1 4876 110 OVEREXPRESSION OF ARGINASE 1 IS LINKED TO DNMT3A AND TET2 MUTATIONS IN LOWER-GRADE MYELODYSPLASTIC SYNDROMES AND CHRONIC MYELOMONOCYTIC LEUKEMIA. IMMUNE DYSREGULATION IS A COMMON FEATURE OF MYELODYSPLASTIC SYNDROMES (MDS) AND CHRONIC MYELOMONOCYTIC LEUKEMIA (CMML), PARTICULARLY IN EARLY STAGES. HOWEVER, THE GENETIC BASIS REMAINS POORLY UNDERSTOOD. WE RECENTLY REPORTED THAT MACROPHAGES FROM MICE DEFICIENT IN TET METHYLCYTOSINE DIOXYGENASE 2 (TET2), A MODEL OF MDS/CMML, ARE HYPERINFLAMMATORY AND HAVE INCREASED EXPRESSION OF ARGINASE 1 (ARG1). IN MACROPHAGES AND MYELOID DERIVED SUPPRESSOR CELLS (MDSCS) EXPRESSION OF ARG1 CONTRIBUTES TO T-CELL SUPPRESSION AND IMMUNE EVASION BY L-ARGININE DEPLETION, IN THE SETTING OF CHRONIC INFLAMMATION AND CANCER. SINCE HUMAN MDS AND CMML ARE DRIVEN BY TET2 MUTATIONS AND ASSOCIATED WITH CHRONIC INFLAMMATION, WE HYPOTHESIZED THAT ARGINASE ENZYMATIC ACTIVITY AND ARG1 EXPRESSION WOULD BE INCREASED IN HUMAN MDS/CMML BONE MARROW. ELEVATED ARGINASE ACTIVITY WAS OBSERVED IN BONE MARROW MONONUCLEAR CELLS OF MDS AND CMML PATIENTS WITH LOWER-GRADE FEATURES. IMMUNOHISTOCHEMICAL STUDIES CONFIRMED THAT MYELOMONOCYTIC CELLS OVEREXPRESS ARG1. ADDITIONALLY, MUTATIONS IN THE EPIGENETIC REGULATORS TET2 AND DNMT3A CORRESPONDED TO HIGH ARG1 EXPRESSION AND ACTIVITY. THESE FINDINGS SUGGEST ARG1 IS A BIOMARKER OF IMMUNE DYSREGULATION IN EARLY MDS AND CMML. RECENT MURINE FINDINGS HAVE IMPLICATED TET2 AND DNMT3A IN REGULATION OF INNATE IMMUNITY. OUR STUDY SUGGESTS SIMILAR CHANGES MAY BE DRIVEN BY HUMAN TET2 AND DNMT3A MUTATIONS. 2018 2 5983 51 TET2 RESTRAINS INFLAMMATORY GENE EXPRESSION IN MACROPHAGES. TET METHYLCYTOSINE DIOXYGENASE 2 (TET2) IS ONE OF THE EARLIEST AND MOST FREQUENTLY MUTATED GENES IN CLONAL HEMATOPOIESIS OF INDETERMINATE POTENTIAL (CHIP) AND MYELOID CANCERS, INCLUDING MYELODYSPLASTIC SYNDROMES (MDS) AND CHRONIC MYELOMONOCYTIC LEUKEMIA (CMML). TET2 CATALYZES THE OXIDATION OF 5-METHYLCYTOSINE TO 5-HYDROXYMETHYLCYTOSINE, LEADING TO DNA DEMETHYLATION, AND ALSO AFFECTS TRANSCRIPTION BY RECRUITING HISTONE MODIFIERS. INACTIVATING TET2 MUTATIONS CAUSE EPIGENETIC DYSREGULATION, CLONAL HEMATOPOIETIC STEM CELL (HSC) DOMINANCE, AND MONOCYTIC LINEAGE SKEWING. HERE, WE FOUND THAT TET2 WAS THE MOST HIGHLY EXPRESSED TET ENZYME IN MURINE MACROPHAGE (MPHI) DIFFERENTIATION. TET2 TRANSCRIPTION WAS FURTHER INDUCED BY LIPOPOLYSACCHARIDE (LPS), BUT NOT INTERLEUKIN (IL)-4, STIMULATION, POTENTIALLY IN A NUCLEAR FACTOR KAPPABETA-DEPENDENT MANNER. TET2 LOSS DID NOT AFFECT EARLY LPS GENE RESPONSES IN VITRO, BUT INCREASED IL-1B, IL-6, AND ARGINASE 1 (ARG1) MRNA EXPRESSION AT LATER STAGES OF STIMULATION IN BONE-MARROW-DERIVED MPHIS (BMMPHIS). TET2-DEFICIENT PERITONEAL MPHIS, HOWEVER, DEMONSTRATED PROFOUND, CONSTITUTIVE EXPRESSION OF LPS-INDUCED GENES ASSOCIATED WITH AN INFLAMMATORY STATE IN VIVO. IN CONTRAST, TET2 DEFICIENCY DID NOT AFFECT ALTERNATIVE MPHI GENE EXPRESSION SIGNIFICANTLY IN RESPONSE TO IL-4. THESE RESULTS SUGGESTED IMPAIRED RESOLUTION