Anti-thymocyte globulin (ATG) differentially depletes naïve and memory T cells and permits memory-type regulatory T cell...

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Title:
Anti-thymocyte globulin (ATG) differentially depletes naïve and memory T cells and permits memory-type regulatory T cells in nonobese diabetic mice
Physical Description:
Mixed Material
Language:
English
Creator:
Xia, Chang-Qing
Chernatynskaya, Anna V.
Wasserfall, Clive H.
Wan, Suigui
Looney, Benjamin M.
Eisenbeis, Scott
Williams, John
Clare-Salzler, Michael J.
Atkinson, Mark A.
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Bio-Med Central (BMC Immunology)
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Abstract:
Background: ATG has been employed to deplete T cells in several immune-mediated conditions. However, whether ATG administration affects naïve and memory T cell differently is largely unknown. The context and purpose of the study: In this study, we assessed how murine ATG therapy affected T cell subsets in NOD mice, based on their regulatory and naïve or memory phenotype, as well as its influence on antigen-specific immune responses. Results: Peripheral blood CD4+ and CD8+ T cells post-ATG therapy declined to their lowest levels at day 3, while CD4+ T cells returned to normal levels more rapidly than CD8+ T cells. ATG therapy failed to eliminate antigen-primed T cells. CD4+ T cell responses post-ATG therapy skewed to T helper type 2 (Th2) and possibly IL-10-producing T regulatory type 1 (Tr1) cells. Intriguingly, Foxp3+ regulatory T cells (Tregs) were less sensitive to ATG depletion and remained at higher levels following in vivo recovery compared to controls. Of note, the frequency of Foxp3+ Tregs with memory T cell phenotype was significantly increased in ATG-treated animals. Conclusion: ATG therapy may modulate antigen-specific immune responses through inducing memory-like regulatory T cells as well as other protective T cells such as Th2 and IL-10-producing Tr1 cells. Keywords: Anti-thymocyte globulin, Naïve and memory T cells, Regulatory T cells, T helper cell, Autoimmune diabetes, Nonobese diabetic mouse
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Publication of this article was funded in part by the University of Florida Open-Access publishing Fund. In addition, reqestors receiving funding through the UFOAP project are expected to submit a post-review, final draft of the article to UF's institutional repository, IR@UF, (www.uflib.ufl.edu/UFir) at the time of funding. The institutional Repository at the University of Florida community, with research, news, outreach, and educational materials.
General Note:
Xia et al. BMC Immunology 2012, 13:70 http://www.biomedcentral.com/1471-2172/13/70; Pages 1-13
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doi:10.1186/1471-2172-13-70 Cite this article as: Xia et al.: Anti-thymocyte globulin (ATG) differentially depletes naïve and memory T cells and permits memory-type regulatory T cells in nonobese diabetic mice. BMC Immunology 2012 13:70.

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RESEARCHARTICLEOpenAccessAnti-thymocyteglobulin(ATG)differentially depletesnaveandmemoryTcellsandpermits memory-typeregulatoryTcellsinnonobese diabeticmiceChang-QingXia1,2*,AnnaVChernatynskaya2,CliveHWasserfall2,SuiguiWan1,BenjaminMLooney2, ScottEisenbeis3,JohnWilliams3,MichaelJClare-Salzler2andMarkAAtkinson2AbstractBackground: ATGhasbeenemployedtodepleteTcellsinseveralimmune-mediatedconditions.However, whetherATGadministrationaffectsnaveandmemoryTcelldifferentlyislargelyunknown. Thecontextandpurposeofthestudy: Inthisstudy,weassessedhowmurineATGtherapyaffectedTcell subsetsinNODmice,basedontheirregulatoryandnaveormemoryphenotype,aswellasitsinfluenceon antigen-specificimmuneresponses. Results: PeripheralbloodCD4+andCD8+Tcellspost-ATGtherapydeclinedtotheirlowestlevelsatday3,while CD4+TcellsreturnedtonormallevelsmorerapidlythanCD8+Tcells.ATGtherapyfailedtoeliminate antigen-primedTcells.CD4+Tcellresponsespost-ATGtherapyskewedtoThelpertype2(Th2)andpossibly IL-10-producingTregulatorytype1(Tr1)cells.Intriguingly,Foxp3+regulatoryTcells(Tregs)werelesssensitiveto ATGdepletionandremainedathigherlevelsfollowinginvivorecoverycomparedtocontrols.Ofnote,the frequencyofFoxp3+TregswithmemoryTcellphenotypewassignificantlyincreasedinATG-treatedanimals. Conclusion: ATGtherapymaymodulateantigen-specificimmuneresponsesthroughinducingmemory-like regulatoryTcellsaswellasotherprotectiveTcellssuchasTh2andIL-10-producingTr1cells. Keywords: Anti-thymocyteglobulin,NaveandmemoryTcells,RegulatoryTcells,Thelpercell,Autoimmune diabetes,NonobesediabeticmouseBackgroundAnti-thymocyteglobulin(ATG),tradenamethymoglobulinW,hasbeenemployedfordecadesasanimmune modulatorforavarietyofclinicalindications.Itiscurrentlyoneofthemostcommonimmunosuppressive reagentsusedinallogeneictransplantation[1-3]and morerecently,inthetreatmentofavarietyofautoimmunedisorders[4-8].Thereisacommonbeliefthat ATGtherapyfunctionsthroughcomplementmediated depletionofmatureTcells.However,recentdata suggeststhatATGtherapyinducesimmunemodulation beyondthatofsimpleTcelldepletion[9].Forexample, ATGtherapymayfacilitatetoleranceinductionthrough modulationofdendriticcells(DC),bothphenotypically andfunctionally[10].EvidencehasalsoshownthatATG therapymayalsoinduceregulatoryTcells(Tregs) invivo[11-13].However,itremainsunclearhowATG therapyaffectsnaiveandmemoryTcellsinautoimmune settingssuchasT1D,althougharecentstudysuggested thatATGtherapyeffectivelyeliminatesalloantigenspecificmemoryTcellsinanallogeneictransplantation mousemodel[13].Inthecurrentstudy,weusedboth standardNODmice,aswellasaTCRtransgenicform ofthesemice(i.e.,NOD.BDC2.5)toinvestigatechanges withinimmunecellsubsetsinperipheralblood,spleen *Correspondence: cqx65@yahoo.com1DepartmentofHematology,XuanwuHospital,CapitalMedicalUniversity, #45ChangchunStreet,XichengDistrict,Beijing,P.R.China2DepartmentofPathology,ImmunologyandLaboratoryMedicine,University ofFloridaCollegeofMedicine,Gainesville,FL32610,USA Fulllistofauthorinformationisavailableattheendofthearticle 2012Xiaetal.;licenseeBioMedCentralLtd.ThisisanOpenAccessarticledistributedunderthetermsoftheCreative CommonsAttributionLicense(http://creativecommons.org/licenses/by/2.0),whichpermitsunrestricteduse,distribution,and reproductioninanymedium,providedtheoriginalworkisproperlycited.Xia etal.BMCImmunology 2012, 13 :70 http://www.biomedcentral.com/1471-2172/13/70

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andlymphnodespost-ATGtherapy,specificallyfocusing onaddressingthequestionsofhowATGtherapy affectednaiveandmemoryTcells,includingnaveand memoryTregs.Thesestrainswereutilizedduetotheir commonutilizationinstudiesofmurineATGefficacy fortype1diabetes,aswellastheabilitytoutilizemice havingadefinedantigenicspecificity.TheresultsdemonstratedthatATGtherapydifferentiallydepletes Tcellsfromperipheralbloodandlymphoidorgans.ATG therapywasmoreefficientindepletingnaveTcellsthan memoryTcells.TregsappearedresistanttoATGdepletionandtheirfrequencyremainedatincreasedlevelsafter homeostaticrecoveryfromATGtherapy.Itwasalsonoted thatproportionatelyTregswithmemoryTcellphenotype weresignificantlyincreasedpost-ATGtherapy.Takencollectively,webelievethisisapreviouslyunrecognized mechanismwherebyATGtherapydifferentiallyaffects naveandmemoryTregs.MethodsMiceFemaleNOD/LtjwerepurchasedfromJacksonLaboratoryandhousedinspecificpathogenfreefacilitiesat UniversityofFloridaAnimalCareService.TheInstitutionalAnimalCareandUseCommitteeatUniversityof Floridaapprovedallanimalprocedures(approvalID: 20090279).MediaandreagentsRPMI1640mediawithglutaminewerepurchasedfrom FisherScientific(Pittsburgh,PA).Completeculture mediawerepreparedusingRPMI1640plus10%fetalbovineserum(ThermoScientific,Waltham,MA)and1x penicillinandstreptomycin(Cellgro,Manassas,VA). MurineATGwasprovidedbyGenzyme(Framingham, MA).RabbitIgGisotypewaspurchasedfromthe JacksonLaboratory.ThefollowingantibodieswerepurchasedfromBDBiosciences:(SanJose,CA):CD4-PerCp (cloneRM4-5),CD8-FITC(clone53 – 6.7),B220-APC (cloneRA3-6B2),CD44-APC(cloneIM7),CD11c-APC (cloneHL3),CD3-PE(clone17A2)andCD25-APC (clonePC61).TheantibodiesofCD62L-APCand – FITC (mEL-14)andCD11b-PE(m1/70)werepurchasedfrom eBioscience(SanDiego,CA).Gr1(Ly6G/Ly6C)-APC (cloneRB6-8C5)andFoxp3-PE,-FITC(cloneMF-14) werepurchasedfromBioLegend(SanDiego,CA).CellTraceCFSEkits,andCD3,CD28antibody-coatedDynabeadswerepurchasedfromInvitrogen(Carlsbad,CA). Multiplexbeadcytokineassaykitswerepurchasedfrom Millipore(Billerica,MA).MouseCD11cbeadswerepurchasedfromMiltenyiBiotech(Germany).CD4+Tcell negativeselectionkitswerepurchasedfromStemCell BiotechnologyInc.(Vancouver,Canada).KLHwaspurchasedfromCalbioChem(SanDiego,CA).Bovine serumalbuminwaspurchasedfromSigma-Aldrich (St.Louis,MO).Alumadjuvantwaspurchasedfrom ThermoScientific(Waltham,MA).ATGtreatmentandobservationofperipheralbloodcell components6 – 8weekoldNODmiceweretreatedwithtwointraperitonealinjectionsofATGorisotypeIgG(500ug/mouse),3 daysapart,aspreviouslydescribed[11,12].Insome experiments,twogroupsofmiceweremonitoredlongitudinallybyexaminingwhitebloodcelllineagesusingflow cytometry(LSRFortessa,BD)includingCD4+,CD8+ Tcells,B220+Bcells,Gr-1+granulocytesaswellas CD62L+naiveTcellsandCD62-CD44+memoryTcells. ThedatawereanalyzedbyFCSexpressDeNovosoftware version3(Vancouver,Canada).MeasurementofsplenicmemoryandnaiveTcellsandT cellresponsetoinvitrostimulationpostATGtherapyNODmiceweretreatedwithATGandisotypeIgGas describedabove.Atday3or22,thetreatedmicewere sacrificed.Singlecellsuspensionsofspleencellswere preparedandCD4+,CD8+TcellsaswellasCD62L+ naiveandCD62-CD44+memoryTcellswereexamined byflowcytometry(LSRFortessa,BD).Aportionofthe spleencellswereusedforCD4+Tcellisolationusing CD4+TcellnegativeisolationEasySepkitsfollowingthe manufacturer ’ sinstructions(StemCellInc.Canada). Spleencells(1106)werestimulatedwithanti-CD3 antibody(3ug/ml)andinsomeexperiments,purified CD4+TcellswerestimulatedwithCD3andCD28 antibody-coatedDynabeadsmouseTcellactivator(Invitrogen),withsplenicDCplusantigens(KLH),orautoantigens(NIT-1celllysates)asindicatedfor3 – 4days, then,3H-thymidine(1uCi/well)wasaddedtoeachwell forthefinal16hours.Incorporationof3H-thymidine wasmeasuredbyscintillationcounting(WallacTrilux).MeasurementofFoxp3+TregcellsSpleencellswerestainedwithanti-CD4-PerCpandantiCD25-APC.Thecellswerethenfixedandpermeablized andstainedwithanti-Foxp3-PEfollowingtheinstructions ofthemanufacturer(eBioscience).CD4+CD25+Foxp3+ Tregcellswereexaminedbyflowcytometry(LSRFortessa, BD)andanalyzedbyFCSexpressDeNovoSoftwareversion3.SplenicCD4+TcellandCD11c+DCisolationSpleencellswerefreshlyprepared.PurifiedCD4+Tcells werepreparedusingEasySepCD4+Tcellnegativesectionkit(StemCellTechnologiesInc,Vancouver,Canada), andsplenicDCswerelabeledwithanti-CD11c-microbeads,andthenisolatedbymagneticcellsortingfollowingXia etal.BMCImmunology 2012, 13 :70 Page2of13 http://www.biomedcentral.com/1471-2172/13/70

