genedifferedbetweenthesusceptibleDAratandtheresistantE3rat.Tounderstandthemolecularmechanismsunderlyingtheeffectonarthritis,weneededtoidentifythearthritiscausativeSNP.MutatedrecombinantNcf1atthethreedifferentpositionsweretestedfortheireffectonROSproductioninvitro.TheSNPresponsibleforanaminoacidshiftatposition153frommethioninetothreoninewasshowntorestoredtheNcf1mediatedROSproduction.TotestthefunctionalimpactofthisSNPonarthritisdevelopment,inbredratstrainswerescreenedforpolymorphismsintheNCF1gene.Asub-strainoftheWistarratwasidentifiedwithDAallelesattwoofthethreeSNPsfoundtodifferbetweenDAandE3.OnlythethirdSNPcausingtheaminoacidshiftatposition153wasidenticaltotheE3rat.ThegenomicregioncontainingtheWistarallelicversionoftheNcf1genewasisolatedinacongenicstrainandimmunizedforarthritis.SimilartotheE3rat,thenewDA.Wistar-Ncf1congenicalsoshowedreducedarthritisseverityhighlightingthe153snpastheonlydiseaseregulatinggeneticvariant.ThuswecouldfunctionallyprovethatthereducedarthritisseverityobservedinNcf1congenicratswasduetoincreasedROSproductionandregulatedbyasinglenucleotide.
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5.4PaperIV
Combinedsequence-basedandgeneticmappinganalysisofcomplextraitsinoutbredrats
Positionallycloningofgenesisatimeconsumingandacostlyendeavor.InthefourthstudyweutilizedtheNIHheterogeneousstockforhighresolutionmappingof2000ratsoutbredratsandcollected160phenotypestoidentifygenestocomplextraitsinvolvedinforexamplemetabolism,immuneregulationandcardiovasculardisease.EightfounderstrainsoftheHSratsweresequencedandtheirsequenceimputedtohaplotypesinto1400SNPtypedoutbredratsusedinthestudy.Thestrategywasprovensuccessfulandwecouldidentify35causalgenesinvolvedin31phenotypes.
WiththeuseofflowcytometrywestudiesthefrequencyofdifferentleukocytesandexpressionofsurfacemoleculesinbloodofnaïveNIH-HSrats.Ofinteresttoourworkwas
theidentificationoftheTbx21geneinaQTLregulatingtheproportionofCD4+cellswithhighexpressionofCD25.HerethecandidatevariantintheTbx21geneleadstoaglycinetoargininesubstitutionatposition175oftheTbx21andcouldpossiblyaltertheDNA-bindingdomainofthisprotein.TheTbx21genehasbeenimplicatedinthegeneticcontrolofregulatoryTcellspreviouslyandthustheQTLregulatingCD4+CD25highcellsmightrepresentregulatorycells.Furtherinvestigationandisolationofthisvariantisneededtoconcludeanassociationtotheobservedphenotype.
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6 CONCLUDING REMARKS
LackofefficienttherapeuticsinRApatientsleadstohighsocioeconomiccostsandseverelyreducethequalityoflifefortheindividual112.Inaddition,poormanagementofco-morbiditiesandanincreasedriskofinfectionswithcurrenttherapiesleadtoanincreasedmortalityinRApatients.Thus,thereisahighunmetneedinRAandfurtherunderstandingofthediseasepathogenesisisneededtodiscovernewtherapeutics.
Hypothesisfreediscoveryofgenesinvolvedinautoimmunityusingexperimentalcrossesisavaluabletooltodiscovernewtherapies.TheidentificationoftheROSregulatingeffectoftheNcf1geneinautoimmunityhasledtothedevelopmentofROSinducersfortreatingautoimmunedisordersandhavebeenshowntoworkinarthritisinrats113.WehopethatthediscoveryofEA2canleadtonewandmoreeffectivetherapiesinautoimmunedisorderstoo.ByinhibitingEA2thereisapotentialofaddressingmanyoftheunmetneedsinRA.WiththeuseofEA2inhibitorswecouldpotentiallyaddresstwoimportantfeaturesofRA,lymphocyteactivationandtargettissuedestruction.FirstbyinhibitingtheactivationofautoreactiveTcells,whichhavebeenlinkedtothedetrimentalchroniccircleofimmunecellactivation,stoppingtheautoreactiveresponse.Second,throughpublicallyavailabledatarepositories(BioGPS)wehavefoundthatthegeneexpressionofEA2isincreasedinsynoviocytesofRApatientscomparedtohealthycontrolsandindividualssufferingfromosteoarthritis.EA2hasalsobeenshowntoregulatetheendocytosisofmembraneboundmetalloproteinases114,knowntobeimportantfordegradationoftheextracellularmatrix.ThusbytargetingEA2insynoviocytesonecanreducetheirproliferationandinhibittheirinvasivenessleadingtoasubsequentregenerationofthetargettissue.Additionally,RApatientshaveanincreasedriskofmalignancies115anditisstilldebatedwhethercurrenttreatmentscontributingtothis116.KnockingdownEA2incancercellshaveshowntoreduceproliferationandtumorinvasion117thusinhibitingEA2inRApatientsonecouldpotentiallyalsoreducetheprevalenceofmalignancies.