OF INFLAMMATION IN THE ABSENCE OF TET2 BOTH IN VITRO AND IN VIVO. FOR THE FIRST TIME, WE ALSO DETECTED TET2 MUTATIONS IN BMMPHIS FROM MDS AND CMML PATIENTS AND ASSAYED THEIR EFFECTS ON LPS RESPONSES, INCLUDING THEIR POTENTIAL INFLUENCE ON HUMAN IL-6 EXPRESSION. OUR RESULTS SHOW THAT TET2 RESTRAINS INFLAMMATION IN MURINE MPHIS AND MICE, RAISING THE POSSIBILITY THAT LOSS OF TET2 FUNCTION IN MPHIS MAY ALTER THE IMMUNE ENVIRONMENT IN THE LARGE ELDERLY POPULATION WITH TET2-MUTANT CHIP AND IN TET2-MUTANT MYELOID CANCER PATIENTS. 2017 3 5971 36 TET PROTEINS AND 5-METHYLCYTOSINE OXIDATION IN HEMATOLOGICAL CANCERS. DNA METHYLATION HAS PIVOTAL REGULATORY ROLES IN MAMMALIAN DEVELOPMENT, RETROTRANSPOSON SILENCING, GENOMIC IMPRINTING, AND X-CHROMOSOME INACTIVATION. CANCER CELLS DISPLAY HIGHLY DYSREGULATED DNA METHYLATION PROFILES CHARACTERIZED BY GLOBAL HYPOMETHYLATION IN CONJUNCTION WITH HYPERMETHYLATION OF PROMOTER CPG ISLANDS THAT PRESUMABLY LEAD TO GENOME INSTABILITY AND ABERRANT EXPRESSION OF TUMOR SUPPRESSOR GENES OR ONCOGENES. THE RECENT DISCOVERY OF TEN-ELEVEN-TRANSLOCATION (TET) FAMILY DIOXYGENASES THAT OXIDIZE 5MC TO 5-HYDROXYMETHYLCYTOSINE (5HMC), 5-FORMYLCYTOSINE (5FC), AND 5-CARBOXYLCYTOSINE (5CAC) IN DNA HAS LED TO PROFOUND PROGRESS IN UNDERSTANDING THE MECHANISM UNDERLYING DNA DEMETHYLATION. AMONG THE THREE TET GENES, TET2 RECURRENTLY UNDERGOES INACTIVATING MUTATIONS IN A WIDE RANGE OF MYELOID AND LYMPHOID MALIGNANCIES. TET2 FUNCTIONS AS A BONA FIDE TUMOR SUPPRESSOR PARTICULARLY IN THE PATHOGENESIS OF MYELOID MALIGNANCIES RESEMBLING CHRONIC MYELOMONOCYTIC LEUKEMIA (CMML) AND MYELODYSPLASTIC SYNDROMES (MDS) IN HUMAN. HERE WE REVIEW DIVERSE FUNCTIONS OF TET PROTEINS AND THE NOVEL EPIGENETIC MARKS THAT THEY GENERATE IN DNA METHYLATION/DEMETHYLATION DYNAMICS AND NORMAL AND MALIGNANT HEMATOPOIETIC DIFFERENTIATION. THE IMPACT OF TET2 INACTIVATION IN HEMATOPOIESIS AND VARIOUS MECHANISMS MODULATING THE EXPRESSION OR ACTIVITY OF TET PROTEINS ARE ALSO DISCUSSED. FURTHERMORE, WE ALSO PRESENT EVIDENCE THAT TET2 AND TET3 COLLABORATE TO SUPPRESS ABERRANT HEMATOPOIESIS AND HEMATOPOIETIC TRANSFORMATION. A DETAILED UNDERSTANDING OF THE NORMAL AND PATHOLOGICAL FUNCTIONS OF TET PROTEINS MAY PROVIDE NEW AVENUES TO DEVELOP NOVEL EPIGENETIC THERAPIES FOR TREATING HEMATOLOGICAL MALIGNANCIES. 2015 4 5965 30 TEN-ELEVEN-TRANSLOCATION 2 (TET2) NEGATIVELY REGULATES HOMEOSTASIS AND DIFFERENTIATION OF HEMATOPOIETIC STEM CELLS IN MICE. THE TEN-ELEVEN-TRANSLOCATION 2 (TET2) GENE ENCODES A MEMBER OF TET FAMILY ENZYMES THAT ALTERS THE EPIGENETIC STATUS OF DNA BY OXIDIZING 5-METHYLCYTOSINE TO 5-HYDROXYMETHYLCYTOSINE (5HMC). SOMATIC LOSS-OF-FUNCTION MUTATIONS OF TET2 ARE FREQUENTLY OBSERVED IN PATIENTS WITH DIVERSE MYELOID MALIGNANCIES, INCLUDING MYELODYSPLASTIC SYNDROMES, MYELOPROLIFERATIVE NEOPLASMS, AND CHRONIC MYELOMONOCYTIC LEUKEMIA. BY ANALYZING MICE WITH TARGETED DISRUPTION OF THE TET2 CATALYTIC DOMAIN, WE SHOW HERE THAT TET2 IS A CRITICAL REGULATOR OF SELF-RENEWAL AND