2024
Single-cell CAR T atlas reveals type 2 function in 8-year leukaemia remission
Bai Z, Feng B, McClory S, de Oliveira B, Diorio C, Gregoire C, Tao B, Yang L, Zhao Z, Peng L, Sferruzza G, Zhou L, Zhou X, Kerr J, Baysoy A, Su G, Yang M, Camara P, Chen S, Tang L, June C, Melenhorst J, Grupp S, Fan R. Single-cell CAR T atlas reveals type 2 function in 8-year leukaemia remission. Nature 2024, 634: 702-711. PMID: 39322664, PMCID: PMC11485231, DOI: 10.1038/s41586-024-07762-w.Peer-Reviewed Original ResearchChimeric antigen receptorChimeric antigen receptor T cellsT cellsIL-4CAR T-cell dysfunctionChimeric antigen receptor T-cell productsCAR-T cell persistenceProteomic profiling of seraCAR-T cellsT cell persistenceT-cell therapyLong-term remissionT cell dysfunctionCAR-T productsType 2 cytokinesAntigen-specific activationT cell productionAssociated with patientsType 2 cellsDysfunctional subsetPotential therapeutic strategyCellular immunotherapyLeukemia remissionPatients relapseType 2 functions
2023
CTLA-4 tail fusion enhances CAR-T antitumor immunity
Zhou X, Cao H, Fang S, Chow R, Tang K, Majety M, Bai M, Dong M, Renauer P, Shang X, Suzuki K, Levchenko A, Chen S. CTLA-4 tail fusion enhances CAR-T antitumor immunity. Nature Immunology 2023, 24: 1499-1510. PMID: 37500885, PMCID: PMC11344484, DOI: 10.1038/s41590-023-01571-5.Peer-Reviewed Original ResearchConceptsCytoplasmic tailSingle-cell RNA sequencingRNA sequencingC-terminusTail fusionCell engineering techniquesAntigen receptorFurther characterizationCytometry analysisSurface expressionCAR functionLow surface expressionCellsUnique strategyT cellsPowerful therapeuticsFusionEndocytosisLeukemia modelTerminusTailSequencingPhenotypeReduced activationEngineering techniquesImmunogenetic Metabolomics Reveals Key Enzymes That Modulate CAR T-cell Metabolism and Function.
Renauer P, Park J, Bai M, Acosta A, Lee W, Lin G, Zhang Y, Dai X, Wang G, Errami Y, Wu T, Clark P, Ye L, Yang Q, Chen S. Immunogenetic Metabolomics Reveals Key Enzymes That Modulate CAR T-cell Metabolism and Function. Cancer Immunology Research 2023, 11: 1068-1084. PMID: 37253111, PMCID: PMC10527769, DOI: 10.1158/2326-6066.cir-22-0565.Peer-Reviewed Original ResearchConceptsCAR T cellsHER2-specific CAR T cellsT cellsTumor microenvironmentChimeric antigen receptor T cellsT cell-based immunotherapyAntigen receptor T cellsCD19-specific chimeric antigen receptor (CAR) T cellsCAR T-cell therapyCell-based immunotherapyReceptor T cellsT-cell therapyVivo colorectal cancer modelsColorectal cancer modelT cell functionT cell metabolismTumor infiltrationEvasion mechanismsImmunosuppressive metaboliteImmune evasionCancer modelImmunologic analysisCD19-specificUnfavorable tumor microenvironmentPDK1 deficiency
2021
The aging transcriptome and cellular landscape of the human lung in relation to SARS-CoV-2