Insummary,theresultsofthisthesisshowthatRAisindeedaheterogeneousdiseaseandidentificationofgenescouldbenefitfromstratification,thereisanoverlapindiseasepathwaysbetweendifferentautoimmunediseasesandthatperipheraltolerancemechanismmediatedbyEndophilinA2,Vav1andNcf1arecrucialinlimitinganautoimmuneresponse.
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7 FUTURE PERSPECTIVES Positionallycloningofgenesusinganimalsisapowerfultooltofunctionallycharacterizeandstudygenesinvolvedautoimmunedisorders.Althoughprovensuccessfulinthisthesis,theidentificationofgenesusingF2crossesandisolationincongenicstrainsisatimeconsumingendeavor.Withtheintroductionofnewtechnologiesinthe‘omicseraandthedropinpricesofsequencing,directstudiesinhumanscomparinggenotypetophenotypewillprobablyreplacemanyoftheanimalstudies.However,theneedforanimalmodelswillnotdecline,asmanyofthefindingsinhumanswillneedfunctionalcharacterizationandvalidationinanimals.Additionally,theneedformanydifferentanimalmodelsmimickingdifferentsubgroups,asevidentinwiththeVAV1gene,willbevaluablewhendevelopingnewtherapeutics.
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8 ACKNOWLEDGEMENT Iguessthisisthemostimportantpartofthethesistomostofmyreaders.Itistometoo!Ihavehadtheprivilegetomeetandworkwithsomanysmart,talentedandhardworkingpeopleduringmyPhDstudiesandithasbeentrulyinspiring.Researchershavethemostexcitingjobintheworldbutalsothemostfrustratingattimeswithfailedexperiments(forwhatsometimesappeartobewithoutanyreasonableexplanation)andwithoutmyfellowscientificfriendsIwouldhavegivenupalongtimeago.I’vemadefriendsforlife.Sothankyouforbeingthereandmakingmyexperiencesospecial.
Tomysupervisors:
RikardHolmdahl,foryourvisionaryapproachtoscience,sharedpassionfornovelfindingsandthefreedomyouhavegivenmetofollowmyideasanddreams(whichIhavetakenfulladvantageof,myapologies).
LiselotteBäckdahl,foryourinvaluablehelpandmentalsupport,neverlettingmegiveupalwayssaying”youaresoclosenow”insuchaconvincingwaythatIactuallybelievedyou.
JohanBäcklund,foryourloveofskånskaanddiscussionsaboutourlovelyrats.
TotheMIRfamilymembers:
AngelYao-Mattisson,foryourlovingcare,makingsureweallgetacknowledgedonourspecialdaysandyoureffortsintryingtokeepussocial.CarlosandKristina,formakingmefeellikeatinypartinyourfamilyandthedescentdowntotheanimalhousemoreamicable.KatrinKlocke,mylife-fixer,foralwaysbeingreadytolendahand,teachingmehowtomakegreatfiguresandmakingsurewehaveamazingcakesatvariousevent.CarolaRinstisch,forteachingmeallaboutratgeneticsandlayingasolidgeneticfoundationintheDACPproject.DianaEkman,thequeenofbioinformatics,foryourinvaluablehelpwithduringtheHSprojectandtheNGSstudies.FlorianForster,forventuringoutintotheTCRsignalingworldwithme.LiseuMeng,foryourhappyspiritandallyourhelpwiththeanimalsandcontinuingtheGOIgroupinChina.LinaOlsson,forbeingthelab’slinktohumanstudiesandteachingmeallabouthumangeneticsandbeinganoutletforfrustrationduringroughtimes.AngelaPizolla,forallourtalksaboutworkandlifegoingtoandfromthelabandgreattimesinJapanandvästraskogen.MichaelFörster,forallgreatmemoriesandyourenthusiasminlifeandwork.IdaAndersson,forallgreatmommydiscussionsduringmy/ourpregnancyandfuntimesduringmaternityleave.IngridLindh,forhavingafriendfromtheverybeginning,includingmeinlabactivitiesandmakingmefeelathomeinthelabfromthestart.BingzeXu,foryourimpressivespeedyandaccurateexecutionofwhatevermaycomeyourwaye.g.GOIproteinbindingassays.DanielleVaartjees,forkeepingmementallyandphysicallyfitandprocrastinatingInstapicsduringthesiswriting.AnthonyYau,forsharingthetrialsandtribulationofworkingwithratsandratgeneticswithme.ErikLönnblom,foryournever-endingsourceofinterestingconversationtopics.
