2023
Combinatorial Immunotherapy with Agonistic CD40 Activates Dendritic Cells to Express IL12 and Overcomes PD-1 Resistance.
Krykbaeva I, Bridges K, Damsky W, Pizzurro G, Alexander A, McGeary M, Park K, Muthusamy V, Eyles J, Luheshi N, Turner N, Weiss S, Olino K, Kaech S, Kluger H, Miller-Jensen K, Bosenberg M. Combinatorial Immunotherapy with Agonistic CD40 Activates Dendritic Cells to Express IL12 and Overcomes PD-1 Resistance. Cancer Immunology Research 2023, 11: 1332-1350. PMID: 37478171, DOI: 10.1158/2326-6066.cir-22-0699.Peer-Reviewed Original ResearchMeSH KeywordsAnimalsCD40 AntigensCD8-Positive T-LymphocytesCytokinesDendritic CellsDisease Models, AnimalHumansImmunotherapyInterleukin-12MiceNeoplasmsProgrammed Cell Death 1 ReceptorTumor MicroenvironmentConceptsPD-1 resistanceDendritic cellsTumor regressionAnti-PD-1 resistanceActivates Dendritic CellsCytokine secretion profilingSystemic cytokine profileTriple therapy combinationInnate immune activationAdaptive immune responsesComplete tumor regressionMajority of miceSignificant clinical challengeMouse melanoma modelT cell activationAgonistic CD40Checkpoint inhibitorsDC subsetsTriple therapyCytokine profileImmune activationCombinatorial immunotherapyTherapy combinationsT cellsClinical challengeLenvatinib or anti-VEGF in combination with anti-PD-1 differentially augments anti-tumor activity in melanoma
Tran T, Caulfield J, Zhang L, Schoenfeld D, Djureinovic D, Chiang V, Oria V, Weiss S, Olino K, Jilaveanu L, Kluger H. Lenvatinib or anti-VEGF in combination with anti-PD-1 differentially augments anti-tumor activity in melanoma. JCI Insight 2023, 8: e157347. PMID: 36821392, PMCID: PMC10132152, DOI: 10.1172/jci.insight.157347.Peer-Reviewed Original ResearchMeSH KeywordsAnimalsCell Line, TumorCytokinesMelanomaMicePhenylurea CompoundsProgrammed Cell Death 1 ReceptorTumor MicroenvironmentVascular Endothelial Growth Factor AConceptsTumor microenvironmentAnti-VEGFCytokine/chemokine signalingCytokine/chemokine profilingBlood-brain barrier modelBlood vesselsLeukocyte transmigrationTumor-associated blood vesselsTumor-associated macrophagesIntratumoral blood vesselsAnti-angiogenesis effectAnti-tumor activityExtracranial diseasePlasmacytoid DCsImmune checkpointsPD-1Melanoma murine modelImmune infiltrationBBB modelChemokine profilingEndothelial stabilizationMurine modelLenvatinibCombined targetingMelanoma model
2019
Immunotherapy of Melanoma: Facts and Hopes
Weiss SA, Wolchok JD, Sznol M. Immunotherapy of Melanoma: Facts and Hopes. Clinical Cancer Research 2019, 25: 5191-5201. PMID: 30923036, PMCID: PMC6726509, DOI: 10.1158/1078-0432.ccr-18-1550.Peer-Reviewed Original ResearchMeSH KeywordsAnimalsAntineoplastic Agents, ImmunologicalClinical Trials as TopicCTLA-4 AntigenHumansImmunotherapyMelanomaNeoplasm MetastasisPrognosisProgrammed Cell Death 1 ReceptorRandomized Controlled Trials as TopicConceptsOverall survivalMetastatic diseaseImmune therapyPredictive biomarkersNivolumab/ipilimumab combinationRandomized phase III trialLong-term clinical benefitImmunobiology of tumorsDuration of therapyPhase III trialsLong-term survivorsEffective immune therapyAdjuvant settingIpilimumab combinationMetastatic settingIII trialsPatient subsetsClinical benefitImmune modulationMetastatic melanomaClinical trialsSingle agentTherapyTrue increaseCell therapyPatterns of failure after immunotherapy with checkpoint inhibitors predict durable progression-free survival after local therapy for metastatic melanoma
Klemen ND, Wang M, Feingold PL, Cooper K, Pavri SN, Han D, Detterbeck FC, Boffa DJ, Khan SA, Olino K, Clune J, Ariyan S, Salem RR, Weiss SA, Kluger HM, Sznol M, Cha C. Patterns of failure after immunotherapy with checkpoint inhibitors predict durable progression-free survival after local therapy for metastatic melanoma. Journal For ImmunoTherapy Of Cancer 2019, 7: 196. PMID: 31340861, PMCID: PMC6657062, DOI: 10.1186/s40425-019-0672-3.Peer-Reviewed Original ResearchConceptsThree-year progression-free survivalProgression-free survivalDisease-specific survivalFive-year disease-specific survivalPatterns of failureDurable progression-free survivalLocal therapyStereotactic body radiotherapyMetastatic melanomaNew metastasesPatient selectionIndependent radiological reviewOngoing complete responseResultsFour hundred twentyEvidence of diseaseCNS metastasisCPI treatmentImmunotherapy failureCheckpoint inhibitorsMost patientsProgressive diseaseRadiological reviewComplete responsePD-1PD-L1
2018
Collateral Damage: Insulin-Dependent Diabetes Induced With Checkpoint Inhibitors
Stamatouli AM, Quandt Z, Perdigoto AL, Clark PL, Kluger H, Weiss SA, Gettinger S, Sznol M, Young A, Rushakoff R, Lee J, Bluestone JA, Anderson M, Herold KC. Collateral Damage: Insulin-Dependent Diabetes Induced With Checkpoint Inhibitors. Diabetes 2018, 67: dbi180002. PMID: 29937434, PMCID: PMC6054443, DOI: 10.2337/dbi18-0002.Peer-Reviewed Original ResearchMeSH KeywordsAnimalsAntineoplastic Agents, ImmunologicalAutoimmune DiseasesB7-H1 AntigenDiabetes Mellitus, Type 1Genetic Predisposition to DiseaseGenotypeHLA-DR4 AntigenHumansHypoglycemic AgentsInsulinInsulin SecretionIsoantibodiesKetosisModels, ImmunologicalNeoplasmsPancreasPancreatitisProgrammed Cell Death 1 ReceptorConceptsInsulin-dependent diabetesCheckpoint inhibitorsAdverse eventsHLA-DR4Classic type 1 diabetesPD-L1 checkpoint inhibitorsEvidence of pancreatitisImmune adverse eventsSolid organ cancersType 1 diabetesPeridiagnosis periodPositive autoantibodiesL1 antibodyInsulin-DependentHigh riskPatientsDiabetesCancerInhibitorsKetoacidosisAutoimmuneAutoantibodiesPancreatitisComplicationsSyndrome