DIFFERENTIATION OF HEMATOPOIETIC STEM CELLS (HSCS). TET2 DEFICIENCY LED TO DECREASED GENOMIC LEVELS OF 5HMC AND AUGMENTED THE SIZE OF THE HEMATOPOIETIC STEM/PROGENITOR CELL POOL IN A CELL-AUTONOMOUS MANNER. IN COMPETITIVE TRANSPLANTATION ASSAYS, TET2-DEFICIENT HSCS WERE CAPABLE OF MULTILINEAGE RECONSTITUTION AND POSSESSED A COMPETITIVE ADVANTAGE OVER WILD-TYPE HSCS, RESULTING IN ENHANCED HEMATOPOIESIS INTO BOTH LYMPHOID AND MYELOID LINEAGES. IN VITRO, TET2 DEFICIENCY DELAYED HSC DIFFERENTIATION AND SKEWED DEVELOPMENT TOWARD THE MONOCYTE/MACROPHAGE LINEAGE. OUR DATA INDICATE THAT TET2 HAS A CRITICAL ROLE IN REGULATING THE EXPANSION AND FUNCTION OF HSCS, PRESUMABLY BY CONTROLLING 5HMC LEVELS AT GENES IMPORTANT FOR THE SELF-RENEWAL, PROLIFERATION, AND DIFFERENTIATION OF HSCS. 2011 5 535 30 ASXL1 MUTATION CORRECTION BY CRISPR/CAS9 RESTORES GENE FUNCTION IN LEUKEMIA CELLS AND INCREASES SURVIVAL IN MOUSE XENOGRAFTS. RECURRENT SOMATIC MUTATIONS OF THE EPIGENETIC MODIFIER AND TUMOR SUPPRESSOR ASXL1 ARE COMMON IN MYELOID MALIGNANCIES, INCLUDING CHRONIC MYELOID LEUKEMIA (CML), AND ARE ASSOCIATED WITH POOR CLINICAL OUTCOME. CRISPR/CAS9 HAS RECENTLY EMERGED AS A POWERFUL AND VERSATILE GENOME EDITING TOOL FOR GENOME ENGINEERING IN VARIOUS SPECIES. WE HAVE USED THE CRISPR/CAS9 SYSTEM TO CORRECT THE ASXL1 HOMOZYGOUS NONSENSE MUTATION PRESENT IN THE CML CELL LINE KBM5, WHICH LACKS ASXL1 PROTEIN EXPRESSION. CRISPR/CAS9-MEDIATED ASXL1 HOMOZYGOUS CORRECTION RESULTED IN PROTEIN RE-EXPRESSION WITH RESTORED NORMAL FUNCTION, INCLUDING DOWN-REGULATION OF POLYCOMB REPRESSIVE COMPLEX 2 TARGET GENES. SIGNIFICANTLY REDUCED CELL GROWTH AND INCREASED MYELOID DIFFERENTIATION WERE OBSERVED IN ASXL1 MUTATION-CORRECTED CELLS, PROVIDING NEW INSIGHTS INTO THE ROLE OF ASXL1 IN HUMAN MYELOID CELL DIFFERENTIATION. MICE XENOGRAFTED WITH MUTATION-CORRECTED KBM5 CELLS SHOWED SIGNIFICANTLY LONGER SURVIVAL THAN UNCORRECTED XENOGRAFTS. THESE RESULTS SHOW THAT THE SOLE CORRECTION OF A DRIVER MUTATION IN LEUKEMIA CELLS INCREASES SURVIVAL IN VIVO IN MICE. THIS STUDY PROVIDES PROOF-OF-CONCEPT FOR DRIVER GENE MUTATION CORRECTION VIA CRISPR/CAS9 TECHNOLOGY IN HUMAN LEUKEMIA CELLS AND PRESENTS A STRATEGY TO ILLUMINATE THE IMPACT OF ONCOGENIC MUTATIONS ON CELLULAR FUNCTION AND SURVIVAL. 2015 6 151 29 ABERRANT METHYLATION AND IMPAIRED EXPRESSION OF THE P15(INK4B) CELL CYCLE REGULATORY GENE IN CHRONIC MYELOMONOCYTIC LEUKEMIA (CMML). THE IMPORTANT CELL CYCLE REGULATORY GENE P15(INK4B) HAS BEEN SHOWN TO BE INACTIVATED IN ACUTE MYELOID LEUKEMIA AND MYELODYSPLASTIC SYNDROME. LITTLE IS KNOWN ABOUT THE EXPRESSION AND EPIGENETIC MODIFICATION OF THIS GENE IN CHRONIC MYELOMONOCYTIC LEUKEMIA (CMML) THAT BELONGS TO THE MYELODYSPLASTIC/MYELOPROLIFERATIVE DISORDERS (MDS/MPD) WITH A HIGH PROPORTION OF BLASTIC TRANSFORMATION. ANALYSIS OF BONE MARROW TREPHINES IN A SERIES OF 33 CMML CASES SHOWED AN ABERRANT P15(INK4B) GENE METHYLATION IN UP TO 58% OF CASES. METHYLATION WAS ANALYZED EMPLOYING DIFFERENT METHYLATION-SPECIFIC PCR AND