Chow RD, Majety M, Chen S. The aging transcriptome and cellular landscape of the human lung in relation to SARS-CoV-2. Nature Communications 2021, 12: 4. PMID: 33397975, PMCID: PMC7782551, DOI: 10.1038/s41467-020-20323-9.Peer-Reviewed Original ResearchConceptsSARS-CoV-2SARS-CoV-2 infectionHuman lungCOVID-19Natural killer/T-cellAirway smooth muscle cellsSevere coronavirus diseaseSevere COVID-19Alveolar type 2 cellsMajor risk factorType 2 cellsSmooth muscle cellsSARS-CoV-2 proteomeAge-associated genesAge-associated changesDendritic cellsRisk factorsT cellsGoblet cellsAlveolar fibroblastsCoronavirus diseaseMuscle cellsOlder populationCellular landscapeEndothelial cells
2019
In vivo CRISPR screening in CD8 T cells with AAV–Sleeping Beauty hybrid vectors identifies membrane targets for improving immunotherapy for glioblastoma
Ye L, Park JJ, Dong MB, Yang Q, Chow RD, Peng L, Du Y, Guo J, Dai X, Wang G, Errami Y, Chen S. In vivo CRISPR screening in CD8 T cells with AAV–Sleeping Beauty hybrid vectors identifies membrane targets for improving immunotherapy for glioblastoma. Nature Biotechnology 2019, 37: 1302-1313. PMID: 31548728, PMCID: PMC6834896, DOI: 10.1038/s41587-019-0246-4.Peer-Reviewed Original ResearchMeSH KeywordsAnimalsAntigens, CDCD8-Positive T-LymphocytesCell Line, TumorCRISPR-Cas SystemsDependovirusFemaleGene EditingGlioblastomaHumansImmunotherapy, AdoptiveLymphocyte Activation Gene 3 ProteinMaleMembrane ProteinsMiceN-AcetylglucosaminyltransferasesNeoplasm ProteinsProtein Disulfide-IsomerasesReceptors, Cell SurfaceRNA, Guide, CRISPR-Cas SystemsTransposasesXenograft Model Antitumor AssaysConceptsRNA cassetteMembrane protein targetsPrimary murine T cellsGenetic screening systemSingle-cell sequencingScreen hitsSleeping Beauty (SB) transposonCRISPR screensMembrane proteinsCell sequencingT cellsAdeno-associated virusGenomic integrationMembrane targetsMurine T cellsProtein targetsEfficient geneHuman GBM cellsGene editingT cell receptor transgenic modelGBM cellsBeauty transposonPDIA3T cell-based immunotherapyAntigen-specific killingSystematic Immunotherapy Target Discovery Using Genome-Scale In Vivo CRISPR Screens in CD8 T Cells
Dong MB, Wang G, Chow RD, Ye L, Zhu L, Dai X, Park JJ, Kim HR, Errami Y, Guzman CD, Zhou X, Chen KY, Renauer PA, Du Y, Shen J, Lam SZ, Zhou JJ, Lannin DR, Herbst RS, Chen S. Systematic Immunotherapy Target Discovery Using Genome-Scale In Vivo CRISPR Screens in CD8 T Cells. Cell 2019, 178: 1189-1204.e23. PMID: 31442407, PMCID: PMC6719679, DOI: 10.1016/j.cell.2019.07.044.Peer-Reviewed Original ResearchMeSH KeywordsAnimalsBreast NeoplasmsCD8-Positive T-LymphocytesCell Line, TumorClustered Regularly Interspaced Short Palindromic RepeatsCytokinesFemaleHumansImmunologic MemoryImmunotherapyMaleMiceMice, KnockoutNF-kappa BProgrammed Cell Death 1 ReceptorRNA HelicasesRNA, Guide, CRISPR-Cas SystemsTranscriptomeConceptsCRISPR screensTarget discoveryGenome-scale CRISPR screensCD8 TRNA helicase DHX37Vivo CRISPR screensGenetic screenGenome scaleTranscriptomic profilingBiochemical interrogationAntigen-specific CD8 TAnti-tumor immune responseFunctional regulatorTriple-negative breast cancerDHX37Essential roleTim-3PD-1Cytokine productionTumor infiltrationImmunotherapy targetImmunotherapy settingsRegulatorBreast cancerT cells