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JaimeJames,forsharingthesameexcellenttasteinmusicandoursing-a-longs.GonzaloLahore-Fernandez,forthesmart-offchallenge(BTW,IthinkI’mwinning).MikeAuon,forthecontroversialandfundiscussionsaboutanythingandeverything.AmitSaxena,forourjointlysharedpassionofreachingforthestars.ClaraMarquinas,foryourgreatsenseofhumorandbeinganamazingkaraokepartner.ChangrongGe,foryourhelpwiththeGOIcrystalsandbindingassays.VilmaUrbonaviciute,forallyoursmartinputsandsharedideas.MinYang,forourlunchdatesdiscussinglife,loveandscience.SusannWinter,foryourcoolandcalm.EmmaMondoc,forneversayingnowhenIwanttoordersomethinganddiscussionsaboutleadingahealthierlifestyle.PatrickMerkyandSaraLind-Enoksson,foralwayshavingtheWednesdaylunchestolookforwardtoandyourflowcytometryexcellence.MartinaJohannesson,forbeingagenuinelykindpersonandourdiscussionsregardingtheHSproject.BrunoRaposo,foralwaysshowinganinterestinmyworkduringseminars.NandakumarKuttySelva(Nan),foryourphilosophicalinputduringseminarsmakingusthinkofthebiggerpicture.KajsaWing,forexcellentinputwheneverIhaveanissueIwanttodiscuss.Biborka,forallyourgreathelpwiththeanimaladministrationandprovidingthelabmemberswithfinejewelry.Bibo,forexpandingmytasteinChinesefood.Naru,foryourpeacefulways.Dongmei,for”sharing”variouslabequipmentwithme.SusannevandenBerg,formakingsurewekeepthelabinthestateitshouldbeforanefficientandsafeworkplace.JianghongZhong,foryourtirelessnessattitudetowardswork.HuseyinUysalfornicebaklavaafterRamadanandinterestingdiscussions.DorotaKlaczkowska,foryourrelaxedandfunattitude.IaKhmaladze,forfindingafriendintheanimalhouseduringstrangehours.FridaLaulundforstandingyourgroundandnicefikasoutsidethelab.OutiSareila,fornicewineandspaexperiences.CeciliaHagert,forfundiscussions.SimonGuerard,forthemotivatingquickexit.JonatanTuncel,forintroducingmetotheHS-project.SabrinaHaag,formakinglatenightsinthelablesslonely.ChristophandKatarinaKessel,forallthenicetimesatdinnersandparties.MarcusHoffman,forinterestingscientificandnon-scientificdiscussions.MalinHultqvistandPeterOlofsson,forpavingthepathwithyourworkonNcf1anddiscussionsregardingstart-ups.FranziskaLange,forgivingthearrivaltoStockholmafamiliarfeeling.ThereseLindvallandTiinaKelkkafornicetimesinLund.GuotianLuo,forstartinguptheoncologysectionofMIR.ThomasBlom,forallyourhelpandsupportinLund.Animalhousestaff,Isabelle,Evelina,Lina,Lilu,Jinlianfortakingexcellentcareoftheanimalsthroughouttheyears
Tomydream-team:
EveryoneatKIABandmycoachesMarkFarmery,foryourmentoringandencouragementandChristianKrog-Jensen,forgreatinputonmyproject.TheChemicalbiologicalconsortiumSwedenatKI,ThomasLundbäck,forteachingmesomuchaboutproteinchemistryanddrugdiscoveryusingsmallmolecules.MartinHaraldsson,forallyourworkonthemoleculesandourdiscussions.HannaAxelsson,forallyourworkontheGOIassay
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development.TomasNymanatSPF,forallyourhelpwiththeprotein-bindingstudies.
Tomycollaborators:
ProfessorTomasOlssonandyourwonderfulgroupforgreatcollaborationsandfuntimes,inparticularPernilla,Petra,Andre,Maja,Melanie,Amennai,RasmusandNada.LeonidPadyukov,ProfessorIngridKockum,AlexandraGyllenberg,IngerGjertsson,MariaBergquist,TulayLindberg,AnnaKatsandKajaErikssonforgreatcollaborations.TheHSgroupinparticularAlberto,Esther,Regina,Toni,Gloria,Carme,Amelie,ErikWandJonathanforgreatcollaborationsandfuntimes.
Tomyscientificcommunity:
BobHarris,myun-officialmentor,forourdiscussionsonresearchandresearcheducationandyournoBSapproachbutmostimportantlyforthefeelingthatsomeonehadmyback.
PeopleintheDoctoralstudent’sassociationArash,Åsa,Hugo,Marcus,Sonal,Yuan,JayeshandBoardofresearcheducationProfessorsAndersGustavsson,MarianneSchultzberg,LarsAlfredsson,KristinaBroliden,LenavonKochandLennartNilssonforinterestingandimportantdiscussionsregardingresearcheducationin2012.
Mystudents,BeatriceBergström,AnetteFriberg,EllinoreJanssonandMalinLjunggrenforimprovingmypedagogicskillsandhelpingmybecomeabetterteacher.
Tomyfamilyandfriends:
Tomydearestfriendsfortakingmymindoffworkandmakingmylifesospecialandfuneveryday.Minkärafamilj,mammaochpappaföralldenkärleknigerossochattnilärtosskännaempatifördesomhardetsämre.Mamma,förallatelefonsamtaltillochfrånjobbetsenakvällarochnätterochbarnpassningnärvibehövdedetsommest.Pappa,förattdualdriglätossvinnaispelnärvivarsmåsomgjortattjaginterädskämpaiunderlägeochintegermig.Finastesyskonenmankanönskasig,KarinochRickard,förallaroligastundervihartillsammansocherkärlekochuppmuntrangenomlivet,jagharalltidenvänier.MinandrafamiljAgneta,RaymondochÅse,förattniinkluderademigieralivfrånförstabörjanochallhjälpmedVille.
