2018
A dormant TIL phenotype defines non-small cell lung carcinomas sensitive to immune checkpoint blockers
Gettinger SN, Choi J, Mani N, Sanmamed MF, Datar I, Sowell R, Du VY, Kaftan E, Goldberg S, Dong W, Zelterman D, Politi K, Kavathas P, Kaech S, Yu X, Zhao H, Schlessinger J, Lifton R, Rimm DL, Chen L, Herbst RS, Schalper KA. A dormant TIL phenotype defines non-small cell lung carcinomas sensitive to immune checkpoint blockers. Nature Communications 2018, 9: 3196. PMID: 30097571, PMCID: PMC6086912, DOI: 10.1038/s41467-018-05032-8.Peer-Reviewed Original ResearchMeSH KeywordsAmino Acid SequenceAnimalsAntibodies, BlockingCarcinogenesisCarcinoma, Non-Small-Cell LungCell ProliferationCytotoxicity, ImmunologicHistocompatibility Antigens Class IHumansLung NeoplasmsLymphocyte ActivationLymphocytes, Tumor-InfiltratingMaleMice, Inbred NODMice, SCIDMutant ProteinsMutationPeptidesPhenotypeProgrammed Cell Death 1 ReceptorReproducibility of ResultsSurvival AnalysisTobaccoConceptsImmune checkpoint blockersCheckpoint blockersQuantitative immunofluorescenceNon-small cell lung carcinoma patientsCell lung carcinoma patientsNon-small cell lung carcinomaPatient-derived xenograft modelsIntratumoral T cellsMultiplexed quantitative immunofluorescencePD-1 blockadeLevels of CD3Lung carcinoma patientsCell lung carcinomaT cell proliferationPre-treatment samplesTIL phenotypeSurvival benefitCarcinoma patientsEffector capacityLung carcinomaT cellsWhole-exome DNA sequencingXenograft modelFavorable responseBlockers
2009
Analysis of Drosophila Segmentation Network Identifies a JNK Pathway Factor Overexpressed in Kidney Cancer
Liu J, Ghanim M, Xue L, Brown CD, Iossifov I, Angeletti C, Hua S, Nègre N, Ludwig M, Stricker T, Al-Ahmadie HA, Tretiakova M, Camp RL, Perera-Alberto M, Rimm DL, Xu T, Rzhetsky A, White KP. Analysis of Drosophila Segmentation Network Identifies a JNK Pathway Factor Overexpressed in Kidney Cancer. Science 2009, 323: 1218-1222. PMID: 19164706, PMCID: PMC2756524, DOI: 10.1126/science.1157669.Peer-Reviewed Original ResearchMeSH KeywordsAmino Acid SequenceAnimalsApoptosisCarcinoma, Renal CellCell LineCompound Eye, ArthropodDrosophila melanogasterDrosophila ProteinsEmbryo, NonmammalianFushi Tarazu Transcription FactorsGene Expression ProfilingGene Regulatory NetworksHomeodomain ProteinsHumansJanus KinasesKidneyKidney NeoplasmsMolecular Sequence DataNervous SystemNuclear ProteinsPhosphoprotein PhosphatasesPhosphorylationRepressor ProteinsSignal TransductionTranscription FactorsTranscription, GeneticConceptsTranscription factorsClear cell renal cell carcinomaCell renal cell carcinomaKey transcription factorDrosophila segmentation networkConserved roleEmbryonic segmentationDrosophila melanogasterUbiquitin E3JNK signalingDependent apoptosisSPOPRenal cell carcinomaSPOP expressionKidney cancerTumor necrosis factorNew roleDrosophilaMelanogasterPuckeredGenesSignalingOverexpressedIdentificationApoptosis