GENOMIC SEQUENCING PROTOCOLS. IT TURNED OUT TO BE SPREAD OVER A BROAD AREA OF THE 5' REGION AND EXHIBITED SUBSTANTIAL HETEROGENEITY BETWEEN CASES AND EVEN IN INDIVIDUAL PATIENTS. THE DEGREE OF ABERRANT METHYLATION WAS CORRELATED WITH A REDUCED MRNA AS WELL AS REDUCED PROTEIN EXPRESSION, AND WAS ASSOCIATED WITH A HIGHER EXPRESSION OF DNA METHYLTRANSFERASE DNMT 3A. WE CONCLUDE THAT ABERRANT GENE METHYLATION IS A FREQUENT EVENT IN CMML THAT MIGHT CONTRIBUTE TO THE PATHOGENESIS OF THIS MDS/MPD. 2003 7 2237 31 EPIGENETIC MODIFIERS IN MYELOID MALIGNANCIES: THE ROLE OF HISTONE DEACETYLASE INHIBITORS. MYELOID HEMATOLOGICAL MALIGNANCIES ARE CLONAL BONE MARROW NEOPLASMS, COMPRISING OF ACUTE MYELOID LEUKEMIA (AML), THE MYELODYSPLASTIC SYNDROMES (MDS), CHRONIC MYELOMONOCYTIC LEUKEMIA (CMML), THE MYELOPROLIFERATIVE NEOPLASMS (MPN) AND SYSTEMIC MASTOCYTOSIS (SM). THE FIELD OF EPIGENETIC REGULATION OF NORMAL AND MALIGNANT HEMATOPOIESIS IS RAPIDLY GROWING. IN RECENT YEARS, HETEROZYGOUS SOMATIC MUTATIONS IN GENES ENCODING EPIGENETIC REGULATORS HAVE BEEN FOUND IN ALL SUBTYPES OF MYELOID MALIGNANCIES, SUPPORTING THE RATIONALE FOR TREATMENT WITH EPIGENETIC MODIFIERS. HISTONE DEACETYLASE INHIBITORS (HDACI) ARE EPIGENETIC MODIFIERS THAT, IN VITRO, HAVE BEEN SHOWN TO INDUCE GROWTH ARREST, APOPTOTIC OR AUTOPHAGIC CELL DEATH, AND TERMINAL DIFFERENTIATION OF MYELOID TUMOR CELLS. THESE EFFECTS WERE OBSERVED BOTH AT THE BULK TUMOR LEVEL AND IN THE MOST IMMATURE CD34(+)38(-) CELL COMPARTMENTS CONTAINING THE LEUKEMIC STEM CELLS. THUS, THERE IS A STRONG RATIONALE SUPPORTING HDACI THERAPY IN MYELOID MALIGNANCIES. HOWEVER, DESPITE INITIAL PROMISING RESULTS IN PHASE I TRIALS, HDACI IN MONOTHERAPY AS WELL AS IN COMBINATION WITH OTHER DRUGS, HAVE FAILED TO IMPROVE RESPONSES OR SURVIVAL. THIS REVIEW PROVIDES AN OVERVIEW OF THE RATIONALE FOR HDACI IN MYELOID MALIGNANCIES, CLINICAL RESULTS AND SPECULATIONS ON WHY CLINICAL TRIALS HAVE THUS FAR NOT MET THE EXPECTATIONS, AND HOW THIS MAY BE IMPROVED IN THE FUTURE. 2018 8 4547 27 MUTATION ALLELE BURDEN REMAINS UNCHANGED IN CHRONIC MYELOMONOCYTIC LEUKAEMIA RESPONDING TO HYPOMETHYLATING AGENTS. THE CYTIDINE ANALOGUES AZACYTIDINE AND 5-AZA-2'-DEOXYCYTIDINE (DECITABINE) ARE COMMONLY USED TO TREAT MYELODYSPLASTIC SYNDROMES, WITH OR WITHOUT A MYELOPROLIFERATIVE COMPONENT. IT REMAINS UNCLEAR WHETHER THE RESPONSE TO THESE HYPOMETHYLATING AGENTS RESULTS FROM A CYTOTOXIC OR AN EPIGENETIC EFFECT. IN THIS STUDY, WE ADDRESS THIS QUESTION IN CHRONIC MYELOMONOCYTIC LEUKAEMIA. WE DESCRIBE A COMPREHENSIVE ANALYSIS OF THE MUTATIONAL LANDSCAPE OF THESE TUMOURS, COMBINING WHOLE-EXOME AND WHOLE-GENOME SEQUENCING. WE IDENTIFY AN AVERAGE OF 14+/-5 SOMATIC MUTATIONS IN CODING SEQUENCES OF SORTED MONOCYTE DNA AND THE SIGNATURES OF THREE MUTATIONAL PROCESSES. SERIAL SEQUENCING DEMONSTRATES THAT THE RESPONSE TO HYPOMETHYLATING AGENTS IS ASSOCIATED WITH CHANGES IN DNA METHYLATION AND GENE EXPRESSION, WITHOUT ANY DECREASE IN THE MUTATION ALLELE BURDEN, NOR PREVENTION OF NEW GENETIC ALTERATION OCCURENCE. OUR FINDINGS INDICATE THAT CYTOSINE ANALOGUES RESTORE A BALANCED HAEMATOPOIESIS WITHOUT DECREASING THE SIZE OF THE MUTATED CLONE, ARGUING FOR A PREDOMINANTLY EPIGENETIC EFFECT. 