MinälskadeBjörn,vadvorejagutandig.Dugermittlivvärdeochgördetmervackertvarjedag.Dinuppmuntranochtropåmigochminaförmågorhargjortattjagorkatkämpapåmångagångernärjagvillegeupp.Särskilttackföralltditttålamodochstödpåsistatiden.VårfinasonVilhelm,minälskadesolstråle,förattdulyseruppävendengråasteavdagar.Duärredansåklokochjagsermedspänningframemotalltvadduskatadigförilivet.
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9 REFERENCES
1. Cooper,G.S.,Bynum,M.L.K.&Somers,E.C.Recentinsightsintheepidemiologyofautoimmunediseases:improvedprevalenceestimatesandunderstandingofclusteringofdiseases.J.Autoimmun.33,197–207(2009).
2. Baxter,A.G.Immunogeneticsandthecauseofautoimmunedisease.Autoimmunity25,177–189(1997).
3. Haegert,D.G.Analysisofthethresholdliabilitymodelprovidesnewunderstandingofcausationinautoimmunediseases.Med.Hypotheses63,257–261(2004).
4. vanderHelm-vanMil,A.H.M.etal.AnindependentroleofprotectiveHLAclassIIallelesinrheumatoidarthritisseverityandsusceptibility.ArthritisRheum.52,2637–2644(2005).
5. Bogdanos,D.P.etal.Twinstudiesinautoimmunedisease:genetics,genderandenvironment.J.Autoimmun.38,J156–69(2012).
6. Cárdenas-Roldán,J.,Rojas-Villarraga,A.&Anaya,J.-M.Howdoautoimmunediseasesclusterinfamilies?Asystematicreviewandmeta-analysis.BMCMed11,73(2013).
7. Gough,S.C.L.&Simmonds,M.J.TheHLARegionandAutoimmuneDisease:AssociationsandMechanismsofAction.Curr.Genomics8,453–465(2007).
8. Parkes,M.,Cortes,A.,vanHeel,D.A.&Brown,M.A.Geneticinsightsintocommonpathwaysandcomplexrelationshipsamongimmune-mediateddiseases.NatureReviewsGenetics14,661–673(2013).
9. Rosman,Z.,Shoenfeld,Y.&Zandman-Goddard,G.Biologictherapyforautoimmunediseases:anupdate.BMCMed11,755(2013).
10. Herrath,von,M.G.,Fujinami,R.S.&Whitton,J.L.Microorganismsandautoimmunity:makingthebarrenfieldfertile?Nat.Rev.Microbiol.1,151–157(2003).
11. Stamnaes,J.&Sollid,L.M.Celiacdisease:Autoimmunityinresponsetofoodantigen.SeminarsinImmunology27,343–352(2015).
12. Honda,K.&Littman,D.R.Themicrobiotainadaptiveimmunehomeostasisanddisease.Nature535,75–84(2016).
13. Wu,H.-J.etal.Gut-residingsegmentedfilamentousbacteriadriveautoimmunearthritisviaThelper17cells.Immunity32,815–827(2010).
14. Cusick,M.F.,Libbey,J.E.&Fujinami,R.S.Molecularmimicryasamechanismofautoimmunedisease.ClinRevAllergyImmunol42,102–111(2012).
15. Roep,B.O.etal.Molecularmimicryintype1diabetes:immunecross-reactivitybetweenisletautoantigenandhumancytomegalovirusbutnotCoxsackievirus.Ann.N.Y.Acad.Sci.958,163–165(2002).
16. Pruksakorn,S.etal.IdentificationofTcellautoepitopesthatcross-reactwiththeC-terminalsegmentoftheMproteinofgroupAstreptococci.Int.Immunol.6,1235–1244(1994).
17. Rantapää-Dahlqvist,S.etal.AntibodiesagainstcycliccitrullinatedpeptideandIgArheumatoidfactorpredictthedevelopmentofrheumatoidarthritis.ArthritisRheum.48,2741–2749(2003).
18. Cho,J.H.&Feldman,M.Heterogeneityofautoimmunediseases:pathophysiologicinsightsfromgeneticsandimplicationsfornewtherapies.Nat.Med.21,730–738(2015).
27
19. vanMeerwijk,J.P.etal.QuantitativeimpactofthymicclonaldeletionontheTcellrepertoire.JournalofExperimentalMedicine185,377–383(1997).
20. Surh,C.D.&Sprent,J.T-cellapoptosisdetectedinsituduringpositiveandnegativeselectioninthethymus.Nature372,100–103(1994).
21. Palmer,E.Negativeselection--clearingoutthebadapplesfromtheT-cellrepertoire.Nat.Rev.Immunol.3,383–391(2003).
22. Derbinski,J.,Schulte,A.,Kyewski,B.&Klein,L.Promiscuousgeneexpressioninmedullarythymicepithelialcellsmirrorstheperipheralself.NatureImmunology2,1032–1039(2001).
23. Anderson,M.S.etal.Projectionofanimmunologicalselfshadowwithinthethymusbytheaireprotein.Science298,1395–1401(2002).
24. Pitkänen,J.&Peterson,P.Autoimmuneregulator:fromlossoffunctiontoautoimmunity.GenesImmun.4,12–21(2003).
25. Danke,N.A.,Koelle,D.M.,Yee,C.,Beheray,S.&Kwok,W.W.AutoreactiveTcellsinhealthyindividuals.J.Immunol.172,5967–5972(2004).