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manufacturer ’ sinstructions(Miltenyi).Thepurityof CD4+TcellsandCD11c+DCwasapproximately95%.KLHimmunizationandrecallresponseassayNODmiceweretreatedwithATGorisotypeIgGas describedabovealongwithsimultaneousimmunization byintraperitonealinjectionsofKLH(25ug/mouse)in adjuvantAlum.Thetreatedmiceweresacrificedatday 22post-ATGtherapyandharvestedcellswerecultured withstimulatorsasindicated,ormediumonlyfor4days. Supernatants(50ul/well)wereharvestedandstoredfor latercytokineassay.Then,3H-thymidine(1uCi/well) wasaddedtotheculturesandincubatedforadditional 16hours.3H-thymidineincorporationwasmeasuredas describedabove.Autoantigenimmunizationandrecallresponseinvitro andinvivoNIT1cells(NODinsulinomacellline)werecultured accordingtothemethodprovidedfromthevendor (ATCC).NIT1cells(2107)weresuspendedinto1ml PBS.Thecellsuspensionunderwentfreeze-thawprocedures4timestoprepareNIT1celllysates.NODmice (6weeksold)weretreatedwithATGorisotypeIgGas describedabovealongwithintraperitonealinjectionsof 50 lofNIT1lysatesin50 lofAlum.InvitroantigenrecallresponseassayAweekfollowingthelasttreatment,allmicewere sacrificedandspleencellspreparedandstimulated withNIT1lysates(10ul/well),acontrolantigenKLH (10ug/ml),ormediumfor4days.Supernatants(50ul/ well)wereharvestedandstoredforlatercytokineassay. Then,3H-thymidine(1uCi/well)wasaddedtotheculturesandincubatedforadditional16hours.3H-thymidine incorporationwasmeasuredbyscintillationcounting.A portionofthespleencellsfromtheabovemicewere usedforCD4+Tcellisolation.TheisolatedCD4+Tcells (2105/well)werestimulatedwithsplenicdendriticcells (2104/well)purifiedfromnaiveNODmiceinthepresenceofNIT1lysates(20 l/well).TheTcellproliferation wasmeasuredby3H-thymidineincorporationassay,as describedabove.InvivoantigenrecallresponseassayIntheseexperiments,westainedaportionofspleen cellspreparedabovewithcarboxyfluoresceinsuccinimidylester(CFSE)followingtheinstructionsfromthe manufacturer(Invitrogen).Then,weadoptivelytransferredCFSE-labeledspleencells(2107/mouse),aspreparedabove,into8-week-oldNODmice.Fourdays later,themiceweresacrificedandpancreaticlymph nodecells,aswellascellsfrominguinallymphnode, werepreparedandtheCFSE-labeledTcellproliferation (dilutionofCFSE)wasexaminedbyflowcytometry.In theseexperiments,wechosetouseCFSE-labeledwhole spleencellsbutnotpurifiedCD4+Tcellsbecausethe wholespleencellswouldbemorereflectingtheTcell behaviorspost-ATGtherapy.CytokineassayCytokineconcentrationsinculturesupernatants,includingIFN,IL-4,IL-5andIL-10,weremeasuredbymultiplexcytokineassaykitsusingLuminex100(Luminex MapTechnology)followingtheinstructionfromthe manufacturer(Millipore).StatisticalanalysisDatawereanalyzedusingStudent t testing.Differences withp<0.05wereconsideredtobestatisticallysignificant.ResultsATGtherapyefficientlydepletesTcellsfromperipheral blood,butislessefficientindepletingTcellsfrom lymphoidorgansItisknownthatATGtherapycanlargelyeliminateT cellsfromperipheralblood.However,itwasofinterest tolearntowhatextentATGeliminatedTcellsfrom lymphoidorgans.Ourkineticobservationofperipheral bloodcellspost-ATGtherapyrevealedthatboththe CD4+andCD8+Tcellsdroppedtotheirlowestlevelsat day3post-ATGtherapyandbyday22,peripheralblood CD4+Tcellsreturnedtonormallevels.Incontrast, whereasCD8+Tcellswereshowntorecover,they remainedsignificantlylowerthanatbaselinebyday22 (Figure1AandAdditionalfile1:FigureS1).Basedon thekineticchangesofbloodTcellsabove,insubsequent experiments,wecomparedCD4+andCD8+Tcellsin peripheralbloodandspleenatday3andday22postATGtherapy.Again,wefoundthatatday3post-ATG therapy,bothCD4+andCD8+Tcellsweredrastically reducedinperipheralblood(Figure1BandD).Incontrast,thereductionofbothTcellpopulationsinspleen atday3post-ATGtherapywassignificantlylessthanin peripheralblood(Figure1CandD).WedidnotfindsignificantdifferencesbetweenATGandisotypeIgGtreatedanimalsintermsofthespleensizeandthetotalcell numbersinspleenatday3post-ATGtherapy(datanot shownandAdditionalfile1:FigureS2).Therefore,the percentagechangewouldreflecttheabsolutenumber changeinsplenicTcells.Again,byday22post-treatment,thepercentageofCD4+TcellsdidnotshowsignificantdifferencesbetweentheATGgroupandisotype IgGgroup,inbothbloodandspleen(Figures1B,Cand Additionalfile1:FigureS1).However,CD8+Tcells weresignificantlylowerintheATGgroupthanincontrolanimals,inbothbloodandspleen(Figure1B,Cand Additionalfile1:FigureS1).TheseresultsindicatethatXia etal.BMCImmunology 2012, 13 :70 Page3of13 http://www.biomedcentral.com/1471-2172/13/70

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Figure1 ATGtherapydifferentiallydepletesTcellsfromperipheralbloodandlymphoidorgans. NODmiceweretreatedwithATGor isotypeIgGtwicewitha3-dayinterval.Then,CD4+andCD8+Tcellsinperipheralbloodwereexaminedbyflowcytometryevery3daysuntilday 22. A showsCD4+andCD8+TcellpercentagesintotalperipheralwhitebloodcellsatdifferenttimepointspostATGtherapy(n=4miceineach group); B and C showCD4+andCD8+Tcellpercentagesinperipheralwhitebloodcellsandspleencells,respectively(n=3miceineachgroup). D exhibitsCD4+andCD8+Tcelldepletionratesinperipheralbloodandspleenatday3postATGtherapy,respectively(n=3miceineach group).Thesimilarresultswereobtainedinadditionaltwoindependentexperiments. Xia etal.BMCImmunology 2012, 13 :70 Page4of13 http://www.biomedcentral.com/1471-2172/13/70

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Tcelldepletionpredominantlytakesplaceinperipheral bloodandthatCD4+TcellsrecoverfasterthanCD8+T cells.ATGtherapydifferentiallydepletesnaiveandmemory TcellsfromtheperipheralbloodandspleenItisstillamatterofdebatewhetherATGtherapypreferentiallydepletescertainsubsetsofTcells[4,14-17].In theseexperiments,weinvestigatedchangesofnaiveand memoryTcellsusingCD62LandCD44markers(shown inFigure2),respectively,inperipheralbloodandspleen, atday3andday22post-ATGtreatment.Wediscovered thatCD62L+CD4+(Figures2AandB)andCD62L+CD8+ naiveTcells(datanotshown)weresignificantlyreduced atday3post-ATGtherapy,incontrasttotheIsotypeIgG group,inbothperipheralbloodandspleen.Ofinterest, thepercentageofCD62L-CD44+CD4+Tcells(Figure2A andB)andCD62L-CD44+CD8+Tcells(datanotshown) intotalCD4+andCD8+Tcells,respectively,weresignificantlyincreasedintheATGgroupcomparedtothecontrolgroup.TheseresultssuggestthatATGtherapymay preferentiallydepletenaiveTcells.However,byday 22post-treatment,therewerenodifferencesbetween twogroupsinthefrequencyofnaiveandmemoryCD4+ Blood SpleenB A Figure2 ATGtherapydifferentiallydepletesnaiveandmemoryTcellsinperipheralbloodandspleen. NODmiceweretreatedwithATG orisotypeIgGtwicewitha3-dayinterval.Atday3posttreatment,CD62L+CD4+andCD44+CD62L-CD4+Tcellsinperipheralbloodandspleen wereexaminedbyflowcytometryandanalyzedbygatingCD4+Tcellsasdepictedintheupperpanelsof A and B ,respectively. A showsthe summaryofthepercentagesofCD62L+CD4+TandCD44+CD62L-CD4+TcellsintotalCD4+Tcellsintheperipheralblood,respectively(lower panels). B showsthesummaryofthepercentagesofaboveTcellsubsetsintotalCD4+Tcellsinspleencells,respectively(lowerpanels).Three micewereincludedineachgroup.Threeindependentexperimentswereperformedwithsimilarresults. Xia etal.BMCImmunology 2012, 13 :70 Page5of13 http://www.biomedcentral.com/1471-2172/13/70

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Tcells(Additionalfile1:FigureS3).Wedidnotfindany differencesbetweenisotypeIgGtreatedandnon-treated NODmice(datanotshown).ATGtherapydoesnotaffecttheresponseofthe remainingnon-depletedTcellstoTCRstimulation,but inducesdecreasedlevelsofTh1andenhancedlevelsof IL-10-producingTcellsTodeterminewhethertheimmuneresponseofTcells thatarenotdepletedbyATGtherapyalters,atday3 post-treatment,wepreparedspleencellsfromATGor isotypeIgGtreatedNODmiceandstimulatedthemwith anti-CD3antibodies.Tcellproliferationwasmeasured by3H-thymidineincorporationassay.Wefoundthatthe proliferationofTcellsfromspleencellsofATG-treated animalswassignificantlylowerthanthoseobtainedfrom isotypeIgGtreatedanimals(Figure3A).ThereducedT cellproliferationwaslikelyattributabletothelowerfrequencyofTcellsinspleencellsfromATG-treatedmice. ToaddresswhetherATGtreatmentdirectlymodulates TcellsandalterstheirresponsetoTCRactivation,we purifiedCD4+Tcells(purity>95%)andstimulatedthem withCD3andCD28antibodycoatedDynabeads.Then, Tcellproliferationwasexaminedby3H-thymidineincorporationassay.WedidnotobservesignificantdifferencesintermsofTcellproliferationbetweenthe twogroups(Figure3B).CharacterizationofcytokineproducingprofilesofCD4+Tcellsdemonstratedthat Figure3 ProliferationofTcellsfrommicetreatedwithATGorisotypeIgGinresponsetoCD3antibodystimulation. NODmicewere treatedwithATGorisotypeIgGtwicewitha3-dayinterval. A, Atday3posttreatment,spleencellswerepreparedandstimulatedwithanti-CD3 antibodiesfor3days,then3H-thymidine(1uCi/well)wasaddedtotheculturesforadditional16hours.3H-thymidineincorporationwas measuredbyscintillationcounting.Threemiceweretestedineachgroup. B, partoftheabovespleencellswasusedtoisolateCD4+Tcells.The purifiedCD4+Tcellswerestimulatedwithanti-CD3andanti-CD28antibodycoatedbeadsfor3days.Thereafter,3H-thymidine(1uCi/well)was addedtotheculturesforadditional16hours.Tcellproliferationwasexaminedbythemethoddescribedabove. C ,theproductionofIL-10,IFNintheculturesfrom3animalsineachgroupin B wasmeasuredbyLuminex.ThevaluesforIL-10andIFNfortreatmentgroupandcontrolsare (993.3141.0v.s.366.796.1)and(1117.0202.8v.s.3793795.5),respectively.ThedifferencebetweenthetwogroupsforIL-10andIFNby Student t testissignificantwithpvalueasof0.0221and0.0253,respectively.Anadditionalindependentexperimentwasperformedwiththe similarresults. Xia etal.BMCImmunology 2012, 13 :70 Page6of13 http://www.biomedcentral.com/1471-2172/13/70