2001
Novel inactivating mutations of transforming growth factor‐β type I receptor gene in head‐and‐neck cancer metastases
Chen T, Yan W, Wells R, Rimm D, McNiff J, Leffell D, Reiss M. Novel inactivating mutations of transforming growth factor‐β type I receptor gene in head‐and‐neck cancer metastases. International Journal Of Cancer 2001, 93: 653-661. PMID: 11477574, DOI: 10.1002/ijc.1381.Peer-Reviewed Original ResearchMeSH KeywordsActivin Receptors, Type IAmino Acid SequenceDisease ProgressionEndoplasmic ReticulumFemaleHead and Neck NeoplasmsHumansMaleMolecular Sequence DataMutationNeoplasms, Glandular and EpithelialNeoplasms, Unknown PrimaryProtein Serine-Threonine KinasesReceptor, Transforming Growth Factor-beta Type IReceptors, Transforming Growth Factor betaSequence Homology, Amino AcidSignal TransductionTransforming Growth Factor betaConceptsT beta RNeck cancer metastasisTGF-beta signalingCancer metastasisBeta RTGF betaBeta signalingLate-stage diseaseHuman epithelial neoplasmsCorresponding primary tumorsBreast cancer metastasisFine needle aspiratesTGF-beta type I receptorNovel inactivating mutationsBeta type I receptorType I receptorStage diseaseCarcinoma cell linesPrimary tumorCell cycle arrestEpithelial neoplasmsCodon 387MetastasisI receptorHuman tumors
1999
Beta- and gamma-catenin mutations, but not E-cadherin inactivation, underlie T-cell factor/lymphoid enhancer factor transcriptional deregulation in gastric and pancreatic cancer.
Caca K, Kolligs FT, Ji X, Hayes M, Qian J, Yahanda A, Rimm DL, Costa J, Fearon ER. Beta- and gamma-catenin mutations, but not E-cadherin inactivation, underlie T-cell factor/lymphoid enhancer factor transcriptional deregulation in gastric and pancreatic cancer. Molecular Cancer Research 1999, 10: 369-76. PMID: 10392898.Peer-Reviewed Original ResearchMeSH KeywordsAdenomatous Polyposis Coli ProteinAmino Acid SequenceAnimalsBeta CateninCadherinsCytoskeletal ProteinsDesmoplakinsDNA-Binding ProteinsGamma CateninGene Expression Regulation, NeoplasticHMGB ProteinsHumansLymphoid Enhancer-Binding Factor 1Molecular Sequence DataMutagenesisPancreatic NeoplasmsStomach NeoplasmsTCF Transcription FactorsTrans-ActivatorsTranscription Factor 7-Like 1 ProteinTranscription FactorsTranscription, GeneticTumor Cells, CulturedConceptsPhosphorylation sitesMutant proteinsGlycogen synthase kinase 3beta phosphorylation sitesGlycogen synthase kinase-3betaFactor transcription factorsPotential phosphorylation sitesSynthase kinase-3betaTCF transcriptional activityE-cadherin inactivationNH2-terminal deletionsRole of APCImportant binding partnerSerine 28TCF transcriptionTranscriptional deregulationT-cell factorBinding partnerTranscription factorsAPC proteinKinase-3betaTranscriptional activityNH2 terminusAdenomatous polyposis coli (APC) mutationsCell adhesionPancreatic cancer linesFrequent mutation and nuclear localization of beta-catenin in anaplastic thyroid carcinoma.