26. Doyle,H.A.&Mamula,M.J.Autoantigenesis:theevolutionofproteinmodificationsinautoimmunedisease.Curr.Opin.Immunol.24,112–118(2012).
27. Chemin,K.etal.ANovelHLA-DRB1*10:01-RestrictedTCellEpitopeFromCitrullinatedTypeIICollagenRelevanttoRheumatoidArthritis.ArthritisRheumatol68,1124–1135(2016).
28. Klein,L.,Klugmann,M.,Nave,K.A.,Tuohy,V.K.&Kyewski,B.ShapingoftheautoreactiveT-cellrepertoirebyasplicevariantofselfproteinexpressedinthymicepithelialcells.Nat.Med.6,56–61(2000).
29. Kurts,C.,Miller,J.F.,Subramaniam,R.M.,Carbone,F.R.&Heath,W.R.MajorhistocompatibilitycomplexclassI-restrictedcross-presentationisbiasedtowardshighdoseantigensandthosereleasedduringcellulardestruction.JournalofExperimentalMedicine188,409–414(1998).
30. Streilein,J.W.,Wilbanks,G.A.&Cousins,S.W.Immunoregulatorymechanismsoftheeye.J.Neuroimmunol.39,185–200(1992).
31. Jenkins,M.K.&Schwartz,R.H.Antigenpresentationbychemicallymodifiedsplenocytesinducesantigen-specificTcellunresponsivenessinvitroandinvivo.JournalofExperimentalMedicine165,302–319(1987).
32. Walunas,T.L.&Bluestone,J.A.CTLA-4regulatestoleranceinductionandTcelldifferentiationinvivo.J.Immunol.160,3855–3860(1998).
33. Nishimura,H.,Nose,M.,Hiai,H.,Minato,N.&Honjo,T.Developmentoflupus-likeautoimmunediseasesbydisruptionofthePD-1geneencodinganITIMmotif-carryingimmunoreceptor.Immunity11,141–151(1999).
34. Wing,K.&Sakaguchi,S.RegulatoryTcellsexertchecksandbalancesonselftoleranceandautoimmunity.NatureImmunology11,7–13(2010).
35. Bacchetta,R.,Barzaghi,F.&Roncarolo,M.-G.FromIPEXsyndrometoFOXP3mutation:alessononimmunedysregulation.Ann.N.Y.Acad.Sci.n/a–n/a(2016).doi:10.1111/nyas.13011
36. García-González,P.,Ubilla-Olguín,G.,Catalán,D.,Schinnerling,K.&Aguillón,J.C.Tolerogenicdendriticcellsforreprogrammingoflymphocyteresponsesinautoimmunediseases.AutoimmunRev15,1071–1080(2016).
37. Kühn,R.,Löhler,J.,Rennick,D.,Rajewsky,K.&Müller,W.Interleukin-10-deficientmicedevelopchronicenterocolitis.Cell75,263–274(1993).
38. Gelderman,K.A.,Hultqvist,M.,Holmberg,J.,Olofsson,P.&Holmdahl,R.TcellsurfaceredoxlevelsdetermineTcellreactivityandarthritissusceptibility.Proc.
28
Natl.Acad.Sci.U.S.A.103,12831–12836(2006).39. Walker,L.S.K.&Abbas,A.K.THEENEMYWITHIN:KEEPINGSELF-REACTIVET
CELLSATBAYINTHEPERIPHERY.Nat.Rev.Immunol.2,11–19(2002).40. Storey,G.O.,Comer,M.&Scott,D.L.Chronicarthritisbefore1876:earlyBritish
casessuggestingrheumatoidarthritis.Ann.Rheum.Dis.53,557–560(1994).41. Entezami,P.,Fox,D.A.,Clapham,P.J.&Chung,K.C.Historicalperspectiveonthe
etiologyofrheumatoidarthritis.HandClin27,1–10(2011).42. Cojocaru,M.,Cojocaru,I.M.,Silosi,I.,Vrabie,C.D.&Tanasescu,R.Extra-articular
ManifestationsinRheumatoidArthritis.Maedica(Buchar)5,286–291(2010).43. Gabriel,S.E.&Michaud,K.Epidemiologicalstudiesinincidence,prevalence,
mortality,andcomorbidityoftherheumaticdiseases.ArthritisRes.Ther.11,229(2009).
44. Aletaha,D.etal.2010Rheumatoidarthritisclassificationcriteria:anAmericanCollegeofRheumatology/EuropeanLeagueAgainstRheumatismcollaborativeinitiative.ArthritisRheum.62,2569–2581(2010).
45. McInnes,I.B.&Schett,G.Thepathogenesisofrheumatoidarthritis.N.Engl.J.Med.365,2205–2219(2011).
46. Schellekens,G.A.etal.Thediagnosticpropertiesofrheumatoidarthritisantibodiesrecognizingacycliccitrullinatedpeptide.ArthritisRheum.43,155–163(2000).
47. Jilani,A.A.&Mackworth-Young,C.G.Theroleofcitrullinatedproteinantibodiesinpredictingerosivediseaseinrheumatoidarthritis:asystematicliteraturereviewandmeta-analysis.IntJRheumatol2015,728610–8(2015).