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CD4+TcellsfromATG-treatedmiceproducedsignificantlyhigherlevelsofIL-10withreducedlevelsof IFN,incontrasttothosefromisotypeIgGtreated mice(Figure3C).ThesedataindicatethatATGtherapyskewTcellresponsestoIL-10-producingTcells includingTh2andTr1.CD4+Foxp3+TregsarelesssensitivetoATGdepletion andremainatanincreasedfrequencypostCD4+Tcell recoveryTodeterminewhetherTregsundergodepletionpostATGtherapy,NODmiceat6weeksofageweretreated withATGorisotypeIgGasdescribedearlier.Wethen sacrificedone-halfofthemice(n=3)fromeachgroup atday3,andtherest(n=3)atday22post-treatment, respectively,andexaminedtheproportionofFoxp3+ CD4+TcellsoftotalCD4+Tcellsaswellastheirabsolutenumbers.AsshowninFigure4AandB,compared totheisotypeIgGgroup,theATGgroupdemonstrated asignificantlyincreasedpercentageofCD25+Foxp3+ CD4+TcellsintotalCD4+Tcellsatday3post-therapy andcomparablelevelsofabsolutenumbersofthese cells,suggestingthatFoxp3+Tregswereresistantto ATGmediateddepletion.Moreover,atday22,when CD4+Tcellswererecovered,Tregsremainedathigher levelsintheATGtreatedgroupthanintheisotypeIgG group(Figure4CandD).Ofinterest,theproportionate increaseoftheTregsoutoftotalCD4+Tcellsinlymph nodeswasevenmoredramaticintheATGcomparedto theisotypeIgGgroupatday3post-treatment(Figure4E andG).ThesametrendwasalsoobservedforTreg ’ sabsolutenumbers(Figure4FandH).ATGtherapydrivesmoreCD62L-memorytypeTregsWedemonstrated(Figure2)thatATGpreferentially depletesCD62L+naveTcells.Itwasthenofinterestto learnwhetherATGtherapydepletednaveandmemory Tregsdifferently.Intheseexperiments,weexamined splenicTregsatday3post-ATGorisotypeIgGtreatmentusingflowcytometry.WegatedCD4+CD25+T cellsandthenanalyzedfortheexpressionofFoxp3and CD62L.Surprisingly,wenotedthatATGtherapysignificantlyreducedCD62L+naveTregscomparedtoisotype IgGtreatedanimals(Figure5AandB).ThisfindingsuggeststhatthepreservationofCD62L-memoryTregs mayplayanimportantroleforATGtomodulate antigen-specificimmuneresponses.ATGtherapyfailstoeliminateantigenprimedTcell,but skewsantigen-specificimmuneresponsestoTh2and/or Tr1cellsAsnotedearlier,ATGhasbeenusedforavarietyof immune-mediatedconditionssuchasallogeneictransplantationandautoimmunediseases.OnehopeforATG therapywouldbeitsabilitytoeliminatemostantigenspecificTcellssothatimmuneresponsesagainstallograftorself-tissuescouldbeavoided.Forexample,in settingsofautoimmunediabetes,amajorityof cell antigen-specificTcellsarepresumablyprimedandbecome antigen-specificeffectorormemoryTcells.In allogeneictransplantation,alloantigen-specificTcellsare activatedtobecomeeffectorormemoryTcellsunless thereisimmuneintervention.ToaddresshowATG therapyaffectsantigen-stimulatedTcells,wedesigned andperformedaseriesofexperimentswherebyNOD miceweretreatedwithATGorisotypeIgG,alongwith simultaneousimmunizationbyKLHproteininadjuvant alum.Allmiceweresacrificedatday22post-treatment, withspleencellspreparedandincubatedwithKLH,BSA (unrelatedantigen)andmediumalone.Wefoundthat KLHstronglystimulatedspleencellsfromboththeATG andisotypeIgGtreatedmicetocomparablelevels (Figure6A).Spleencellsfromeithergroupresponded poorlytoBSAstimulation(Figure6A).Thesefindings suggestthatATGtherapyisunabletoeliminateantigenprimedTcells.Wealsofoundthatspleencellsfrom bothgroupsrespondedtoanti-CD3antibodystimulation similarly(Figure6B).However,wealsoobservedthat spleencellsfromtheATGtreatedanimalsproducedsignificantlyincreasedlevelsofIL-4,IL-5andIL-10alongsideofmarkedlyreducedlevelsofIFNinresponseto stimulationofKLH(Figure6C),incomparisontoisotypeIgGtreatedanimals.Thesefindingssuggestthat despitethefailuretoeliminateantigen-specificTcells, ATGtherapyinducesantigen-specificTcellresponses skewedtoTh2andTr1,andlargelylimitstheinflammatoryTh1response.ATGtherapyfailstoeliminateautoantigen-stimulated TcellsFromtheresultsabove,itappearedthatATGtherapyis unabletoeliminateexogenousforeignantigenstimulatedTcells(Figure6A).Itisofinteresttoknowhow ATGtherapyaffectsselfantigen-stimulatedTcells.To addressthisissue,westimulated cellantigen-specific TcellsinNODmiceat6weeksofagewithanintraperitonealinjectionofNIT1(NODmiceinsulinomacell line)lysatesalongwithATGorisotypeIgGtreatment, asdescribedpreviously.Intheseexperiments,wedid notwaituntil22daysposttreatmenttoassessTcell responsesbecauseoftheconcernthattheexposureof endogenous antigenswouldcontinuouslyprimeT cells.Thus,atday7post-treatment,wesacrificedthe mice,withthespleencellspreparedandstimulatedwith NIT1lysatesorunrelatedantigenKLH.Asexpected,becauseofthetransientsignificantdepletionofTcellsby ATGtherapy,inresponsetostimulationoftheNIT1cell lysates,theproliferationofwholespleencellsfromXia etal.BMCImmunology 2012, 13 :70 Page7of13 http://www.biomedcentral.com/1471-2172/13/70

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ATG-treatedanimalswassignificantlylowerwhencomparedtoisotypeIgGtreatedanimals(Figure7A).However,comparedtotheunrelatedantigenKLH,NIT1 lysatesstillsignificantlystimulatedspleencellsfromthe ATGtreatedanimals(Figure7A).Todeterminetowhat degreetheATGtherapydepletes antigen-specificT cells,wepreparedspleencellsfromtheaforementioned miceandthenperformedanadoptivetransferofCFSElabeledspleencellstorecipientNODmiceat8weeksof age.Fourdayslater,CD4+TcellproliferationofCFSElabeledcellsininguinalandpancreaticlymphnodeswas examinedbyflowcytometry.AsshowninFigure7C,in inguinallymphnodes,theproliferationofCD4+Tcells ofinjectedCFSE-spleencellsfromATGtreatedanimals isslightlyhigherthanthatofCD4+Tcellsfromcontrol group,whichmayreflectthehigherTcellhomeostatic proliferationpotentialpost-ATGtherapy[18].Moreimportantly,wefoundtheproliferationofCFSE-labeled CD4+Tcellswasmuchhigherinpancreaticthanininguinallymphnodesforbothgroups,whichreflects cell-antigenspecificTcellresponse.However,unexpectedly,inresponsetoendogenous cellantigens,theproliferationofthoseinjectedCD4+TcellsfromATG treatedanimalsinpancreaticlymphnodewassignificantlyhigherthanthatofCD4+TcellsfromisotypeIgG treatedanimals.TheseresultsfurtherconfirmthatATG therapyfailstoeliminateantigen-primedTcells.To confirmthis,wedemonstratedthatpurifiedCD4+T cellsfromthespleencellsofbothgroupshadcomparablelevelsofproliferationinresponsetostimulationof syngenicsplenicDCplusNIT-1lysates(Figure7B). Nevertheless,consistentwiththeresultsshownin Figure6C,thecytokineassayfortheculturesshownin Figure7BdemonstratedthatATGtherapysuppressed cellantigen-specificIFNproductionbutenhancedIL10productionbytheCD4+Tcells(Figure7D).DiscussionInthisstudy,wequestionedhowATGtherapyaffected naveandmemoryTcellsincludingTregswithnaveor memoryphenotypes.Untilnow,itwasuncleartowhat extentATGtreatmentaffectednaiveandmemoryTcells pools.Resolvingthisissueisofgreatsignificancein managingATGtherapyinautoimmunediseasesaswell C B A D P=0.0019 P=0.006 P=0.4839 P=0.015 G F E HP=0.0051 P=0.0027P=0.018 P=0.0096 Figure4 EffectofATGtherapyonFoxp3+Tregcells. NODmice weretreatedwithATGorisotypeIgGtwicewitha3-dayinterval.At day3and22,CD4+Foxp3+regulatoryTcellsinspleenwere examinedbyflowcytometryandthesummaryofeachgroupwas showninFigure4AandB,and4CandD,respectively.Atday3, CD4+Foxp3+regulatoryTcellsinpancreaticandinguinallymph nodeswerealsoexaminedandshowninFigure4EandF,4GandH, respectively.Threemicewereincludedineachgroup.Thesimilar resultswereobtainedinadditionaltwoindependentexperiments. Xia etal.BMCImmunology 2012, 13 :70 Page8of13 http://www.biomedcentral.com/1471-2172/13/70

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asinallogeneictransplantation.Inlinewiththeprevious reports[12],wefoundthatATGtherapymarkedly depletedCD4+andCD8+Tcellsfromtheperipheral blood,andlargelysparedBcellsandgranulocytes.By day3post-treatment,Tcellnumbersreachedtheirnadir. Byday22,CD4+Tcellsrecoveredtowithinnormal ranges,butCD8+Tcellsremainedlowerthanbaseline. IthasbeensuggestedthatATGtherapymayhavedifferentialeffectsindepletingTcellsinperipheralbloodand lymphoidorgansdependentondosing[19].Inthis study,wetestedourtreatmentprotocolwithoptimalefficacyinpreventingorreversingtype1diabetes(500 g/ mouse2doses3daysapart)asdescribedinourother reports[11,12].TodeterminetheefficiencyofourATG treatmentprotocolindepletingTcellsfromthelymphoidorgans,weexaminedsplenicCD4+andCD8+T cellsinbothgroups(ATGversusisotypeIgG)atday3 post-ATGtherapy.Wefoundthatthedepletionofboth CD4+andCD8+Tcellswaslessefficientinspleenthan fromperipheralblood.Thesimilarresultswereobtained inlymphnodessuchasinguinalorpancreaticlymph nodes(datanotshown).Ofinterest,itappearsthatATG therapypreferentiallydepletesCD62L+naiveTcells fromthebloodbecausetheproportionofCD62L+CD4+ naiveTcellswasmarkedlyreducedwhileCD44+CD62LCD4+memoryTcellsasafractionoftotalCD4+Tcells wereincreased.Weobservedasimilarsignificanttrendin thechangeofnaiveandmemoryTcellsinspleenaswell. WhetherthisdifferentialdepletingeffectofATGexhibits inlocallymphnodes,especiallyinpancreaticlymphnodes isofinteresttobefurtheraddressed.Itisunlikelythatthe increaseofmemoryTcellsatday3post-ATGtherapyis duetotheconversionfromnaveTcells[20,21]because ATGisstilldepletingTcellsduringthisshortperiodof timepost-ATGtherapy,andhomeostaticproliferationunlikelyleadstomuchinthewayofTcellconversion. TherelativeresistanceofmemoryTcellstoATGinducedTcelldepletionwouldallowforsurvivalof memoryTcellswhichpotentiallycouldleadtothe recurrenceofallograftrejectionorautoimmunityafter reconstitutionofimmunesystempost-ATGtherapy. Consistentwiththis,wedemonstratedthattheproliferationofspleencellsfrommicereceivingATGandde novoKLHimmunizationwasashighasthatofspleen cellsfromisotypeIgGtreatedanimalsinKLHrecall responsesinvitro.Wealsofoundthat cellantigenprimedTcellsduringATGtherapycouldsurviveATG depletionaswell.However,despiteunaffectedTcell proliferationinresponsetoantigenstimulationpostATGtherapy,theTcellcytokine-producingprofilein ATGtreatedanimalsindicatedthatATGtherapyskewed Th2andpossiblyIL-10-producingTr1,andreduced IFN-producingTh1responses.Wehadpreviously shownlong-termreversalofdiabetesinNODmice usingATGorATGincombinationwithG-CSF[11,12] andourcurrentfindingsinthisreportprovideamechanisticbasisforthisintheskewingtowardTh2and/or IL-10-producingTr1responsesundertheregimenof ATG.Inthisstudy,althoughwefocusedourstudieson CD4+Tcells,itisalsoimportanttostudyphenotypic andfunctionalalterationsofCD8+TcellsbytheATG therapy,giventhepathogenicroleofCD8+Tcellsin BATG Isotype IgGA Figure5 EffectofATGtherapyonnaiveandmemoryTregs. NODmiceweretreatedwithATGorisotypeIgGtwicewitha3-dayinterval.At day3posttreatment,themiceweresacrificed.ThespleencellswerepreparedandstainedwithCD4,CD25CD62LandFoxp3antibodiesand examinedbyflowcytometry.CD62L+Foxp3+andCD62L-Foxp3+TregswereanalyzedbygatingtheCD4+CD25+cellpopulationasshownin Figure5A.ThesummaryofsplenicCD62L+TregswasshowninFigure5B.ILN:inguinallymphnode;PLN:pancreaticlymphnode.Anadditional experimentwasperformedwithsimilarresults. Xia etal.BMCImmunology 2012, 13 :70 Page9of13 http://www.biomedcentral.com/1471-2172/13/70

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type1diabetes,whichwillbeaddressedinthefollowing futurestudies.ThememoryTcellphenotypiccharacteristics,aswellasthefunctionalalterationspost-ATG therapy,mayallowthemodulatedantigen-primedTcells toefficientlyexerttheirregulatoryfunctionsintheperipherythroughaffectingtheirmigratingandhoming capabilities,therebypreventingtherecurrenceofautoimmunityinautoimmunediseasesandallogeneicrejectioninallogeneictransplantation.Thesefindingsalso implicatethatATGtherapyplusantigenvaccination couldleadtosynergisticeffectoninductionofantigenspecificimmunetolerance.Suchinformationwouldbe ofgreatsignificancefordevelopingantigen-basedimmunotherapeuticstrategyforautoimmunediseasessuchas type1diabetes. Priortothiseffort,severalmechanismsunderlying ATGimmunemodulationhavebeenproposed.AcommonbeliefisthatATGtherapyworksbyTcelldepletion throughcomplement-mediatedcelllysisandactivationinducedcelldeath.However,anotherviewregarding ATGtherapyisthatthisagentexertsimmunosuppressivefunctionbeyondthatofsimpleTcelldepletion[7,9]. ATGtherapymaymodulateimmuneresponseinvivo throughinhibitingchemokine-drivenTcellchemotaxis [22].ItmayalsoinfluencetheinteractionbetweenT cellsandendothelialcellsthroughmodulatingexpressionofadhesionmolecules[22].Ourrecentstudy showedthatATGtherapyeliminatedcertainsubsetof dendritriccellsandinducedtolerogenicdendriticcells [10].Inaddition,ATGtherapymayfacilitatetolerance inductionthroughATG-mediatedapoptosisofTcells; becauseTcellapoptosisinducedbyanti-CD3therapy wasrecentlydemonstratedtobeassociatedwithCD3 antibodytherapy-inducedimmunetolerance[23].The skewingofantigen-specificTh2andIL-10-producing regulatoryTcells(i.e.,Tr1)byATGtherapydemonstratedinthecurrentstudysuggeststhatthenondepletedantigen-respondingTcells,insteadofcausing immuneattack,mayleadtoantigen-specificrestoration ofimmunetolerance,whichimpliesthatATGworksas immunemodulatorratherthanimmunesuppressant. Assuggestedpreviously,Foxp3+Tregsmayplaya majorroleinpreventingautoimmunediabetesduring ATGtherapy[11,12].However,itisincompletely ABp=0.001p=0.0002p=0.004p=0.0165C Figure6 EffectofATGtherapyonantigen-stimulatedTcellproliferationandcytokineproduction. NODmiceweretreatedwithATGor isotypeIgGalongwithintraperitonealinjectionsofKLHinAlumasdescribedinMethods.Allmiceweresacrificedatday22posttreatment. A, spleencellswereincubatedwithKLH,BSAormediaonly; B, spleencellswerestimulatedwithanti-CD3antibodies.Allcultureswerepulsedby3H-thymidine(1uCi/well)atday4foradditional16hours.Tcellproliferationwasmeasuredbyscintillationcounting.Triplicatewellsweresetup foreachincubation.Threeanimalswereincludedineachgroup. C ,TheproductionofcytokinesinthecultureswithKLHshowninFigure6Awas measuredbyLuminexassay.Thisexperimentwasrepeatedinadditionaltwoseparateexperimentswithsimilarresults. Xia etal.BMCImmunology 2012, 13 :70 Page10of13 http://www.biomedcentral.com/1471-2172/13/70