2016 9 1070 31 CLONAL ARCHITECTURE OF CHRONIC MYELOMONOCYTIC LEUKEMIAS. GENOMIC STUDIES IN CHRONIC MYELOID MALIGNANCIES, INCLUDING MYELOPROLIFERATIVE NEOPLASMS (MPN), MYELODYSPLASTIC SYNDROMES (MDS), AND MPN/MDS, HAVE IDENTIFIED COMMON MUTATIONS IN GENES ENCODING SIGNALING, EPIGENETIC, TRANSCRIPTION, AND SPLICING FACTORS. IN THE PRESENT STUDY, WE INTERROGATED THE CLONAL ARCHITECTURE BY MUTATION-SPECIFIC DISCRIMINATION ANALYSIS OF SINGLE-CELL-DERIVED COLONIES IN 28 PATIENTS WITH CHRONIC MYELOMONOCYTIC LEUKEMIAS (CMML), THE MOST FREQUENT MPN/MDS. THIS ANALYSIS REVEALS A LINEAR ACQUISITION OF THE STUDIED MUTATIONS WITH LIMITED BRANCHING THROUGH LOSS OF HETEROZYGOSITY. SERIAL ANALYSIS OF UNTREATED AND TREATED SAMPLES DEMONSTRATES A DYNAMIC ARCHITECTURE ON WHICH MOST CURRENT THERAPEUTIC APPROACHES HAVE LIMITED EFFECTS. THE MAIN DISEASE CHARACTERISTICS ARE EARLY CLONAL DOMINANCE, ARISING AT THE CD34(+)/CD38(-) STAGE OF HEMATOPOIESIS, AND GRANULOMONOCYTIC DIFFERENTIATION SKEWING OF MULTIPOTENT AND COMMON MYELOID PROGENITORS. COMPARISON OF CLONAL EXPANSIONS OF TET2 MUTATIONS IN MDS, MPN, AND CMML, TOGETHER WITH FUNCTIONAL INVALIDATION OF TET2 IN SORTED PROGENITORS, SUGGESTS A CAUSATIVE LINK BETWEEN EARLY CLONAL DOMINANCE AND SKEWED GRANULOMONOCYTIC DIFFERENTIATION. ALTOGETHER, EARLY CLONAL DOMINANCE MAY DISTINGUISH CMML FROM OTHER CHRONIC MYELOID NEOPLASMS WITH SIMILAR GENE MUTATIONS. 2013 10 1674 31 DRIVER MUTATIONS IN LEUKEMIA PROMOTE DISEASE PATHOGENESIS THROUGH A COMBINATION OF CELL-AUTONOMOUS AND NICHE MODULATION. STUDIES OF PATIENTS WITH ACUTE MYELOID LEUKEMIA (AML) HAVE LED TO THE IDENTIFICATION OF MUTATIONS THAT AFFECT DIFFERENT CELLULAR PATHWAYS. SOME OF THESE HAVE BEEN CLASSIFIED AS PRELEUKEMIC, AND A STEPWISE EVOLUTION PROGRAM WHEREBY CELLS ACQUIRE ADDITIONAL MUTATIONS HAS BEEN PROPOSED IN THE DEVELOPMENT OF AML. HOW THE TIMING OF ACQUISITION OF THESE MUTATIONS AND THEIR IMPACT ON TRANSFORMATION AND THE BONE MARROW (BM) MICROENVIRONMENT OCCURS HAS ONLY RECENTLY BEGUN TO BE INVESTIGATED. WE SHOW THAT CONSTITUTIVE AND EARLY LOSS OF THE EPIGENETIC REGULATOR, TET2, WHEN COMBINED WITH CONSTITUTIVE ACTIVATION OF FLT3, RESULTS IN TRANSFORMATION OF CHRONIC MYELOMONOCYTIC LEUKEMIA-LIKE OR MYELOPROLIFERATIVE NEOPLASM-LIKE PHENOTYPE TO AML, WHICH IS MORE PRONOUNCED IN DOUBLE-MUTANT MICE RELATIVE TO MICE CARRYING MUTATIONS IN SINGLE GENES. FURTHERMORE, WE SHOW THAT IN PRELEUKEMIC AND LEUKEMIC MICE THERE ARE ALTERATIONS IN THE BM NICHE AND SECRETED CYTOKINES, WHICH CREATES A PERMISSIVE ENVIRONMENT FOR THE GROWTH OF MUTATION-BEARING CELLS RELATIVE TO NORMAL CELLS. 