48. Gullick,N.J.&Scott,D.L.Co-morbiditiesinestablishedrheumatoidarthritis.BestPractResClinRheumatol25,469–483(2011).
49. Wolfe,F.etal.Themortalityofrheumatoidarthritis.ArthritisRheum.37,481–494(1994).
50. Gibofsky,A.Currenttherapeuticagentsandtreatmentparadigmsforthemanagementofrheumatoidarthritis.AmJManagCare20,S136–44(2014).
51. Smolen,J.S.&Aletaha,D.Rheumatoidarthritistherapyreappraisal:strategies,opportunitiesandchallenges.NatRevRheumatol11,276–289(2015).
52. Singh,J.A.etal.2012updateofthe2008AmericanCollegeofRheumatologyrecommendationsfortheuseofdisease-modifyingantirheumaticdrugsandbiologicagentsinthetreatmentofrheumatoidarthritis.ArthritisCareRes(Hoboken)64,625–639(2012).
53. Wessels,J.A.M.,Huizinga,T.W.J.&Guchelaar,H.-J.Recentinsightsinthepharmacologicalactionsofmethotrexateinthetreatmentofrheumatoidarthritis.Rheumatology(Oxford)47,249–255(2008).
54. Feldmann,M.&Maini,R.N.Anti-TNFalphatherapyofrheumatoidarthritis:whathavewelearned?Annu.Rev.Immunol.19,163–196(2001).
55. Keffer,J.etal.Transgenicmiceexpressinghumantumournecrosisfactor:apredictivegeneticmodelofarthritis.EMBOJ.10,4025–4031(1991).
56. Ali,T.etal.Clinicaluseofanti-TNFtherapyandincreasedriskofinfections.DrugHealthcPatientSaf5,79–99(2013).
57. Smolen,J.S.,Aletaha,D.&McInnes,I.B.Rheumatoidarthritis.TheLancet388,2023–2038(2016).
58. Sardar,S.&Andersson,Å.OldandnewtherapeuticsforRheumatoidArthritis:invivomodelsanddrugdevelopment.ImmunopharmacolImmunotoxicol38,2–13(2016).
29
59. vanderWoude,D.etal.Quantitativeheritabilityofanti-citrullinatedproteinantibody-positiveandanti-citrullinatedproteinantibody-negativerheumatoidarthritis.ArthritisRheum.60,916–923(2009).
60. Stastny,P.Mixedlymphocyteculturesinrheumatoidarthritis.JournalofClinicalInvestigation57,1148–1157(1976).
61. Stastny,P.AssociationoftheB-cellalloantigenDRw4withrheumatoidarthritis.N.Engl.J.Med.298,869–871(1978).
62. Gibofsky,A.,Winchester,R.J.,Patarroyo,M.,Fotino,M.&Kunkel,H.G.DiseaseassociationsoftheIa-likehumanalloantigens.Contrastingpatternsinrheumatoidarthritisandsystemiclupuserythematosus.JournalofExperimentalMedicine148,1728–1732(1978).
63. Gregersen,P.K.,Silver,J.&Winchester,R.J.Thesharedepitopehypothesis.Anapproachtounderstandingthemoleculargeneticsofsusceptibilitytorheumatoidarthritis.ArthritisRheum.30,1205–1213(1987).
64. Raychaudhuri,S.etal.FiveaminoacidsinthreeHLAproteinsexplainmostoftheassociationbetweenMHCandseropositiverheumatoidarthritis.NatureGenetics44,291–296(2012).
65. Begovich,A.B.etal.Amissensesingle-nucleotidepolymorphisminageneencodingaproteintyrosinephosphatase(PTPN22)isassociatedwithrheumatoidarthritis.Am.J.Hum.Genet.75,330–337(2004).
66. Eyre,S.etal.High-densitygeneticmappingidentifiesnewsusceptibilitylociforrheumatoidarthritis.NatureGenetics44,1336–1340(2012).
67. Frisell,T.etal.Familialaggregationofarthritis-relateddiseasesinseropositiveandseronegativerheumatoidarthritis:aregister-basedcase-controlstudyinSweden.Ann.Rheum.Dis.75,183–189(2016).
68. Padyukov,L.etal.Agenome-wideassociationstudysuggestscontrastingassociationsinACPA-positiveversusACPA-negativerheumatoidarthritis.Ann.Rheum.Dis.70,259–265(2011).
69. Malmström,V.,Catrina,A.I.&Klareskog,L.Theimmunopathogenesisofseropositiverheumatoidarthritis:fromtriggeringtotargeting.Nat.Rev.Immunol.17,60–75(2017).
70. Klareskog,L.etal.Anewmodelforanetiologyofrheumatoidarthritis:smokingmaytriggerHLA-DR(sharedepitope)-restrictedimmunereactionstoautoantigensmodifiedbycitrullination.ArthritisRheum.54,38–46(2006).
71. Farquharson,D.,Butcher,J.P.&Culshaw,S.Periodontitis,Porphyromonas,andthepathogenesisofrheumatoidarthritis.MucosalImmunol5,112–120(2012).