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understoodwhetherATGtherapydepletesTregsdifferentlythanconventionalTcellsandhowATGaffectsthe distributionofTregsindifferentlymphoidtissues.Itis alsounclearwhetherATGtherapyaffectsnaveand memoryTregsdifferently.Inthepresentstudy,we demonstratedthatATGtherapywaslessefficientindepletingCD4+Foxp3+Tregsandasaresult,theproportionofCD4+Foxp3+TregsinCD4+Tcellswas significantlyincreasedinATGtreatedanimalscompared tocontrols.Thisincreaseisevenmoredramaticin lymphnodeswithgreaterthanadoublinginthefrequencyofTregswithintotalCD4+TcellsinATGtreatedascomparedtoisotypeIgGtreatedanimals.Insome animals,thepercentageofFoxp3+Tregsreaches30%of totallymphnodeCD4+Tcells.UnlikeequivalentabsolutenumbersofsplenicTregsinbothgroups,theabsolutenumberofTregsinlymphnodeswassignificantly higherinATGthaninIsotypeIgGtreatedgroupat3 Figure7 EffectofATGtherapyonselfantigen-specificTcellsinvivo.A, EightweeksoldNODmiceweretreatedwithATGorisotypeIgG alongwithintraperitonealinjectionsof cellantigensNIT1lysatesasdescribedintheMethod.Aweekposttreatment,allmiceweresacrificed andspleencellswereprepared.Spleencells(1106/well)wereincubatedwithNIT1lysates,KLH(un-relatedantigen)ormediumalone.Triplicate wellsweresetupforeachincubation.Tcellproliferationwasmeasuredby3H-thymidineincorporationassayasdescribedintheMethods section.Threemicewereincludedineachgroup.Datashownrepresenttheaverageofthreemice+/ standarddeviation(SD). B, Partofthe spleencellswereusedtoisolateCD4+TcellsandtheisolatedCD4+Tcells(2105/well)wereincubatedwithsplenicdendriticcells(2104/well) purifiedfromnaiveNODmiceinthepresenceofNIT1lysates(20 l/well).Triplicatewellsweresetupforeachincubation.TheproliferationofCD4+ Tcellswasmeasuredby3H-thymidineincorporationassay.Threemicewereincludedineachgroup.Datashownrepresenttheaverageofthreemice +/ SD. C, Partofthemixedspleencellsfromtheabove3ATGor3isotypeIgGtreatedanimalswerestainedwithCSFE.Then,theCFSE-labeledspleen cellswereintravenouslyinjectedinto8weeksoldnaiveNODmice(3micepergroup).Fourdayslater,thecellspreparedfrominguinalandpancreatic lymphnodeswerestainedwithCD4-PerCp.ThepercentagesoftheproliferatingCFSE-labeledCD4+Tcells(dilutionofCFSE)wereexaminedbyflow cytometry.D,cytokinesIFNandIL-10intheculturesshowninBweremeasuredbyluminex.Datashownrepresentaveragevaluesof3mice+/ SD. Anadditionalexperimentwasperformedwithsimilarresults. Xia etal.BMCImmunology 2012, 13 :70 Page11of13 http://www.biomedcentral.com/1471-2172/13/70

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daysposttreatment,suggestingthatmoreTregswere recruitingtothelymphnodesbesidesresistancetoATG depletion.TheincreaseofTregsinlymphnodesmaybe ofgreatimmunologicalsignificanceforATGtocontrol localantigen-specificimmuneresponsesinthesettings ofautoimmunitysuchastype1diabetes,aswellasin allogeneictransplantation.ThisincreaseofTregs3days post-ATGtherapyisunlikelyduetothepreferentialproliferationofTregsintheATG-therapyinducedlymphopenicanimals[24]becausetheproliferationislimitedin thisshortperiodoftimeespeciallystillunderactiveT celldepletion.Ofinterest,byday22post-ATGtreatmentwhenCD4+Tcellsreturntothenormallevels, TregsremainedproportionatelyhigherintheATG groupthanincontrolgroup,whichmaybeattributable toafasterproliferationofTregsthanconventionalT cells[24]becauseTregspossesssuperiorcapabilityto utilizeIL-2toconventionalTcells[25].Thismayalso explainwhyashort-termATGtherapyoffersalongtermprotectionintype1diabetes[11,12]andinallogeneictransplantation[2,26].Intriguingly,Tregswith memoryTcellphenotypewerepreferentiallypreserved inATGtherapy,whichsuggeststhatthepreserved memoryTregsspecifictocertainantigenswouldbe morepotentinsuppressingeffectorTcellsreactiveto thesameantigens.Assuggestedrecently[27],thememoryTregsmayhometoareaswithactiveimmunological reactiontoquicklyexerttheirregulatoryfunctionpreferentiallytonaveTregs.Thisalsoexplainsthefindingsin ourrecentreportthatthepost-therapyTregsgain heightenedimmunosuppressivecapacity[11].Thereis evidencethattheprogressionofautoimmunityinNOD miceleadstomemory-likeCD8+Tregswhichcanbe expandedinvivobystimulationofnanoparticlescoated withMHC-carriedautoantigenicpeptides.Ofnote,injectionofthesenanoparticlesnotonlypreventedT1D butalsoreversedovertdiabetesinNODmice[28]. Thus,thequantitativeandqualitativechangesofTregs postATGtherapymayplayanimportantroleinsuppressingantigen-specificeffectorTcells.AlthoughTregs aregenerallythoughttosuppressTcellresponsesinan antigennon-specificmanner,emergingevidenceshows thatantigen-specificTregsaremorepotentinsuppressingantigen-specificTcellresponses[29-31].Lu,etal. reportedrecentlythatATGtherapyindeedinducedselfantigen-specificTregsinvivothatcouldprovidelongtermT1DprotectioninNODmice[32].Whetherthe increasedmemoryTregspostATGtherapyplusantigen challengeinourexperimentalsettingscontainmore antigen-specificTregsneedstobefurtherexplored.ConclusionsATGtherapypreferentiallydepletesnaiveTcells,largely sparesTregsandaltersTcellcytokine-producing profiles.Thus,ATGtherapymaymodulateantigenspecificimmuneresponsesthroughinducingmemorylikeregulatoryTcellsaswellasotherprotectiveTcells suchasTh2andIL-10-producingTr1cells.AdditionalfileAdditionalfile1: FigureS1. TheeffectofATGtherapyonabsolute numbersofCD4+andCD8+Tcells. FigureS2. TheeffectofATG therapyondepletingspleencellsatday3afterATGinjection. FigureS3. TheproportionsofnaiveandmemoryCD4+TcellsafterCD4+Tcell numberrecoveredfromATGtherapy. Competinginterests SEandJWareemployeesofGenzyme.HumanThymogobulinisa commercialproductsoldbyGenzyme.Genzymegraciouslysuppliedmouse thymoglobulin,butnofinancialsupportfortheresearchdescribedinthis article.Nootherpotentialconflictsofinterestrelevanttothisarticlewere noted. Authors ’ contribution CQXdesignedthestudy,analyzedthedataandwrotethemanuscript;AVC performedthemouseinvivoexperimentsanddataanalyses,CHW,SWand BMLperformedflowcytometricassayandTcellproliferationassay;SEand JWprovidedATGanddiscussedATG-relatedissues;MJCSandMAA participatedintheexperimentaldesignandhelpeddraftthemanuscript.All authorsreadandapprovedthefinalmanuscript. Acknowledgement ThisworkwassupportedinpartbyJuvenileDiabetesResearchFoundation (17-2008-1036toCQX),FloridaStateLungTransplantationAwardtoCQX, andNaturalScienceFoundationofChina(Grant#81172854toCQX). Authordetails1DepartmentofHematology,XuanwuHospital,CapitalMedicalUniversity, #45ChangchunStreet,XichengDistrict,Beijing,P.R.China.2Departmentof Pathology,ImmunologyandLaboratoryMedicine,UniversityofFlorida CollegeofMedicine,Gainesville,FL32610,USA.3GenzymeCorporation, Framingham,MA02142,USA. Received:29June2012Accepted:24November2012 Published:14December2012 References1.BacigalupoA: Antilymphocyte/thymocyteglobulinforgraftversushost diseaseprophylaxis:efficacyandsideeffects. BoneMarrowTransplant 2005, 35 (3):225 – 231. 2.HardingerKL: Rabbitantithymocyteglobulininductiontherapyinadult renaltransplantation. Pharmacotherapy 2006, 26 (12):1771 – 1783. 3.ShapiroR,YoungJB,MilfordEL,TrotterJF,BustamiRT,LeichtmanAB: Immunosuppression:evolutioninpracticeandtrends,1993 – 2003. AmJTransplant 2005, 5 (4Pt2):874 – 886. 4.ChungDT,KornT,RichardJ,RuzekM,KohmAP,MillerS,NahillS,OukkaM: Anti-thymocyteglobulin(ATG)preventsautoimmuneencephalomyelitis byexpandingmyelinantigen-specificFoxp3+regulatoryTcells. IntImmunol 2007, 19 (8):1003 – 1010. 5.MussoM,PorrettoF,CrescimannoA,BondiF,PolizziV,ScaloneR: Intense immunosuppressivetherapyfollowedbyautologousperipheralblood selectedprogenitorcellreinfusionforsevereautoimmunedisease. AmJHematol 2001, 66 (2):75 – 79. 6.SaudekF,HavrdovaT,BoucekP,KarasovaL,NovotaP,SkibovaJ: Polyclonal anti-T-celltherapyfortype1diabetesmellitusofrecentonset. Rev DiabetStud 2004, 1 (2):80 – 88. 7.vandeLindeP,TysmaOM,MedemaJP,HaleG,WaldmannH,RoelenDL, RoepBO: Mechanismsofantibodyimmunotherapyonclonalislet reactiveTcells. HumImmunol 2006, 67 (4 – 5):264 – 273. 8.GluckmanE,Esperou-BourdeauH,BaruchelA,BoogaertsM,BriereJ, DonadioD,LevergerG,LeporrierM,ReiffersJ,JanvierM, etal : AXia etal.BMCImmunology 2012, 13 :70 Page12of13 http://www.biomedcentral.com/1471-2172/13/70