2020 11 2582 29 EPIGENETICS OF MYELODYSPLASTIC SYNDROMES. MYELODYSPLASTIC SYNDROMES (MDS) ARE CLONAL DISEASES OF THE ELDERLY CHARACTERIZED BY CHRONIC CYTOPENIAS, DYSPLASIA AND A VARIABLE RISK OF PROGRESSION TO ACUTE MYELOID LEUKEMIA (AML). ABERRANT METHYLATION OF TUMOR-SUPPRESSOR GENE PROMOTERS HAS BEEN ESTABLISHED FOR MANY YEARS AND RECENTLY TRACKED TO THE MOST IMMATURE CELLS OF MDS, SUGGESTING THAT THESE ALTERATIONS ARE DRIVERS OF MDS PATHOGENESIS. IN RECENT YEARS, RECURRENT SOMATIC MUTATIONS IN GENES ENCODING PROTEINS INVOLVED IN DNA METHYLATION AND DEMETHYLATION AND IN COVALENT HISTONE MODIFICATIONS HAVE BEEN REPORTED IN MYELOID MALIGNANCIES, INCLUDING MDS. WHOLE-GENOME EPIGENETIC PROFILES OF MDS ARE ALSO EMERGING. IN PARALLEL WITH THESE ADVANCES IN THE MOLECULAR PATHOGENESIS OF MDS, CLINICAL TRIALS HAVE ESTABLISHED HYPOMETHYLATING AGENTS (HMAS) AS THE MAINSTAY OF THERAPY IN THE ADVANCED FORMS OF THE DISEASE. IN THIS REVIEW, WE SUMMARIZE THE CURRENT UNDERSTANDING OF THE MOLECULAR MACHINERY INVOLVED IN EPIGENETIC REGULATION, DISCUSS HOW EPIGENETIC ALTERATIONS ARISE IN MDS AND CONTRIBUTE TO ITS PATHOGENESIS AND THEN DISCUSS THE MODE OF ACTION OF HMAS IN MDS. 2014 12 2462 31 EPIGENETIC THERAPY OF MYELODYSPLASTIC SYNDROMES CONNECTS TO CELLULAR DIFFERENTIATION INDEPENDENTLY OF ENDOGENOUS RETROELEMENT DEREPRESSION. BACKGROUND: MYELODYSPLASTIC SYNDROMES (MDS) AND ACUTE MYELOID LEUKAEMIA (AML) ARE CHARACTERISED BY ABNORMAL EPIGENETIC REPRESSION AND DIFFERENTIATION OF BONE MARROW HAEMATOPOIETIC STEM CELLS (HSCS). DRUGS THAT REVERSE EPIGENETIC REPRESSION, SUCH AS 5-AZACYTIDINE (5-AZA), INDUCE HAEMATOLOGICAL IMPROVEMENT IN HALF OF TREATED PATIENTS. ALTHOUGH THE MECHANISMS UNDERLYING THERAPY SUCCESS ARE NOT YET CLEAR, INDUCTION OF ENDOGENOUS RETROELEMENTS (ERES) HAS BEEN HYPOTHESISED. METHODS: USING RNA SEQUENCING (RNA-SEQ), WE COMPARED THE TRANSCRIPTION OF ERES IN BONE MARROW HSCS FROM A NEW COHORT OF MDS AND CHRONIC MYELOMONOCYTIC LEUKAEMIA (CMML) PATIENTS BEFORE AND AFTER 5-AZA TREATMENT WITH HSCS FROM HEALTHY DONORS AND AML PATIENTS. WE FURTHER EXAMINED ERE TRANSCRIPTION USING THE MOST COMPREHENSIVE ANNOTATION OF ERE-OVERLAPPING TRANSCRIPTS EXPRESSED IN HSCS, GENERATED HERE BY DE NOVO TRANSCRIPT ASSEMBLY AND SUPPORTED BY FULL-LENGTH RNA-SEQ. RESULTS: CONSISTENT WITH PRIOR REPORTS, WE FOUND THAT TREATMENT WITH 5-AZA INCREASED THE REPRESENTATION OF ERE-DERIVED RNA-SEQ READS IN THE TRANSCRIPTOME. HOWEVER, SUCH INCREASES WERE COMPARABLE BETWEEN TREATMENT RESPONSES AND FAILURES. THE EXTENDED VIEW OF HSC TRANSCRIPTIONAL DIVERSITY OFFERED BY DE NOVO TRANSCRIPT ASSEMBLY ARGUED AGAINST 5-AZA-RESPONSIVE ERES AS DETERMINANTS OF THE OUTCOME OF THERAPY. INSTEAD, IT UNCOVERED PRE-TREATMENT EXPRESSION AND ALTERNATIVE SPLICING OF DEVELOPMENTALLY REGULATED GENE TRANSCRIPTS AS PREDICTORS OF THE RESPONSE OF MDS AND CMML PATIENTS TO 5-AZA TREATMENT. CONCLUSIONS: OUR STUDY IDENTIFIES THE DEVELOPMENTALLY REGULATED TRANSCRIPTIONAL SIGNATURES OF PROTEIN-CODING AND NON-CODING GENES, RATHER THAN ERES, AS CORRELATES OF A FAVOURABLE RESPONSE OF MDS AND CMML PATIENTS TO 5-AZA TREATMENT AND OFFERS NOVEL CANDIDATES FOR FURTHER EVALUATION. 