Garcia-Rostan G, Tallini G, Herrero A, D'Aquila TG, Carcangiu ML, Rimm DL. Frequent mutation and nuclear localization of beta-catenin in anaplastic thyroid carcinoma. Cancer Research 1999, 59: 1811-5. PMID: 10213482.Peer-Reviewed Original ResearchConceptsNuclear localizationSingle-strand conformational polymorphismE-cadherin-mediated cell-cell adhesionBeta-catenin actsFrequent nuclear localizationCell-cell adhesionExon 3Conformational polymorphismBeta-catenin genePhosphorylation sitesWingless pathwayTranscriptional activationCytoplasmic proteinsSubcellular localizationMobility shiftMutational analysisNucleotide sequencingDNA sequencingNuclear translocationSomatic alterationsMutationsAnaplastic thyroid carcinomaSequencingProteinFrequent mutations
1997
Vinculin Is Associated with the E-cadherin Adhesion Complex*
Hazan R, Kang L, Roe S, Borgen P, Rimm D. Vinculin Is Associated with the E-cadherin Adhesion Complex*. Journal Of Biological Chemistry 1997, 272: 32448-32453. PMID: 9405455, DOI: 10.1074/jbc.272.51.32448.Peer-Reviewed Original ResearchConceptsE-cadherin complexAdhesion complexesMDA-MB-468 cellsCalcium-dependent cell-cell adhesionE-cadherin adhesion complexAlpha-catenin geneCadherin-dependent adhesionCell-cell adhesionCell adhesion complexesE-cadherinCell linesAlpha-catenin expressionAlpha cateninReciprocal immunoprecipitationCytoplasmic interactionsCoprecipitation analysisAnti-vinculin antibodiesVinculinCadherinCytoplasmic connectionsFusion proteinE-cadherin expressionSame binding siteMDA-MB-468 breast cancer cell lineCell lysates
1994
Molecular Cloning Reveals Alternative Splice Forms of Human α(E)-Catenin
Rimm DL, Kebriaei P, Morrow JS. Molecular Cloning Reveals Alternative Splice Forms of Human α(E)-Catenin. Biochemical And Biophysical Research Communications 1994, 203: 1691-1699. PMID: 7945318, DOI: 10.1006/bbrc.1994.2381.Peer-Reviewed Original ResearchMeSH KeywordsAlpha CateninAlternative SplicingAmino Acid SequenceAnimalsBase SequenceCadherinsCell LineChickensCloning, MolecularConserved SequenceCytoskeletal ProteinsDNA, ComplementaryDrosophilaHominidaeHumansMiceMolecular Sequence DataPhylogenyPolymerase Chain ReactionRNA, MessengerSequence Homology, Amino AcidTranscription, GeneticConceptsCadherin cell-cell adhesion complexCell-cell adhesion complexAmino acid proteinAlternative splice formsSuperfamily of proteinsAmino acid insertionTranscription sitesAdhesion complexesCytoplasmic domainDistinct transcriptsMolecular cloningSingle geneAcid proteinSplice formsAcid insertionSecond transcriptCatenin geneSplice siteNon-epithelial tissuesVinculinTranscriptsCateninHuman alphaSouthern blottingProtein
1991
Analysis of cDNA clones for Acanthamoeba profilin‐I and profilin‐II shows end to end homology with vertebrate profilins and a small family of profilin genes
Pollard T, Rimm D. Analysis of cDNA clones for Acanthamoeba profilin‐I and profilin‐II shows end to end homology with vertebrate profilins and a small family of profilin genes. Cytoskeleton 1991, 20: 169-177. PMID: 1751969, DOI: 10.1002/cm.970200209.Peer-Reviewed Original ResearchConceptsProfilin IIDNA sequencesProtein sequencesAcanthamoeba profilinGenomic DNA fragmentsFull-length cDNAFamily of proteinsProfilin geneAncestral precursorDifferent phylaInvariant residuesAdditional genesCDNA clonesLength cDNAConservative substitutionsPairwise identityDNA fragmentsSouthern blotNorthern blotGenesProfilinAmino acidsSmall familyCDNAConsiderable divergence
1984
Structural analysis of the murine IgG3 constant region gene.
Wels J, Word C, Rimm D, Der-Balan G, Martinez H, Tucker P, Blattner F. Structural analysis of the murine IgG3 constant region gene. The EMBO Journal 1984, 3: 2041-6. PMID: 6092053, PMCID: PMC557641, DOI: 10.1002/j.1460-2075.1984.tb02089.x.Peer-Reviewed Original ResearchConceptsConstant region genesMembrane exonsMRNA precursorsHeavy chain constant region genesAmino acid sequenceRegion genesSwitch recombination regionC gamma 3 geneGamma 3 chainCarbohydrate addition sitesProtein domainsC deltaCarboxyl terminusComplete sequenceAcid sequenceRemarkable homologyGamma 3 geneAddition siteSwitch sitesSecondary structureMembrane formClass switch mechanismExonsGenesC mu