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multicenterrandomizedstudycomparingcyclosporin-Aaloneand antithymocyteglobulinwithprednisonefortreatmentofsevereaplastic anemia.Thecooperativegrouponthetreatmentofaplasticanemia. JAutoimmun 1992, 5 (SupplA):271 – 275. 9.MohtyM: Mechanismsofactionofantithymocyteglobulin:T-cell depletionandbeyond. Leukemia 2007, 21 (7):1387 – 1394. 10.HuangY,ParkerM,XiaC,PengR,WasserfallC,ClarkeT,WuL,ChowdhryT, Campbell-ThompsonM,WilliamsJ, etal : Rabbitpolyclonalmouse antithymocyteglobulinadministrationaltersdendriticcellprofileand functioninNODmicetosuppressdiabetogenicresponses. JImmunol 2009, 182 (8):4608 – 4615. 11.ParkerMJ,XueS,AlexanderJJ,WasserfallCH,Campbell-ThompsonML, BattagliaM,GregoriS,MathewsCE,SongS,TrouttM, etal : Immune depletionwithcellularmobilizationimpartsimmunoregulationand reversesautoimmunediabetesinnonobesediabeticmice. Diabetes 2009, 58 (10):2277 – 2284. 12.SimonG,ParkerM,RamiyaV,WasserfallC,HuangY,BressonD,SchwartzRF, Campbell-ThompsonM,TenaceL,BruskoT, etal : Murineantithymocyte globulintherapyaltersdiseaseprogressioninNODmicebyatimedependentinductionofimmunoregulation. Diabetes 2008, 57 (2):405 – 414. 13.LopezM,ClarksonMR,AlbinM,SayeghMH,NajafianN: Anovelmechanism ofactionforanti-thymocyteglobulin:inductionofCD4+CD25+Foxp3+ regulatoryTcells. JAmSocNephrol 2006, 17 (10):2844 – 2853. 14.FengX,KajigayaS,SolomouEE,KeyvanfarK,XuX,RaghavachariN,Munson PJ,HerndonTM,ChenJ,YoungNS: RabbitATGbutnothorseATG promotesexpansionoffunctionalCD4+CD25highFOXP3+regulatoryT cellsinvitro. Blood 2008, 111 (7):3675 – 3683. 15.KroemerA,XiaoX,VuMD,GaoW,MinamimuraK,ChenM,MakiT,LiXC: OX40controlsfunctionallydifferentTcellsubsetsandtheirresistanceto depletiontherapy. JImmunol 2007, 179 (8):5584 – 5591. 16.OgawaN,MinamimuraK,KodakaT,MakiT: Shortadministrationof polyclonalanti-Tcellantibody(ALS)inNODmicewithextensiveinsulitis preventssubsequentdevelopmentofautoimmunediabetes. JAutoimmun 2006, 26 (4):225 – 231. 17.MinamimuraK,GaoW,MakiT: CD4+regulatoryTcellsaresparedfrom deletionbyantilymphocyteserum,apolyclonalanti-Tcellantibody. JImmunol 2006, 176 (7):4125 – 4132. 18.BoymanO,LetourneauS,KriegC,SprentJ: Homeostaticproliferationand survivalofnaiveandmemoryTcells. EurJImmunol2009, 39 (8):2088 – 2094. 19.MullerTF,GrebeSO,NeumannMC,HeymannsJ,RadsakK,SprengerH, LangeH: Persistentlong-termchangesinlymphocytesubsetsinduced bypolyclonalantibodies. Transplantation 1997, 64 (10):1432 – 1437. 20.SurhCD,SprentJ: HomeostasisofnaiveandmemoryTcells. Immunity 2008, 29 (6):848 – 862. 21.TakadaK,JamesonSC: NaiveTcellhomeostasis:fromawarenessofspace toasenseofplace. NatRevImmunol 2009, 9 (12):823 – 832. 22.MichalletMC,PrevilleX,FlacherM,FournelS,GenestierL,RevillardJP: Functionalantibodiestoleukocyteadhesionmoleculesinantithymocyte globulins. Transplantation 2003, 75 (5):657 – 662. 23.PerrucheS,ZhangP,LiuY,SaasP,BluestoneJA,ChenW: CD3-specific antibody-inducedimmunetoleranceinvolvestransforminggrowth factor-betafromphagocytesdigestingapoptoticTcells. NatMed 2008, 14 (5):528 – 535. 24.MatsuokaK,KimHT,McDonoughS,BascugG,WarshauerB,KorethJ,Cutler C,HoVT,AlyeaEP,AntinJH, etal : AlteredregulatoryTcellhomeostasisin patientswithCD4+lymphopeniafollowingallogeneichematopoietic stemcelltransplantation. JClinInvest 2010, 120 (5):1479 – 1493. 25.PandiyanP,ZhengL,IshiharaS,ReedJ,LenardoMJ: CD4+CD25+Foxp3+ regulatoryTcellsinducecytokinedeprivation-mediatedapoptosisof effectorCD4+Tcells. NatImmunol 2007, 8 (12):1353 – 1362. 26.LowskyR,TakahashiT,LiuYP,Dejbakhsh-JonesS,GrumetFC,ShizuruJA, LaportGG,Stockerl-GoldsteinKE,JohnstonLJ,HoppeRT, etal : Protective conditioningforacutegraft-versus-hostdisease. NEnglJMed 2005, 353 (13):1321 – 1331. 27.Darrasse-JezeG,BergotAS,DurgeauA,BilliardF,SalomonBL,CohenJL, BellierB,PodsypaninaK,KlatzmannD: Tumoremergenceissensedby self-specificCD44himemoryTregsthatcreateadominanttolerogenic environmentfortumorsinmice. JClinInvest 2009, 119 (9):2648 – 2662. 28.TsaiS,ShameliA,YamanouchiJ,Clemente-CasaresX,WangJ,SerraP,YangY, MedarovaZ,MooreA,SantamariaP: Reversalofautoimmunitybyboosting memory-likeautoregulatoryTcells. Immunity 2010,32 (4):568 – 580. 29.AlbertMH,LiuY,AnasettiC,YuXZ: Antigen-dependentsuppressionof alloresponsesbyFoxp3-inducedregulatoryTcellsintransplantation. EurJImmunol 2005, 35 (9):2598 – 2607. 30.ZangW,LinM,KalacheS,ZhangN,KrugerB,Waaga-GasserAM,GrimmM, HancockW,HeegerP,SchroppelB, etal : Inhibitionofthealloimmune responsethroughthegenerationofregulatoryTcellsbyaMHCclass II-derivedpeptide. JImmunol 2008, 181 (11):7499 – 7506. 31.DiPaoloRJ,BrinsterC,DavidsonTS,AnderssonJ,GlassD,ShevachEM: Autoantigen-specificTGFbeta-inducedFoxp3+regulatoryTcellsprevent autoimmunitybyinhibitingdendriticcellsfromactivatingautoreactive Tcells. JImmunol 2007, 179 (7):4685 – 4693. 32.LuY,SuzukiJ,GuillioliM,UmlandO,ChenZ: Inductionofself-antigenspecificFoxp3+regulatoryTcellsintheperipherybylymphodepletion treatmentwithanti-mousethymocyteglobulininmice. Immunology 2011, 134 (1):50 – 59.doi:10.1186/1471-2172-13-70 Citethisarticleas: Xia etal. : Anti-thymocyteglobulin(ATG)differentially depletesnaveandmemoryTcellsandpermitsmemory-type regulatoryTcellsinnonobesediabeticmice. BMCImmunology 2012 13 :70. 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ji 1471-2172
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dochead Research article
bibl
title
p Anti-thymocyte globulin (ATG) differentially depletes naïve and memory T cells and permits memory-type regulatory T cells in nonobese diabetic mice
aug
au id A1 ca yes snm Xiafnm Chang-Qinginsr iid I1 I2 email cqx65@yahoo.com
A2 Chernatynskayami VAnnaavche@ufl.edu
A3 WasserfallHClivecwasserf@ufl.edu
A4 WanSuiguiwansuigui@hotmai.com
A5 LooneyMBenjaminLooneyb@ufl.edu
A6 EisenbeisScottI3 SEisenbe@genyme.com
A7 WilliamsJohnJwilliams1@genyme.com
A8 Clare-SalzlerJMichaelSALZLER@pathology.ufl.edu
A9 AtkinsonAMarkATKINSON@pathology.ufl.edu
insg
ins Department of Hematology, Xuanwu Hospital, Capital Medical University, #45 Changchun Street, Xicheng District, Beijing, P.R. China
Department of Pathology, Immunology and Laboratory Medicine, University of Florida College of Medicine, Gainesville, FL 32610, USA
Genzyme Corporation, Framingham, MA, 02142, USA
source BMC Immunology
section Clinical immunology: transplants, autoimmunity and vaccinesissn 1471-2172
pubdate 2012
volume 13
issue 1
fpage 70
url http://www.biomedcentral.com/1471-2172/13/70
xrefbib pubidlist pubid idtype doi 10.1186/1471-2172-13-70pmpid 23237483
history rec date day 29month 6year 2012acc 24112012pub 14122012
cpyrt 2012collab Xia et al.; licensee BioMed Central Ltd.note This is an Open Access article distributed under the terms of the Creative Commons Attribution License (http://creativecommons.org/licenses/by/2.0), which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.
kwdg
kwd Anti-thymocyte globulin
Naïve and memory T cells
Regulatory T cells
T helper cell
Autoimmune diabetes
Nonobese diabetic mouse
abs
sec
st
Abstract
Background
ATG has been employed to deplete T cells in several immune-mediated conditions. However, whether ATG administration affects naïve and memory T cell differently is largely unknown.
The context and purpose of the study
In this study, we assessed how murine ATG therapy affected T cell subsets in NOD mice, based on their regulatory and naïve or memory phenotype, as well as its influence on antigen-specific immune responses.
Results
Peripheral blood CD4+ and CD8+ T cells post-ATG therapy declined to their lowest levels at day 3, while CD4+ T cells returned to normal levels more rapidly than CD8+ T cells. ATG therapy failed to eliminate antigen-primed T cells. CD4+ T cell responses post-ATG therapy skewed to T helper type 2 (Th2) and possibly IL-10-producing T regulatory type 1 (Tr1) cells. Intriguingly, Foxp3+ regulatory T cells (Tregs) were less sensitive to ATG depletion and remained at higher levels following in vivo recovery compared to controls. Of note, the frequency of Foxp3+ Tregs with memory T cell phenotype was significantly increased in ATG-treated animals.
Conclusion
ATG therapy may modulate antigen-specific immune responses through inducing memory-like regulatory T cells as well as other protective T cells such as Th2 and IL-10-producing Tr1 cells.
bdy
Background
Anti-thymocyte globulin (ATG), trade name thymoglobulin®, has been employed for decades as an immune modulator for a variety of clinical indications. It is currently one of the most common immunosuppressive reagents used in allogeneic transplantation abbrgrp
abbr bid B1 1
B2 2
B3 3
and more recently, in the treatment of a variety of autoimmune disorders
B4 4
B5 5
B6 6
B7 7
B8 8
. There is a common belief that ATG therapy functions through complement mediated depletion of mature T cells. However, recent data suggests that ATG therapy induces immune modulation beyond that of simple T cell depletion
B9 9
. For example, ATG therapy may facilitate tolerance induction through modulation of dendritic cells (DC), both phenotypically and functionally
B10 10
. Evidence has also shown that ATG therapy may also induce regulatory T cells (Tregs) in vivo
B11 11
B12 12
B13 13
. However, it remains unclear how ATG therapy affects naive and memory T cells in autoimmune settings such as T1D, although a recent study suggested that ATG therapy effectively eliminates alloantigen specific memory T cells in an allogeneic transplantation mouse model
13
. In the current study, we used both standard NOD mice, as well as a TCR transgenic form of these mice (i.e., NOD.BDC2.5) to investigate changes within immune cell subsets in peripheral blood, spleen and lymph nodes post-ATG therapy, specifically focusing on addressing the questions of how ATG therapy affected naive and memory T cells, including naïve and memory Tregs. These strains were utilized due to their common utilization in studies of murine ATG efficacy for type 1 diabetes, as well as the ability to utilize mice having a defined antigenic specificity. The results demonstrated that ATG therapy differentially depletes T cells from peripheral blood and lymphoid organs. ATG therapy was more efficient in depleting naïve T cells than memory T cells. Tregs appeared resistant to ATG depletion and their frequency remained at increased levels after homeostatic recovery from ATG therapy. It was also noted that proportionately Tregs with memory T cell phenotype were significantly increased post-ATG therapy. Taken collectively, we believe this is a previously unrecognized mechanism whereby ATG therapy differentially affects naïve and memory Tregs.
Methods
Mice
Female NOD/Ltj were purchased from Jackson Laboratory and housed in specific pathogen free facilities at University of Florida Animal Care Service. The Institutional Animal Care and Use Committee at University of Florida approved all animal procedures (approval ID: 20090279).
Media and reagents
RPMI1640 media with glutamine were purchased from Fisher Scientific (Pittsburgh, PA). Complete culture media were prepared using RPMI1640 plus 10% fetal bovine serum (Thermo Scientific, Waltham, MA) and 1x penicillin and streptomycin (Cellgro, Manassas, VA). Murine ATG was provided by Genzyme (Framingham, MA). Rabbit IgG isotype was purchased from the Jackson Laboratory. The following antibodies were purchased from BD Biosciences: (San Jose, CA): CD4-PerCp (clone RM4-5), CD8-FITC (clone 53–6.7), B220-APC (clone RA3-6B2), CD44-APC (clone IM7), CD11c-APC (clone HL3), CD3-PE (clone 17A2) and CD25-APC (clone PC61). The antibodies of CD62L-APC and –FITC (mEL-14) and CD11b-PE (m1/70) were purchased from eBioscience (San Diego, CA). Gr1 (Ly6G/Ly6C)-APC (clone RB6-8C5) and Foxp3-PE, -FITC (clone MF-14) were purchased from BioLegend (San Diego, CA). CellTrace CFSE kits, and CD3, CD28 antibody-coated Dynabeads were purchased from Invitrogen (Carlsbad, CA). Multiplex bead cytokine assay kits were purchased from Millipore (Billerica, MA). Mouse CD11c beads were purchased from Miltenyi Biotech (Germany). CD4+ T cell negative selection kits were purchased from StemCell Biotechnology Inc. (Vancouver, Canada). KLH was purchased from CalbioChem (San Diego, CA). Bovine serum albumin was purchased from Sigma-Aldrich (St. Louis, MO). Alum adjuvant was purchased from Thermo Scientific (Waltham, MA).
ATG treatment and observation of peripheral blood cell components
6–8 week old NOD mice were treated with two intraperitoneal injections of ATG or isotype IgG (500 ug/mouse), 3 days apart, as previously described
11
12
. In some experiments, two groups of mice were monitored longitudinally by examining white blood cell lineages using flow cytometry (LSRFortessa, BD) including CD4+, CD8+ T cells, B220+ B cells, Gr-1+ granulocytes as well as CD62L+ naive T cells and CD62-CD44+ memory T cells. The data were analyzed by FCS express De Novo software version 3 (Vancouver, Canada).
Measurement of splenic memory and naive T cells and T cell response to in vitro stimulation post ATG therapy
NOD mice were treated with ATG and isotype IgG as described above. At day 3 or 22, the treated mice were sacrificed. Single cell suspensions of spleen cells were prepared and CD4+, CD8+ T cells as well as CD62L+ naive and CD62-CD44+ memory T cells were examined by flow cytometry (LSRFortessa, BD). A portion of the spleen cells were used for CD4+ T cell isolation using CD4+ T cell negative isolation EasySep kits following the manufacturer’s instructions (StemCell Inc. Canada). Spleen cells (1 × 10sup 6) were stimulated with anti-CD3 antibody (3 ug/ml) and in some experiments, purified CD4+ T cells were stimulated with CD3 and CD28 antibody-coated Dynabeads mouse T cell activator (Invitrogen), with splenic DC plus antigens (KLH), or autoantigens (NIT-1 cell lysates) as indicated for 3–4 days, then, 3H-thymidine (1 uCi/well) was added to each well for the final 16 hours. Incorporation of 3H-thymidine was measured by scintillation counting (Wallac Trilux).
Measurement of Foxp3+ Treg cells
Spleen cells were stained with anti-CD4-PerCp and anti-CD25-APC. The cells were then fixed and permeablized and stained with anti-Foxp3-PE following the instructions of the manufacturer (eBioscience). CD4+CD25+Foxp3+ Treg cells were examined by flow cytometry (LSRFortessa, BD) and analyzed by FCS express De Novo Software version 3.
Splenic CD4+ T cell and CD11c+ DC isolation
Spleen cells were freshly prepared. Purified CD4+ T cells were prepared using EasySep CD4+ T cell negative section kit (StemCell Technologies Inc, Vancouver, Canada), and splenic DCs were labeled with anti-CD11c-microbeads, and then isolated by magnetic cell sorting following manufacturer’s instructions (Miltenyi). The purity of CD4+ T cells and CD11c+ DC was approximately 95%.
KLH immunization and recall response assay
NOD mice were treated with ATG or isotype IgG as described above along with simultaneous immunization by intraperitoneal injections of KLH (25 ug/mouse) in adjuvant Alum. The treated mice were sacrificed at day 22 post-ATG therapy and harvested cells were cultured with stimulators as indicated, or medium only for 4 days. Supernatants (50 ul/well) were harvested and stored for later cytokine assay. Then, 3H-thymidine (1 uCi/well) was added to the cultures and incubated for additional 16 hours. 3H-thymidine incorporation was measured as described above.
Autoantigen immunization and recall response in vitro and in vivo
NIT1 cells (NOD insulinoma cell line) were cultured according to the method provided from the vendor (ATCC). NIT1 cells (2 × 107) were suspended into 1 ml PBS. The cell suspension underwent freeze-thaw procedures 4 times to prepare NIT1 cell lysates. NOD mice (6 weeks old) were treated with ATG or isotype IgG as described above along with intraperitoneal injections of 50 μl of NIT1 lysates in 50 μl of Alum.
In vitro antigen recall response assay
A week following the last treatment, all mice were sacrificed and spleen cells prepared and stimulated with NIT1 lysates (10 ul/well), a control antigen KLH (10 ug/ml), or medium for 4 days. Supernatants (50 ul/well) were harvested and stored for later cytokine assay. Then, 3H-thymidine (1 uCi/well) was added to the cultures and incubated for additional 16 hours. 3H-thymidine incorporation was measured by scintillation counting. A portion of the spleen cells from the above mice were used for CD4+ T cell isolation. The isolated CD4+ T cells (2 × 105/well) were stimulated with splenic dendritic cells (2 × 104/well) purified from naive NOD mice in the presence of NIT1 lysates (20 μl/well). The T cell proliferation was measured by 3H-thymidine incorporation assay, as described above.
In vivo antigen recall response assay
In these experiments, we stained a portion of spleen cells prepared above with carboxyfluorescein succinimidyl ester (CFSE) following the instructions from the manufacturer (Invitrogen). Then, we adoptively transferred CFSE-labeled spleen cells (2 × 107/mouse), as prepared above, into 8-week-old NOD mice. Four days later, the mice were sacrificed and pancreatic lymph node cells, as well as cells from inguinal lymph node, were prepared and the CFSE-labeled T cell proliferation (dilution of CFSE) was examined by flow cytometry. In these experiments, we chose to use CFSE-labeled whole spleen cells but not purified CD4+ T cells because the whole spleen cells would be more reflecting the T cell behaviors post-ATG therapy.
Cytokine assay
Cytokine concentrations in culture supernatants, including IFN-γ, IL-4, IL-5 and IL-10, were measured by multiplex cytokine assay kits using Luminex 100 (Luminex Map Technology) following the instruction from the manufacturer (Millipore).
Statistical analysis
Data were analyzed using Student it t testing. Differences with p<0.05 were considered to be statistically significant.
Results
ATG therapy efficiently depletes T cells from peripheral blood, but is less efficient in depleting T cells from lymphoid organs
