Featured Publications
Comparative Molecular Life History of Spontaneous Canine and Human Gliomas
Amin S, Anderson K, Boudreau C, Martinez-Ledesma E, Kocakavuk E, Johnson K, Barthel F, Varn F, Kassab C, Ling X, Kim H, Barter M, Lau C, Ngan C, Chapman M, Koehler J, Long J, Miller A, Miller C, Porter B, Rissi D, Mazcko C, LeBlanc A, Dickinson P, Packer R, Taylor A, Rossmeisl J, Woolard K, Heimberger A, Levine J, Verhaak R. Comparative Molecular Life History of Spontaneous Canine and Human Gliomas. Cancer Cell 2020, 37: 243-257.e7. PMID: 32049048, PMCID: PMC7132629, DOI: 10.1016/j.ccell.2020.01.004.Peer-Reviewed Original ResearchMeSH KeywordsAnimalsBrain NeoplasmsDNA MethylationDogsExomeGliomaHumansIsocitrate DehydrogenaseMutationTumor Suppressor Protein p53ConceptsComparative genomic analysisDNA methylation patternsReceptor tyrosine kinasesCell cycle pathwayGenomic analysisMethylation sequencingLife historyMutational processesTyrosine kinaseHigh similarityHuman gliomasTumorigenic mechanismsHost environmentMutational rateSomatic alterationsSporadic gliomasIDH1 R132Canine gliomasMolecular profileGlioma etiologyHuman pediatricPediatric gliomasTranscriptomeKinaseUnique insights
2022
Glioma progression is shaped by genetic evolution and microenvironment interactions
Varn F, Johnson K, Martinek J, Huse J, Nasrallah M, Wesseling P, Cooper L, Malta T, Wade T, Sabedot T, Brat D, Gould P, Wöehrer A, Aldape K, Ismail A, Sivajothi S, Barthel F, Kim H, Kocakavuk E, Ahmed N, White K, Datta I, Moon H, Pollock S, Goldfarb C, Lee G, Garofano L, Anderson K, Nehar-Belaid D, Barnholtz-Sloan J, Bakas S, Byrne A, D’Angelo F, Gan H, Khasraw M, Migliozzi S, Ormond D, Paek S, Van Meir E, Walenkamp A, Watts C, Weiss T, Weller M, Palucka K, Stead L, Poisson L, Noushmehr H, Iavarone A, Verhaak R, Consortium T, Varn F, Johnson K, Martinek J, Huse J, Nasrallah M, Wesseling P, Cooper L, Malta T, Wade T, Sabedot T, Brat D, Gould P, Wöehrer A, Aldape K, Ismail A, Sivajothi S, Barthel F, Kim H, Kocakavuk E, Ahmed N, White K, Datta I, Moon H, Pollock S, Goldfarb C, Lee G, Garofano L, Anderson K, Nehar-Belaid D, Barnholtz-Sloan J, Bakas S, Byrne A, D’Angelo F, Gan H, Khasraw M, Migliozzi S, Ormond D, Paek S, Van Meir E, Walenkamp A, Watts C, Weiss T, Weller M, Alfaro K, Amin S, Ashley D, Bock C, Brodbelt A, Bulsara K, Castro A, Connelly J, Costello J, de Groot J, Finocchiaro G, French P, Golebiewska A, Hau A, Hong C, Horbinski C, Kannan K, Kouwenhoven M, Lasorella A, LaViolette P, Ligon K, Lowman A, Mehta S, Miletic H, Molinaro A, Ng H, Niclou S, Niers J, Phillips J, Rabadan R, Rao G, Reifenberger G, Sanai N, Short S, Smitt P, Sloan A, Smits M, Snyder J, Suzuki H, Tabatabai G, Tanner G, Tomaszewski W, Wells M, Westerman B, Wheeler H, Xie J, Yung W, Zadeh G, Zhao J, Palucka K, Stead L, Poisson L, Noushmehr H, Iavarone A, Verhaak R. Glioma progression is shaped by genetic evolution and microenvironment interactions. Cell 2022, 185: 2184-2199.e16. PMID: 35649412, PMCID: PMC9189056, DOI: 10.1016/j.cell.2022.04.038.Peer-Reviewed Original ResearchMeSH KeywordsAdultBrain NeoplasmsEvolution, MolecularGenes, p16GliomaHumansIsocitrate DehydrogenaseMutationNeoplasm Recurrence, LocalTumor MicroenvironmentConceptsSpecific ligand-receptor interactionsMicroenvironment interactionsDNA sequencing dataGlioma progressionLigand-receptor interactionsNeoplastic cellsSignaling programsCell statesSequencing dataGenetic evolutionGenetic changesIDH wild-type tumorsIsocitrate dehydrogenaseMesenchymal transitionSomatic alterationsDistinct mannerActive tumor growthIDH-mutant gliomasPotential targetTherapy resistanceAdult patientsDisease progressionPossible roleCellsTumor growth
2019
Longitudinal molecular trajectories of diffuse glioma in adults
Barthel FP, Johnson KC, Varn FS, Moskalik AD, Tanner G, Kocakavuk E, Anderson KJ, Abiola O, Aldape K, Alfaro KD, Alpar D, Amin SB, Ashley DM, Bandopadhayay P, Barnholtz-Sloan JS, Beroukhim R, Bock C, Brastianos PK, Brat DJ, Brodbelt AR, Bruns AF, Bulsara KR, Chakrabarty A, Chakravarti A, Chuang JH, Claus EB, Cochran EJ, Connelly J, Costello JF, Finocchiaro G, Fletcher MN, French PJ, Gan HK, Gilbert MR, Gould PV, Grimmer MR, Iavarone A, Ismail A, Jenkinson MD, Khasraw M, Kim H, Kouwenhoven MCM, LaViolette PS, Li M, Lichter P, Ligon KL, Lowman AK, Malta TM, Mazor T, McDonald KL, Molinaro AM, Nam DH, Nayyar N, Ng HK, Ngan CY, Niclou SP, Niers JM, Noushmehr H, Noorbakhsh J, Ormond DR, Park CK, Poisson LM, Rabadan R, Radlwimmer B, Rao G, Reifenberger G, Sa JK, Schuster M, Shaw BL, Short SC, Smitt PAS, Sloan AE, Smits M, Suzuki H, Tabatabai G, Van Meir EG, Watts C, Weller M, Wesseling P, Westerman BA, Widhalm G, Woehrer A, Yung WKA, Zadeh G, Huse JT, De Groot JF, Stead LF, Verhaak RGW. Longitudinal molecular trajectories of diffuse glioma in adults. Nature 2019, 576: 112-120. PMID: 31748746, PMCID: PMC6897368, DOI: 10.1038/s41586-019-1775-1.Peer-Reviewed Original ResearchMeSH KeywordsAdultChromosomes, Human, Pair 1Chromosomes, Human, Pair 19Disease ProgressionGliomaHumansIsocitrate DehydrogenaseMutationPolymorphism, Single NucleotideRecurrenceConceptsAdult patientsDiffuse gliomasRecurrent gliomaOverall survivalPoor outcomeCurrent therapiesChromosome arms 1p/19qAcquired alterationsMajor subtypesTherapeutic resistanceGliomasGlioma developmentGene alterationsIDH mutationsGlioma subtypesPatientsHypermutator phenotypeDriver genesSubtypesClinical annotationSurvivalSubclonal selectionCell cycleAlterationsLittle evidence