72. Zhang,X.etal.Theoralandgutmicrobiomesareperturbedinrheumatoidarthritisandpartlynormalizedaftertreatment.Nat.Med.21,895–905(2015).
73. Liao,K.P.,Alfredsson,L.&Karlson,E.W.Environmentalinfluencesonriskforrheumatoidarthritis.CurrOpinRheumatol21,279–283(2009).
74. Sverdrup,B.etal.Associationbetweenoccupationalexposuretomineraloilandrheumatoidarthritis:resultsfromtheSwedishEIRAcase-controlstudy.ArthritisRes.Ther.7,R1296–303(2005).
75. Wang,Z.,Fingas,M.&Sigouin,L.UsingMultipleCriteriaforFingerprintingUnknownOilSamplesHavingVerySimilarChemicalComposition.EnvironmentalForensics3,251–262(2002).
76. Bevaart,L.,Vervoordeldonk,M.J.&Tak,P.P.Evaluationoftherapeutictargetsinanimalmodelsofarthritis:howdoesitrelatetorheumatoidarthritis?ArthritisRheum.62,2192–2205(2010).
30
77. Benson,J.M.etal.Discoveryandmechanismofustekinumab:ahumanmonoclonalantibodytargetinginterleukin-12andinterleukin-23fortreatmentofimmune-mediateddisorders.MAbs3,535–545(2011).
78. Hegen,M.,Keith,J.C.,Collins,M.&Nickerson-Nutter,C.L.Utilityofanimalmodelsforidentificationofpotentialtherapeuticsforrheumatoidarthritis.Ann.Rheum.Dis.67,1505–1515(2008).
79. Courtenay,J.S.,Dallman,M.J.,Dayan,A.D.,Martin,A.&Mosedale,B.ImmunisationagainstheterologoustypeIIcollageninducesarthritisinmice.Nature283,666–668(1980).
80. Trentham,D.E.AutoimmunitytotypeIIcollagenanexperimentalmodelofarthritis.JournalofExperimentalMedicine146,857–868(1977).
81. Cathcart,E.S.,Hayes,K.C.,Gonnerman,W.A.,Lazzari,A.A.&Franzblau,C.Experimentalarthritisinanonhumanprimate.I.InductionbybovinetypeIIcollagen.Lab.Invest.54,26–31(1986).
82. Holmdahl,R.,Bockermann,R.,Bäcklund,J.&Yamada,H.Themolecularpathogenesisofcollagen-inducedarthritisinmice--amodelforrheumatoidarthritis.AgeingRes.Rev.1,135–147(2002).
83. Stuart,J.M.,Cremer,M.A.,Townes,A.S.&Kang,A.H.TypeIIcollagen-inducedarthritisinrats.PassivetransferwithserumandevidencethatIgGanticollagenantibodiescancausearthritis.JournalofExperimentalMedicine155,1–16(1982).
84. Stuart,J.M.&Dixon,F.J.Serumtransferofcollagen-inducedarthritisinmice.JournalofExperimentalMedicine158,378–392(1983).
85. Wooley,P.H.,Luthra,H.S.,Stuart,J.M.&David,C.S.TypeIIcollagen-inducedarthritisinmice.I.Majorhistocompatibilitycomplex(Iregion)linkageandantibodycorrelates.JournalofExperimentalMedicine154,688–700(1981).
86. McIndoe,R.A.etal.Localizationofnon-Mhccollagen-inducedarthritissusceptibilitylociinDBA/1jmice.Proc.Natl.Acad.Sci.U.S.A.96,2210–2214(1999).
87. Lindh,I.etal.TypeIIcollagenantibodyresponseisenrichedinthesynovialfluidofrheumatoidjointsanddirectedtothesamemajorepitopesasincollageninducedarthritisinprimatesandmice.ArthritisRes.Ther.16,R143(2014).
88. Snir,O.etal.MultifunctionalTcellreactivitywithnativeandglycosylatedtypeIIcollageninrheumatoidarthritis.ArthritisRheum.64,2482–2488(2012).
89. Vingsbo,C.etal.Pristane-inducedarthritisinrats:anewmodelforrheumatoidarthritiswithachronicdiseasecourseinfluencedbybothmajorhistocompatibilitycomplexandnon-majorhistocompatibilitycomplexgenes.Am.J.Pathol.149,1675–1683(1996).
90. Kleinau,S.&Klareskog,L.Oil-inducedarthritisinDAratspassivetransferbyTcellsbutnotwithserum.J.Autoimmun.6,449–458(1993).
91. Hoffmann,M.H.etal.Therheumatoidarthritis-associatedautoantigenhnRNP-A2(RA33)isamajorstimulatorofautoimmunityinratswithpristane-inducedarthritis.J.Immunol.179,7568–7576(2007).
92. Tuncel,J.etal.ClassIImajorhistocompatibilitycomplex-associatedresponsetotypeXIcollagenregulatesthedevelopmentofchronicarthritisinrats.ArthritisRheum.64,2537–2547(2012).
93. Fritsch,R.etal.CharacterizationofautoreactiveTcellstotheautoantigensheterogeneousnuclearribonucleoproteinA2(RA33)andfilaggrininpatientswithrheumatoidarthritis.J.Immunol.169,1068–1076(2002).