2019 13 1039 31 CLINICAL AND BIOLOGICAL IMPLICATIONS OF DRIVER MUTATIONS IN MYELODYSPLASTIC SYNDROMES. MYELODYSPLASTIC SYNDROMES (MDS) ARE A HETEROGENEOUS GROUP OF CHRONIC HEMATOLOGICAL MALIGNANCIES CHARACTERIZED BY DYSPLASIA, INEFFECTIVE HEMATOPOIESIS AND A VARIABLE RISK OF PROGRESSION TO ACUTE MYELOID LEUKEMIA. SEQUENCING OF MDS GENOMES HAS IDENTIFIED MUTATIONS IN GENES IMPLICATED IN RNA SPLICING, DNA MODIFICATION, CHROMATIN REGULATION, AND CELL SIGNALING. WE SEQUENCED 111 GENES ACROSS 738 PATIENTS WITH MDS OR CLOSELY RELATED NEOPLASMS (INCLUDING CHRONIC MYELOMONOCYTIC LEUKEMIA AND MDS-MYELOPROLIFERATIVE NEOPLASMS) TO EXPLORE THE ROLE OF ACQUIRED MUTATIONS IN MDS BIOLOGY AND CLINICAL PHENOTYPE. SEVENTY-EIGHT PERCENT OF PATIENTS HAD 1 OR MORE ONCOGENIC MUTATIONS. WE IDENTIFY COMPLEX PATTERNS OF PAIRWISE ASSOCIATION BETWEEN GENES, INDICATIVE OF EPISTATIC INTERACTIONS INVOLVING COMPONENTS OF THE SPLICEOSOME MACHINERY AND EPIGENETIC MODIFIERS. COUPLED WITH INFERENCES ON SUBCLONAL MUTATIONS, THESE DATA SUGGEST A HYPOTHESIS OF GENETIC "PREDESTINATION," IN WHICH EARLY DRIVER MUTATIONS, TYPICALLY AFFECTING GENES INVOLVED IN RNA SPLICING, DICTATE FUTURE TRAJECTORIES OF DISEASE EVOLUTION WITH DISTINCT CLINICAL PHENOTYPES. DRIVER MUTATIONS HAD EQUIVALENT PROGNOSTIC SIGNIFICANCE, WHETHER CLONAL OR SUBCLONAL, AND LEUKEMIA-FREE SURVIVAL DETERIORATED STEADILY AS NUMBERS OF DRIVER MUTATIONS INCREASED. THUS, ANALYSIS OF ONCOGENIC MUTATIONS IN LARGE, WELL-CHARACTERIZED COHORTS OF PATIENTS ILLUSTRATES THE INTERCONNECTIONS BETWEEN THE CANCER GENOME AND DISEASE BIOLOGY, WITH CONSIDERABLE POTENTIAL FOR CLINICAL APPLICATION. 2013 14 4530 33 MULTILAYER INTRACLONAL HETEROGENEITY IN CHRONIC MYELOMONOCYTIC LEUKEMIA. THE FUNCTIONAL DIVERSITY OF CELLS THAT COMPOSE MYELOID MALIGNANCIES, I.E., THE RESPECTIVE ROLES OF GENETIC AND EPIGENETIC HETEROGENEITY IN THIS DIVERSITY, REMAINS POORLY UNDERSTOOD. THIS QUESTION IS ADDRESSED IN CHRONIC MYELOMONOCYTIC LEUKEMIA, A MYELOID NEOPLASM IN WHICH CLINICAL DIVERSITY CONTRASTS WITH LIMITED GENETIC HETEROGENEITY. TO GENERATE INDUCED PLURIPOTENT STEM CELL CLONES, WE REPROGRAMMED CD34(+) CELLS COLLECTED FROM A PATIENT WITH A CHRONIC MYELOMONOCYTIC LEUKEMIA IN WHICH WHOLE EXOME SEQUENCING OF PERIPHERAL BLOOD MONOCYTE DNA HAD IDENTIFIED 12 GENE MUTATIONS, INCLUDING A MUTATION IN KDM6A AND TWO HETEROZYGOUS MUTATIONS IN TET2 IN THE FOUNDING CLONE AND A SECONDARY KRAS(G12D) MUTATION. CD34(+) CELLS FROM AN AGE-MATCHED HEALTHY DONOR WERE ALSO REPROGRAMMED. WE CAPTURED A PART OF THE GENETIC HETEROGENEITY OBSERVED IN THE PATIENT, I.E. WE ANALYZED FIVE CLONES WITH TWO GENETIC BACKGROUNDS, WITHOUT AND WITH THE KRAS(G12D) MUTATION. HEMATOPOIETIC DIFFERENTIATION OF THESE CLONES RECAPITULATED THE MAIN FEATURES OF THE PATIENT'S DISEASE, INCLUDING OVERPRODUCTION OF GRANULOMONOCYTES AND DYSMEGAKARYOPOIESIS. THESE ANALYSES ALSO DISCLOSED SIGNIFICANT DISCREPANCIES IN THE BEHAVIOR OF HEMATOPOIETIC CELLS DERIVED FROM INDUCED PLURIPOTENT STEM CELL CLONES WITH SIMILAR GENETIC BACKGROUND, CORRELATING WITH LIMITED EPIGENETIC CHANGES. THESE ANALYSES SUGGEST THAT, BEYOND THE CODING MUTATIONS, SEVERAL LEVELS OF INTRACLONAL HETEROGENEITY MAY PARTICIPATE IN THE YET UNEXPLAINED CLINICAL HETEROGENEITY OF THE DISEASE. 