It is known that ATG therapy can largely eliminate T cells from peripheral blood. However, it was of interest to learn to what extent ATG eliminated T cells from lymphoid organs. Our kinetic observation of peripheral blood cells post-ATG therapy revealed that both the CD4+ and CD8+ T cells dropped to their lowest levels at day 3 post-ATG therapy and by day 22, peripheral blood CD4+ T cells returned to normal levels. In contrast, whereas CD8+ T cells were shown to recover, they remained significantly lower than at baseline by day 22 (Figure figr fid F1 1A and Additional file supplr sid S1 1: Figure S1). Based on the kinetic changes of blood T cells above, in subsequent experiments, we compared CD4+ and CD8+ T cells in peripheral blood and spleen at day 3 and day 22 post-ATG therapy. Again, we found that at day 3 post-ATG therapy, both CD4+ and CD8+ T cells were drastically reduced in peripheral blood (Figure 1B and D). In contrast, the reduction of both T cell populations in spleen at day 3 post-ATG therapy was significantly less than in peripheral blood (Figure 1C and D). We did not find significant differences between ATG and isotype IgG treated animals in terms of the spleen size and the total cell numbers in spleen at day 3 post-ATG therapy (data not shown and Additional file 1: Figure S2). Therefore, the percentage change would reflect the absolute number change in splenic T cells. Again, by day 22 post-treatment, the percentage of CD4+ T cells did not show significant differences between the ATG group and isotype IgG group, in both blood and spleen (Figures 1B, C and Additional file 1: Figure S1). However, CD8+ T cells were significantly lower in the ATG group than in control animals, in both blood and spleen (Figure 1B, C and Additional file 1: Figure S1). These results indicate that T cell depletion predominantly takes place in peripheral blood and that CD4+ T cells recover faster than CD8+ T cells.
suppl
Additional file 1
text
b Figure S1. The effect of ATG therapy on absolute numbers of CD4+ and CD8+ T cells. Figure S2. The effect of ATG therapy on depleting spleen cells at day 3 after ATG injection. Figure S3. The proportions of naive and memory CD4+ T cells after CD4+ T cell number recovered from ATG therapy.
file name 1471-2172-13-70-S1.pdf
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fig Figure 1caption ATG therapy differentially depletes T cells from peripheral blood and lymphoid organs.
ATG therapy differentially depletes T cells from peripheral blood and lymphoid organs. NOD mice were treated with ATG or isotype IgG twice with a 3-day interval. Then, CD4+ and CD8+T cells in peripheral blood were examined by flow cytometry every 3 days until day 22. A shows CD4+ and CD8+ T cell percentages in total peripheral white blood cells at different time points post ATG therapy (n=4 mice in each group); B and C show CD4+ and CD8+ T cell percentages in peripheral white blood cells and spleen cells, respectively (n=3 mice in each group). D exhibits CD4+ and CD8+ T cell depletion rates in peripheral blood and spleen at day 3 post ATG therapy, respectively (n=3 mice in each group). The similar results were obtained in additional two independent experiments.
graphic 1471-2172-13-70-1
ATG therapy differentially depletes naive and memory T cells from the peripheral blood and spleen
It is still a matter of debate whether ATG therapy preferentially depletes certain subsets of T cells
4
B14 14
B15 15
B16 16
B17 17
. In these experiments, we investigated changes of naive and memory T cells using CD62L and CD44 markers (shown in Figure F2 2), respectively, in peripheral blood and spleen, at day 3 and day 22 post-ATG treatment. We discovered that CD62L+CD4+ (Figures 2A and B) and CD62L+CD8+ naive T cells (data not shown) were significantly reduced at day 3 post-ATG therapy, in contrast to the Isotype IgG group, in both peripheral blood and spleen. Of interest, the percentage of CD62L-CD44+ CD4+ T cells (Figure 2A and B) and CD62L-CD44+CD8+ T cells (data not shown) in total CD4+ and CD8+ T cells, respectively, were significantly increased in the ATG group compared to the control group. These results suggest that ATG therapy may preferentially deplete naive T cells. However, by day 22 post-treatment, there were no differences between two groups in the frequency of naive and memory CD4+ T cells (Additional file 1: Figure S3). We did not find any differences between isotype IgG treated and non-treated NOD mice (data not shown).
Figure 2ATG therapy differentially depletes naive and memory T cells in peripheral blood and spleen.
ATG therapy differentially depletes naive and memory T cells in peripheral blood and spleen. NOD mice were treated with ATG or isotype IgG twice with a 3-day interval. At day 3 post treatment, CD62L+CD4+ and CD44+CD62L-CD4+ T cells in peripheral blood and spleen were examined by flow cytometry and analyzed by gating CD4+ T cells as depicted in the upper panels of A and B, respectively. A shows the summary of the percentages of CD62L+CD4+ T and CD44+CD62L- CD4+ T cells in total CD4+ T cells in the peripheral blood, respectively (lower panels). B shows the summary of the percentages of above T cell subsets in total CD4+ T cells in spleen cells, respectively (lower panels). Three mice were included in each group. Three independent experiments were performed with similar results.
1471-2172-13-70-2
ATG therapy does not affect the response of the remaining non-depleted T cells to TCR stimulation, but induces decreased levels of Th1 and enhanced levels of IL-10-producing T cells
To determine whether the immune response of T cells that are not depleted by ATG therapy alters, at day 3 post-treatment, we prepared spleen cells from ATG or isotype IgG treated NOD mice and stimulated them with anti-CD3 antibodies. T cell proliferation was measured by 3H-thymidine incorporation assay. We found that the proliferation of T cells from spleen cells of ATG-treated animals was significantly lower than those obtained from isotype IgG treated animals (Figure F3 3A). The reduced T cell proliferation was likely attributable to the lower frequency of T cells in spleen cells from ATG-treated mice. To address whether ATG treatment directly modulates T cells and alters their response to TCR activation, we purified CD4+ T cells (purity >95%) and stimulated them with CD3 and CD28 antibody coated Dynabeads. Then, T cell proliferation was examined by 3H-thymidine incorporation assay. We did not observe significant differences in terms of T cell proliferation between the two groups (Figure 3B). Characterization of cytokine-producing profiles of CD4+ T cells demonstrated that CD4+ T cells from ATG-treated mice produced significantly higher levels of IL-10 with reduced levels of IFN-γ, in contrast to those from isotype IgG treated mice (Figure 3C). These data indicate that ATG therapy skew T cell responses to IL-10-producing T cells including Th2 and Tr1.
Figure 3Proliferation of T cells from mice treated with ATG or isotype IgG in response to CD3 antibody stimulation.
Proliferation of T cells from mice treated with ATG or isotype IgG in response to CD3 antibody stimulation. NOD mice were treated with ATG or isotype IgG twice with a 3-day interval. A, At day 3 post treatment, spleen cells were prepared and stimulated with anti-CD3 antibodies for 3 days, then 3H-thymidine (1 uCi/well) was added to the cultures for additional 16 hours. 3H-thymidine incorporation was measured by scintillation counting. Three mice were tested in each group. B, part of the above spleen cells was used to isolate CD4+ T cells. The purified CD4+ T cells were stimulated with anti-CD3 and anti-CD28 antibody coated beads for 3 days. Thereafter, 3H-thymidine (1 uCi/well) was added to the cultures for additional 16 hours. T cell proliferation was examined by the method described above. C, the production of IL-10, IFN-γ in the cultures from 3 animals in each group in B was measured by Luminex. The values for IL-10 and IFN-γ for treatment group and controls are (993.3±141.0 v.s. 366.7±96.1) and (1117.0±202.8 v.s. 3793±795.5), respectively. The difference between the two groups for IL-10 and IFN-γ by Student t test is significant with p value as of 0.0221 and 0.0253, respectively. An additional independent experiment was performed with the similar results.
1471-2172-13-70-3
CD4+Foxp3+ Tregs are less sensitive to ATG depletion and remain at an increased frequency post CD4+ T cell recovery
To determine whether Tregs undergo depletion post-ATG therapy, NOD mice at 6 weeks of age were treated with ATG or isotype IgG as described earlier. We then sacrificed one-half of the mice (n=3) from each group at day 3, and the rest (n=3) at day 22 post-treatment, respectively, and examined the proportion of Foxp3+ CD4+ T cells of total CD4+ T cells as well as their absolute numbers. As shown in Figure F4 4A and B, compared to the isotype IgG group, the ATG group demonstrated a significantly increased percentage of CD25+Foxp3+ CD4+ T cells in total CD4+ T cells at day 3 post-therapy and comparable levels of absolute numbers of these cells, suggesting that Foxp3+ Tregs were resistant to ATG mediated depletion. Moreover, at day 22, when CD4+ T cells were recovered, Tregs remained at higher levels in the ATG treated group than in the isotype IgG group (Figure 4C and D). Of interest, the proportionate increase of the Tregs out of total CD4+ T cells in lymph nodes was even more dramatic in the ATG compared to the isotype IgG group at day 3 post-treatment (Figure 4E and G). The same trend was also observed for Treg’s absolute numbers (Figure 4F and H).
Figure 4Effect of ATG therapy on Foxp3+ Treg cells.
Effect of ATG therapy on Foxp3+ Treg cells. NOD mice were treated with ATG or isotype IgG twice with a 3-day interval. At day 3 and 22, CD4+Foxp3+ regulatory T cells in spleen were examined by flow cytometry and the summary of each group was shown in Figure 4A and B, and 4C and D, respectively. At day 3, CD4+Foxp3+ regulatory T cells in pancreatic and inguinal lymph nodes were also examined and shown in Figure 4E and F, 4G and H, respectively. Three mice were included in each group. The similar results were obtained in additional two independent experiments.
1471-2172-13-70-4
ATG therapy drives more CD62L- memory type Tregs
We demonstrated (Figure 2) that ATG preferentially depletes CD62L+ naïve T cells. It was then of interest to learn whether ATG therapy depleted naïve and memory Tregs differently. In these experiments, we examined splenic Tregs at day 3 post-ATG or isotype IgG treatment using flow cytometry. We gated CD4+CD25+ T cells and then analyzed for the expression of Foxp3 and CD62L. Surprisingly, we noted that ATG therapy significantly reduced CD62L+ naïve Tregs compared to isotype IgG treated animals (Figure F5 5A and B). This finding suggests that the preservation of CD62L- memory Tregs may play an important role for ATG to modulate antigen-specific immune responses.
Figure 5Effect of ATG therapy on naive and memory Tregs.
Effect of ATG therapy on naive and memory Tregs. NOD mice were treated with ATG or isotype IgG twice with a 3-day interval. At day 3 post treatment, the mice were sacrificed. The spleen cells were prepared and stained with CD4, CD25 CD62L and Foxp3 antibodies and examined by flow cytometry. CD62L+Foxp3+ and CD62L-Foxp3+ Tregs were analyzed by gating the CD4+CD25+ cell population as shown in Figure 5A. The summary of splenic CD62L+Tregs was shown in Figure 5B. ILN: inguinal lymph node; PLN: pancreatic lymph node. An additional experiment was performed with similar results.
1471-2172-13-70-5
ATG therapy fails to eliminate antigen primed T cell, but skews antigen-specific immune responses to Th2 and/or Tr1 cells
As noted earlier, ATG has been used for a variety of immune-mediated conditions such as allogeneic transplantation and autoimmune diseases. One hope for ATG therapy would be its ability to eliminate most antigen-specific T cells so that immune responses against allograft or self-tissues could be avoided. For example, in settings of autoimmune diabetes, a majority of β cell antigen-specific T cells are presumably primed and become β antigen-specific effector or memory T cells. In allogeneic transplantation, alloantigen-specific T cells are activated to become effector or memory T cells unless there is immune intervention. To address how ATG therapy affects antigen-stimulated T cells, we designed and performed a series of experiments whereby NOD mice were treated with ATG or isotype IgG, along with simultaneous immunization by KLH protein in adjuvant alum. All mice were sacrificed at day 22 post-treatment, with spleen cells prepared and incubated with KLH, BSA (unrelated antigen) and medium alone. We found that KLH strongly stimulated spleen cells from both the ATG and isotype IgG treated mice to comparable levels (Figure F6 6A). Spleen cells from either group responded poorly to BSA stimulation (Figure 6A). These findings suggest that ATG therapy is unable to eliminate antigen-primed T cells. We also found that spleen cells from both groups responded to anti-CD3 antibody stimulation similarly (Figure 6B). However, we also observed that spleen cells from the ATG treated animals produced significantly increased levels of IL-4, IL-5 and IL-10 alongside of markedly reduced levels of IFN-γ in response to stimulation of KLH (Figure 6C), in comparison to isotype IgG treated animals. These findings suggest that despite the failure to eliminate antigen-specific T cells, ATG therapy induces antigen-specific T cell responses skewed to Th2 and Tr1, and largely limits the inflammatory Th1 response.
Figure 6Effect of ATG therapy on antigen-stimulated T cell proliferation and cytokine production.
Effect of ATG therapy on antigen-stimulated T cell proliferation and cytokine production. NOD mice were treated with ATG or isotype IgG along with intraperitoneal injections of KLH in Alum as described in Methods. All mice were sacrificed at day 22 post treatment. A, spleen cells were incubated with KLH, BSA or media only; B, spleen cells were stimulated with anti-CD3 antibodies. All cultures were pulsed by 3H-thymidine (1 uCi/well) at day 4 for additional 16 hours. T cell proliferation was measured by scintillation counting. Triplicate wells were set up for each incubation. Three animals were included in each group. C, The production of cytokines in the cultures with KLH shown in Figure 6A was measured by Luminex assay. This experiment was repeated in additional two separate experiments with similar results.
1471-2172-13-70-6
ATG therapy fails to eliminate autoantigen-stimulated T cells
From the results above, it appeared that ATG therapy is unable to eliminate exogenous foreign antigen stimulated T cells (Figure 6A). It is of interest to know how ATG therapy affects self antigen-stimulated T cells. To address this issue, we stimulated β cell antigen-specific T cells in NOD mice at 6 weeks of age with an intraperitoneal injection of NIT1 (NOD mice insulinoma cell line) lysates along with ATG or isotype IgG treatment, as described previously. In these experiments, we did not wait until 22 days post treatment to assess T cell responses because of the concern that the exposure of endogenous β antigens would continuously prime T cells. Thus, at day 7 post-treatment, we sacrificed the mice, with the spleen cells prepared and stimulated with NIT1 lysates or unrelated antigen KLH. As expected, because of the transient significant depletion of T cells by ATG therapy, in response to stimulation of the NIT1 cell lysates, the proliferation of whole spleen cells from ATG-treated animals was significantly lower when compared to isotype IgG treated animals (Figure F7 7A). However, compared to the unrelated antigen KLH, NIT1 lysates still significantly stimulated spleen cells from the ATG treated animals (Figure 7A). To determine to what degree the ATG therapy depletes β antigen-specific T cells, we prepared spleen cells from the aforementioned mice and then performed an adoptive transfer of CFSE-labeled spleen cells to recipient NOD mice at 8 weeks of age. Four days later, CD4+ T cell proliferation of CFSE-labeled cells in inguinal and pancreatic lymph nodes was examined by flow cytometry. As shown in Figure 7C, in inguinal lymph nodes, the proliferation of CD4+ T cells of injected CFSE-spleen cells from ATG treated animals is slightly higher than that of CD4+ T cells from control group, which may reflect the higher T cell homeostatic proliferation potential post-ATG therapy
B18 18
. More importantly, we found the proliferation of CFSE-labeled CD4+ T cells was much higher in pancreatic than in inguinal lymph nodes for both groups, which reflects β cell-antigen specific T cell response. However, unexpectedly, in response to endogenous β cell antigens, the proliferation of those injected CD4+ T cells from ATG treated animals in pancreatic lymph node was significantly higher than that of CD4+ T cells from isotype IgG treated animals. These results further confirm that ATG therapy fails to eliminate antigen-primed T cells. To confirm this, we demonstrated that purified CD4+ T cells from the spleen cells of both groups had comparable levels of proliferation in response to stimulation of syngenic splenic DC plus NIT-1 lysates (Figure 7B). Nevertheless, consistent with the results shown in Figure 6C, the cytokine assay for the cultures shown in Figure 7B demonstrated that ATG therapy suppressed β-cell antigen-specific IFN-γ production but enhanced IL-10 production by the CD4+ T cells (Figure 7D).
Figure 7Effect of ATG therapy on self antigen-specific T cells in vivo.
Effect of ATG therapy on self antigen-specific T cells in vivo. A, Eight weeks old NOD mice were treated with ATG or isotype IgG along with intraperitoneal injections of β cell antigens NIT1 lysates as described in the Method. A week post treatment, all mice were sacrificed and spleen cells were prepared. Spleen cells (1 × 106/well) were incubated with NIT1 lysates, KLH (un-related antigen) or medium alone. Triplicate wells were set up for each incubation. T cell proliferation was measured by 3H-thymidine incorporation assay as described in the Methods section. Three mice were included in each group. Data shown represent the average of three mice+/−standard deviation (SD). B, Part of the spleen cells were used to isolate CD4+ T cells and the isolated CD4+ T cells (2 × 105/well) were incubated with splenic dendritic cells (2 × 104/well) purified from naive NOD mice in the presence of NIT1 lysates (20 μl/well). Triplicate wells were set up for each incubation. The proliferation of CD4+ T cells was measured by 3H-thymidine incorporation assay. Three mice were included in each group. Data shown represent the average of three mice+/−SD. C, Part of the mixed spleen cells from the above 3 ATG or 3 isotype IgG treated animals were stained with CSFE. Then, the CFSE-labeled spleen cells were intravenously injected into 8 weeks old naive NOD mice (3 mice per group). Four days later, the cells prepared from inguinal and pancreatic lymph nodes were stained with CD4-PerCp. The percentages of the proliferating CFSE-labeled CD4+ T cells (dilution of CFSE) were examined by flow cytometry. D, cytokines IFN-γ and IL-10 in the cultures shown in B were measured by luminex. Data shown represent average values of 3 mice+/−SD. An additional experiment was performed with similar results.