94. Jäälinoja,J.etal.SerumantibodiesagainstintacthumancollagenIXareelevated
31
atonsetofrheumatoidarthritisbutarenotrelatedtodevelopmentoferosions.J.Rheumatol.35,745–751(2008).
95. Tuncel,J.etal.AnimalModelsofRheumatoidArthritis(I):Pristane-InducedArthritisintheRat.PLOSONE11,e0155936(2016).
96. Holmberg,J.etal.Pristane,anon-antigenicadjuvant,inducesMHCclassII-restricted,arthritogenicTcellsintherat.J.Immunol.176,1172–1179(2006).
97. Potter,M.&Wax,J.S.Geneticsofsusceptibilitytopristane-inducedplasmacytomasinBALB/cAn:reducedsusceptibilityinBALB/cJwithabriefdescriptionofpristane-inducedarthritis.J.Immunol.127,1591–1595(1981).
98. Hopkins,S.J.,Freemont,A.J.&Jayson,M.I.Pristane-inducedarthritisinBalb/cmice.I.Clinicalandhistologicalfeaturesofthearthropathy.Rheumatol.Int.5,21–28(1984).
99. Kouskoff,V.etal.Organ-specificdiseaseprovokedbysystemicautoimmunity.Cell87,811–822(1996).
100. Maccioni,M.etal.ArthritogenicmonoclonalantibodiesfromK/BxNmice.JournalofExperimentalMedicine195,1071–1077(2002).
101. Matsumoto,I.etal.Howantibodiestoaubiquitouscytoplasmicenzymemayprovokejoint-specificautoimmunedisease.NatureImmunology3,360–365(2002).
102. Pizzolla,A.,Wing,K.&Holmdahl,R.Aglucose-6-phosphateisomerasepeptideinducesTandBcell-dependentchronicarthritisinC57BL/10mice:arthritiswithoutreactiveoxygenspeciesandcomplement.Am.J.Pathol.183,1144–1155(2013).
103. Schaller,M.,Burton,D.R.&Ditzel,H.J.AutoantibodiestoGPIinrheumatoidarthritis:linkagebetweenananimalmodelandhumandisease.NatureImmunology2,746–753(2001).
104. Olsson,L.M.etal.CopynumbervariationofthegeneNCF1isassociatedwithrheumatoidarthritis.Antioxidants&RedoxSignaling16,71–78(2012).
105. MORTON,N.E.Sequentialtestsforthedetectionoflinkage.Am.J.Hum.Genet.7,277–318(1955).
106. Flint,J.,Valdar,W.,Shifman,S.&Mott,R.Strategiesformappingandcloningquantitativetraitgenesinrodents.NatureReviewsGenetics6,271–286(2005).
107. Johannesson,M.etal.Aresourceforthesimultaneoushigh-resolutionmappingofmultiplequantitativetraitlociinrats:theNIHheterogeneousstock.GenomeRes.19,150–158(2009).
108. Altshuler,D.,Daly,M.J.&Lander,E.S.GeneticMappinginHumanDisease.Science322,881–888(2008).
109. Manolio,T.A.etal.Findingthemissingheritabilityofcomplexdiseases.Nature461,747–753(2009).
110. Jagodic,M.etal.AroleforVAV1inexperimentalautoimmuneencephalomyelitisandmultiplesclerosis.SciTranslMed1,10ra21–10ra21(2009).
111. Yoshino,S.&Cleland,L.G.Depletionofalpha/betaTcellsbyamonoclonalantibodyagainstthealpha/betaTcellreceptorsuppressesestablishedadjuvantarthritis,butnotestablishedcollagen-inducedarthritisinrats.JournalofExperimentalMedicine175,907–915(1992).
112. Taylor,P.C.,Moore,A.,Vasilescu,R.,Alvir,J.&Tarallo,M.Astructuredliteraturereviewoftheburdenofillnessandunmetneedsinpatientswithrheumatoidarthritis:acurrentperspective.Rheumatol.Int.36,685–695(2016).
113. Hultqvist,M.,Olofsson,P.,Wallner,F.K.&Holmdahl,R.Pharmacological
32
PotentialofNOX2AgonistsinInflammatoryConditions.Antioxidants&RedoxSignaling23,446–459(2015).
114. Wu,X.,Gan,B.,Yoo,Y.&Guan,J.-L.FAK-mediatedsrcphosphorylationofendophilinA2inhibitsendocytosisofMT1-MMPandpromotesECMdegradation.Dev.Cell9,185–196(2005).
115. Simon,T.A.,Thompson,A.,Gandhi,K.K.,Hochberg,M.C.&Suissa,S.Incidenceofmalignancyinadultpatientswithrheumatoidarthritis:ameta-analysis.ArthritisRes.Ther.17,2569(2015).
116. Chen,Y.,Friedman,M.,Liu,G.,Deodhar,A.&Chu,C.-Q.Dotumornecrosisfactorinhibitorsincreasecancerriskinpatientswithchronicimmune-mediatedinflammatorydisorders?Cytokine(2016).doi:10.1016/j.cyto.2016.09.013
117. Baldassarre,T.etal.EndophilinA2PromotesTNBCCellInvasionandTumorMetastasis.MolecularCancerResearch13,1044–1055(2015).
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