1471-2172-13-70-7
Discussion
In this study, we questioned how ATG therapy affected naïve and memory T cells including Tregs with naïve or memory phenotypes. Until now, it was unclear to what extent ATG treatment affected naive and memory T cells pools. Resolving this issue is of great significance in managing ATG therapy in autoimmune diseases as well as in allogeneic transplantation. In line with the previous reports
12
, we found that ATG therapy markedly depleted CD4+ and CD8+ T cells from the peripheral blood, and largely spared B cells and granulocytes. By day 3 post-treatment, T cell numbers reached their nadir. By day 22, CD4+ T cells recovered to within normal ranges, but CD8+ T cells remained lower than baseline. It has been suggested that ATG therapy may have differential effects in depleting T cells in peripheral blood and lymphoid organs dependent on dosing
B19 19
. In this study, we tested our treatment protocol with optimal efficacy in preventing or reversing type 1 diabetes (500 μg/mouse × 2 doses 3 days apart) as described in our other reports
11
12
. To determine the efficiency of our ATG treatment protocol in depleting T cells from the lymphoid organs, we examined splenic CD4+ and CD8+ T cells in both groups (ATG versus isotype IgG) at day 3 post-ATG therapy. We found that the depletion of both CD4+ and CD8+ T cells was less efficient in spleen than from peripheral blood. The similar results were obtained in lymph nodes such as inguinal or pancreatic lymph nodes (data not shown). Of interest, it appears that ATG therapy preferentially depletes CD62L+ naive T cells from the blood because the proportion of CD62L+CD4+ naive T cells was markedly reduced while CD44+CD62L- CD4+ memory T cells as a fraction of total CD4+ T cells were increased. We observed a similar significant trend in the change of naive and memory T cells in spleen as well. Whether this differential depleting effect of ATG exhibits in local lymph nodes, especially in pancreatic lymph nodes is of interest to be further addressed. It is unlikely that the increase of memory T cells at day 3 post-ATG therapy is due to the conversion from naïve T cells
B20 20
B21 21
because ATG is still depleting T cells during this short period of time post-ATG therapy, and homeostatic proliferation unlikely leads to much in the way of T cell conversion.The relative resistance of memory T cells to ATG-induced T cell depletion would allow for survival of memory T cells which potentially could lead to the recurrence of allograft rejection or autoimmunity after reconstitution of immune system post-ATG therapy. Consistent with this, we demonstrated that the proliferation of spleen cells from mice receiving ATG and de novo KLH immunization was as high as that of spleen cells from isotype IgG treated animals in KLH recall responses in vitro. We also found that β cell antigen-primed T cells during ATG therapy could survive ATG depletion as well. However, despite unaffected T cell proliferation in response to antigen stimulation post-ATG therapy, the T cell cytokine-producing profile in ATG treated animals indicated that ATG therapy skewed Th2 and possibly IL-10-producing Tr1, and reduced IFN-γ-producing Th1 responses. We had previously shown long-term reversal of diabetes in NOD mice using ATG or ATG in combination with G-CSF
11
12
and our current findings in this report provide a mechanistic basis for this in the skewing toward Th2 and/or IL-10-producing Tr1 responses under the regimen of ATG. In this study, although we focused our studies on CD4+ T cells, it is also important to study phenotypic and functional alterations of CD8+ T cells by the ATG therapy, given the pathogenic role of CD8+ T cells in type 1 diabetes, which will be addressed in the following future studies. The memory T cell phenotypic characteristics, as well as the functional alterations post-ATG therapy, may allow the modulated antigen-primed T cells to efficiently exert their regulatory functions in the periphery through affecting their migrating and homing capabilities, thereby preventing the recurrence of autoimmunity in autoimmune diseases and allogeneic rejection in allogeneic transplantation. These findings also implicate that ATG therapy plus antigen vaccination could lead to synergistic effect on induction of antigen-specific immune tolerance. Such information would be of great significance for developing antigen-based immunotherapeutic strategy for autoimmune diseases such as type 1 diabetes.Prior to this effort, several mechanisms underlying ATG immune modulation have been proposed. A common belief is that ATG therapy works by T cell depletion through complement-mediated cell lysis and activation-induced cell death. However, another view regarding ATG therapy is that this agent exerts immunosuppressive function beyond that of simple T cell depletion
7
9
. ATG therapy may modulate immune response in vivo through inhibiting chemokine-driven T cell chemotaxis
B22 22
. It may also influence the interaction between T cells and endothelial cells through modulating expression of adhesion molecules
22
. Our recent study showed that ATG therapy eliminated certain subset of dendritric cells and induced tolerogenic dendritic cells
10
. In addition, ATG therapy may facilitate tolerance induction through ATG-mediated apoptosis of T cells; because T cell apoptosis induced by anti-CD3 therapy was recently demonstrated to be associated with CD3 antibody therapy-induced immune tolerance
B23 23
. The skewing of antigen-specific Th2 and IL-10-producing regulatory T cells (i.e., Tr1) by ATG therapy demonstrated in the current study suggests that the non-depleted antigen-responding T cells, instead of causing immune attack, may lead to antigen-specific restoration of immune tolerance, which implies that ATG works as immune modulator rather than immune suppressant.As suggested previously, Foxp3+ Tregs may play a major role in preventing autoimmune diabetes during ATG therapy
11
12
. However, it is incompletely understood whether ATG therapy depletes Tregs differently than conventional T cells and how ATG affects the distribution of Tregs in different lymphoid tissues. It is also unclear whether ATG therapy affects naïve and memory Tregs differently. In the present study, we demonstrated that ATG therapy was less efficient in depleting CD4+Foxp3+Tregs and as a result, the proportion of CD4+Foxp3+ Tregs in CD4+ T cells was significantly increased in ATG treated animals compared to controls. This increase is even more dramatic in lymph nodes with greater than a doubling in the frequency of Tregs within total CD4+ T cells in ATG treated as compared to isotype IgG treated animals. In some animals, the percentage of Foxp3+ Tregs reaches 30% of total lymph node CD4+ T cells. Unlike equivalent absolute numbers of splenic Tregs in both groups, the absolute number of Tregs in lymph nodes was significantly higher in ATG than in Isotype IgG treated group at 3 days post treatment, suggesting that more Tregs were recruiting to the lymph nodes besides resistance to ATG depletion. The increase of Tregs in lymph nodes may be of great immunological significance for ATG to control local antigen-specific immune responses in the settings of autoimmunity such as type 1 diabetes, as well as in allogeneic transplantation. This increase of Tregs 3 days post-ATG therapy is unlikely due to the preferential proliferation of Tregs in the ATG-therapy induced lymphopenic animals
B24 24
because the proliferation is limited in this short period of time especially still under active T cell depletion. Of interest, by day 22 post-ATG treatment when CD4+ T cells return to the normal levels, Tregs remained proportionately higher in the ATG group than in control group, which may be attributable to a faster proliferation of Tregs than conventional T cells
24
because Tregs possess superior capability to utilize IL-2 to conventional T cells
B25 25
. This may also explain why a short-term ATG therapy offers a long-term protection in type 1 diabetes
11
12
and in allogeneic transplantation
2
B26 26
. Intriguingly, Tregs with memory T cell phenotype were preferentially preserved in ATG therapy, which suggests that the preserved memory Tregs specific to certain antigens would be more potent in suppressing effector T cells reactive to the same antigens. As suggested recently
B27 27
, the memory Tregs may home to areas with active immunological reaction to quickly exert their regulatory function preferentially to naïve Tregs. This also explains the findings in our recent report that the post-therapy Tregs gain heightened immunosuppressive capacity
11
. There is evidence that the progression of autoimmunity in NOD mice leads to memory-like CD8+ Tregs which can be expanded in vivo by stimulation of nanoparticles coated with MHC-carried autoantigenic peptides. Of note, injection of these nanoparticles not only prevented T1D but also reversed overt diabetes in NOD mice
B28 28
. Thus, the quantitative and qualitative changes of Tregs post ATG therapy may play an important role in suppressing antigen-specific effector T cells. Although Tregs are generally thought to suppress T cell responses in an antigen non-specific manner, emerging evidence shows that antigen-specific Tregs are more potent in suppressing antigen-specific T cell responses
B29 29
B30 30
B31 31
. Lu, et al. reported recently that ATG therapy indeed induced self-antigen-specific Tregs in vivo that could provide long-term T1D protection in NOD mice
B32 32
. Whether the increased memory Tregs post ATG therapy plus antigen challenge in our experimental settings contain more antigen-specific Tregs needs to be further explored.
Conclusions
ATG therapy preferentially depletes naive T cells, largely spares Tregs and alters T cell cytokine-producing profiles. Thus, ATG therapy may modulate antigen-specific immune responses through inducing memory-like regulatory T cells as well as other protective T cells such as Th2 and IL-10-producing Tr1 cells.
Competing interests
SE and JW are employees of Genzyme. Human Thymogobulin is a commercial product sold by Genzyme. Genzyme graciously supplied mouse thymoglobulin, but no financial support for the research described in this article. No other potential conflicts of interest relevant to this article were noted.
Authors’ contribution
CQX designed the study, analyzed the data and wrote the manuscript; AVC performed the mouse in vivo experiments and data analyses, CHW, SW and BML performed flow cytometric assay and T cell proliferation assay; SE and JW provided ATG and discussed ATG-related issues; MJCS and MAA participated in the experimental design and helped draft the manuscript. All authors read and approved the final manuscript.
bm
ack
Acknowledgement
This work was supported in part by Juvenile Diabetes Research Foundation (17-2008-1036 to CQX), Florida State Lung Transplantation Award to CQX, and Natural Science Foundation of China (Grant #81172854 to CQX).
refgrp Antilymphocyte/thymocyte globulin for graft versus host disease prophylaxis: efficacy and side effectsBacigalupoABone Marrow Transplant2005353225lpage 23110.1038/sj.bmt.1704758link fulltext 15558041Rabbit antithymocyte globulin induction therapy in adult renal transplantationHardingerKLPharmacotherapy200626121771178310.1592/phco.26.12.177117125438Immunosuppression: evolution in practice and trends, 1993–2003ShapiroRYoungJBMilfordELTrotterJFBustamiRTLeichtmanABAm J Transplant200554 Pt 287488615760415Anti-thymocyte globulin (ATG) prevents autoimmune encephalomyelitis by expanding myelin antigen-specific Foxp3+ regulatory T cellsChungDTKornTRichardJRuzekMKohmAPMillerSNahillSOukkaMInt Immunol20071981003101010.1093/intimm/dxm07817698561Intense immunosuppressive therapy followed by autologous peripheral blood selected progenitor cell reinfusion for severe autoimmune diseaseMussoMPorrettoFCrescimannoABondiFPolizziVScaloneRAm J Hematol2001662757910.1002/1096-8652(200102)66:2<75::AID-AJH1020>3.0.CO;2-V11421302Polyclonal anti-T-cell therapy for type 1 diabetes mellitus of recent onsetSaudekFHavrdovaTBoucekPKarasovaLNovotaPSkibovaJRev Diabet Stud200412808810.1900/RDS.2004.1.80pmcid 178353817491669Mechanisms of antibody immunotherapy on clonal islet reactive T cellsvan de LindePTysmaOMMedemaJPHaleGWaldmannHRoelenDLRoepBOHum Immunol2006674–526427316720206A multicenter randomized study comparing cyclosporin-A alone and antithymocyte globulin with prednisone for treatment of severe aplastic anemia. The cooperative group on the treatment of aplastic anemiaGluckmanEEsperou-BourdeauHBaruchelABoogaertsMBriereJDonadioDLevergerGLeporrierMReiffersJJanvierMetal J Autoimmun19925Suppl A2712751503621Mechanisms of action of antithymocyte globulin: T-cell depletion and beyondMohtyMLeukemia20072171387139410.1038/sj.leu.240468317410187Rabbit polyclonal mouse antithymocyte globulin administration alters dendritic cell profile and function in NOD mice to suppress diabetogenic responsesHuangYParkerMXiaCPengRWasserfallCClarkeTWuLChowdhryTCampbell-ThompsonMWilliamsJJ Immunol200918284608461510.4049/jimmunol.0713269277084119342635Immune depletion with cellular mobilization imparts immunoregulation and reverses autoimmune diabetes in nonobese diabetic miceParkerMJXueSAlexanderJJWasserfallCHCampbell-ThompsonMLBattagliaMGregoriSMathewsCESongSTrouttMDiabetes200958102277228410.2337/db09-0557275021919628781Murine antithymocyte globulin therapy alters disease progression in NOD mice by a time-dependent induction of immunoregulationSimonGParkerMRamiyaVWasserfallCHuangYBressonDSchwartzRFCampbell-ThompsonMTenaceLBruskoTDiabetes200857240541418039815A novel mechanism of action for anti-thymocyte globulin: induction of CD4+CD25+Foxp3+ regulatory T cellsLopezMClarksonMRAlbinMSayeghMHNajafianNJ Am Soc Nephrol200617102844285310.1681/ASN.200605042216914538Rabbit ATG but not horse ATG promotes expansion of functional CD4+CD25highFOXP3+ regulatory T cells in vitroFengXKajigayaSSolomouEEKeyvanfarKXuXRaghavachariNMunsonPJHerndonTMChenJYoungNSBlood200811173675368310.1182/blood-2008-01-130146227502618250226OX40 controls functionally different T cell subsets and their resistance to depletion therapyKroemerAXiaoXVuMDGaoWMinamimuraKChenMMakiTLiXCJ Immunol200717985584559117911646Short administration of polyclonal anti-T cell antibody (ALS) in NOD mice with extensive insulitis prevents subsequent development of autoimmune diabetesOgawaNMinamimuraKKodakaTMakiTJ Autoimmun200626422523110.1016/j.jaut.2006.03.00116713179CD4+ regulatory T cells are spared from deletion by antilymphocyte serum, a polyclonal anti-T cell antibodyMinamimuraKGaoWMakiTJ Immunol200617674125413216547248Homeostatic proliferation and survival of naive and memory T cellsBoymanOLetourneauSKriegCSprentJEur J Immunol20093982088209410.1002/eji.20093944419637200Persistent long-term changes in lymphocyte subsets induced by polyclonal antibodiesMullerTFGrebeSONeumannMCHeymannsJRadsakKSprengerHLangeHTransplantation199764101432143710.1097/00007890-199711270-000109392307Homeostasis of naive and memory T cellsSurhCDSprentJImmunity200829684886210.1016/j.immuni.2008.11.00219100699Naive T cell homeostasis: from awareness of space to a sense of placeTakadaKJamesonSCNat Rev Immunol200991282383210.1038/nri265719935802Functional antibodies to leukocyte adhesion molecules in antithymocyte globulinsMichalletMCPrevilleXFlacherMFournelSGenestierLRevillardJPTransplantation200375565766210.1097/01.TP.0000053198.99206.E612640305CD3-specific antibody-induced immune tolerance involves transforming growth factor-beta from phagocytes digesting apoptotic T cellsPerrucheSZhangPLiuYSaasPBluestoneJAChenWNat Med200814552853510.1038/nm174918438416Altered regulatory T cell homeostasis in patients with CD4+ lymphopenia following allogeneic hematopoietic stem cell transplantationMatsuokaKKimHTMcDonoughSBascugGWarshauerBKorethJCutlerCHoVTAlyeaEPAntinJHJ Clin Invest201012051479149310.1172/JCI41072286090220389017CD4+CD25+Foxp3+ regulatory T cells induce cytokine deprivation-mediated apoptosis of effector CD4+ T cellsPandiyanPZhengLIshiharaSReedJLenardoMJNat Immunol20078121353136210.1038/ni153617982458Protective conditioning for acute graft-versus-host diseaseLowskyRTakahashiTLiuYPDejbakhsh-JonesSGrumetFCShizuruJALaportGGStockerl-GoldsteinKEJohnstonLJHoppeRTN Engl J Med2005353131321133110.1056/NEJMoa05064216192477Tumor emergence is sensed by self-specific CD44hi memory Tregs that create a dominant tolerogenic environment for tumors in miceDarrasse-JezeGBergotASDurgeauABilliardFSalomonBLCohenJLBellierBPodsypaninaKKlatzmannDJ Clin Invest2009119926482662273593819652360Reversal of autoimmunity by boosting memory-like autoregulatory T cellsTsaiSShameliAYamanouchiJClemente-CasaresXWangJSerraPYangYMedarovaZMooreASantamariaPImmunity201032456858010.1016/j.immuni.2010.03.01520381385Antigen-dependent suppression of alloresponses by Foxp3-induced regulatory T cells in transplantationAlbertMHLiuYAnasettiCYuXZEur J Immunol20053592598260710.1002/eji.20052607716078276Inhibition of the alloimmune response through the generation of regulatory T cells by a MHC class II-derived peptideZangWLinMKalacheSZhangNKrugerBWaaga-GasserAMGrimmMHancockWHeegerPSchroppelBJ Immunol2008181117499750619017939Autoantigen-specific TGFbeta-induced Foxp3+ regulatory T cells prevent autoimmunity by inhibiting dendritic cells from activating autoreactive T cellsDiPaoloRJBrinsterCDavidsonTSAnderssonJGlassDShevachEMJ Immunol200717974685469317878367Induction of self-antigen-specific Foxp3+ regulatory T cells in the periphery by lymphodepletion treatment with anti-mouse thymocyte globulin in miceLuYSuzukiJGuillioliMUmlandOChenZImmunology20111341505910.1111/j.1365-2567.2011.03466.x317369421711461



PAGE 1

Day 3 Day 22 sFig 1. Absolute numbers of total blood white blood cells, CD4+ and CD8+ T cells post-ATG therapy NOD mice were treated with ATG as described in the Method section. At day 3 and Day 22, the blood samples were collected. Peripheral blood white blood cells (WBC) were counted using hemacytometer. CD4+ and CD8+ T cells were calculated based on the total WBC numbers and the percentages of CD4+ T cells and CD8+ T cells in total WBC by flow cytometry. Three animals were included in each group. Supplementary figure 1

PAGE 2

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Abstract
Background
ATG has been employed to deplete T cells in several immune-mediated conditions. However, whether ATG administration affects naïve and memory T cell differently is largely unknown.
The context and purpose of the study
In this study, we assessed how murine ATG therapy affected T cell subsets in NOD mice, based on their regulatory and naïve or memory phenotype, as well as its influence on antigen-specific immune responses.
Results
Peripheral blood CD4+ and CD8+ T cells post-ATG therapy declined to their lowest levels at day 3, while CD4+ T cells returned to normal levels more rapidly than CD8+ T cells. ATG therapy failed to eliminate antigen-primed T cells. CD4+ T cell responses post-ATG therapy skewed to T helper type 2 (Th2) and possibly IL-10-producing T regulatory type 1 (Tr1) cells. Intriguingly, Foxp3+ regulatory T cells (Tregs) were less sensitive to ATG depletion and remained at higher levels following in vivo recovery compared to controls. Of note, the frequency of Foxp3+ Tregs with memory T cell phenotype was significantly increased in ATG-treated animals.
Conclusion
ATG therapy may modulate antigen-specific immune responses through inducing memory-like regulatory T cells as well as other protective T cells such as Th2 and IL-10-producing Tr1 cells.
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Xia, Chang-Qing
Chernatynskaya, Anna V
Wasserfall, Clive H
Wan, Suigui
Looney, Benjamin M
Eisenbeis, Scott
Williams, John
Clare-Salzler, Michael J
Atkinson, Mark A
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Chang-Qing Xia et al.; licensee BioMed Central Ltd.
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BMC Immunology. 2012 Dec 14;13(1):70
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fptr FILEID
sword-mets-div-3
sword-mets-div-4