2020 15 2781 32 EZH2 IN MYELOID MALIGNANCIES. OUR UNDERSTANDING OF THE SIGNIFICANCE OF EPIGENETIC DYSREGULATION IN THE PATHOGENESIS OF MYELOID MALIGNANCIES HAS GREATLY ADVANCED IN THE PAST DECADE. ENHANCER OF ZESTE HOMOLOG 2 (EZH2) IS THE CATALYTIC CORE COMPONENT OF THE POLYCOMB REPRESSIVE COMPLEX 2 (PRC2), WHICH IS RESPONSIBLE FOR GENE SILENCING THROUGH TRIMETHYLATION OF H3K27. EZH2 DYSREGULATION IS HIGHLY TUMORIGENIC AND HAS BEEN OBSERVED IN VARIOUS CANCERS, WITH EZH2 ACTING AS AN ONCOGENE OR A TUMOR-SUPPRESSOR DEPENDING ON CELLULAR CONTEXT. WHILE LOSS-OF-FUNCTION MUTATIONS OF EZH2 FREQUENTLY AFFECT PATIENTS WITH MYELODYSPLASTIC/MYELOPROLIFERATIVE NEOPLASMS, MYELODYSPLASTIC SYNDROME AND MYELOFIBROSIS, CASES OF CHRONIC MYELOID LEUKEMIA (CML) SEEM TO BE LARGELY CHARACTERIZED BY EZH2 OVEREXPRESSION. A VARIETY OF OTHER FACTORS FREQUENTLY ABERRANT IN MYELOID LEUKEMIA CAN AFFECT PRC2 FUNCTION AND DISEASE PATHOGENESIS, INCLUDING ADDITIONAL SEX COMBS LIKE 1 (ASXL1) AND SPLICING GENE MUTATIONS. AS THE GENETIC BACKGROUND OF MYELOID MALIGNANCIES IS LARGELY HETEROGENEOUS, IT IS NOT SURPRISING THAT EZH2 MUTATIONS ACT IN CONJUNCTION WITH OTHER ABERRATIONS. SINCE EZH2 MUTATIONS ARE CONSIDERED TO BE EARLY EVENTS IN DISEASE PATHOGENESIS, THEY ARE OF THERAPEUTIC INTEREST TO RESEARCHERS, THOUGH TARGETING OF EZH2 LOSS-OF-FUNCTION DOES PRESENT UNIQUE CHALLENGES. PRELIMINARY RESEARCH INDICATES THAT COMBINED TYROSINE KINASE INHIBITOR (TKI) AND EZH2 INHIBITOR THERAPY MAY PROVIDE A STRATEGY TO ELIMINATE THE RESIDUAL DISEASE BURDEN IN CML TO ALLOW PATIENTS TO REMAIN IN TREATMENT-FREE REMISSION. 2020 16 825 27 CHARACTERIZATION OF FUNCTIONAL TRANSPOSABLE ELEMENT ENHANCERS IN ACUTE MYELOID LEUKEMIA. TRANSPOSABLE ELEMENTS (TES) HAVE BEEN SHOWN TO HAVE IMPORTANT GENE REGULATORY FUNCTIONS AND THEIR ALTERATION COULD LEAD TO DISEASE PHENOTYPES. ACUTE MYELOID LEUKEMIA (AML) DEVELOPS AS A CONSEQUENCE OF A SERIES OF GENETIC CHANGES IN HEMATOPOIETIC PRECURSOR CELLS, INCLUDING MUTATIONS IN EPIGENETIC FACTORS. HERE, WE SET OUT TO STUDY THE GENE REGULATORY ROLE OF TES IN AML. WE FIRST EXPLORED THE EPIGENETIC LANDSCAPE OF TES IN AML PATIENTS USING ATAC-SEQ DATA. WE SHOW THAT A LARGE NUMBER OF TES IN GENERAL, AND MORE SPECIFICALLY MAMMALIAN-WIDE INTERSPERSED REPEATS (MIRS), ARE MORE ENRICHED IN AML CELLS THAN IN NORMAL BLOOD CELLS. WE OBTAINED A SIMILAR FINDING WHEN ANALYZING HISTONE MODIFICATION DATA IN AML PATIENTS. GENE ONTOLOGY ENRICHMENT ANALYSIS SHOWED THAT GENES NEAR MIRS IN OPEN CHROMATIN REGIONS ARE INVOLVED IN LEUKEMOGENESIS. TO FUNCTIONALLY VALIDATE THEIR REGULATORY ROLE, WE SELECTED 19 MIR REGIONS IN AML CELLS, AND TESTED THEM FOR ENHANCER ACTIVITY IN AN AML CELL LINE (KASUMI-1) AND A CHRONIC MYELOID LEUKEMIA (CML) CELL LINE (K562); THE RESULTS REVEALED SEVERAL MIRS TO BE FUNCTIONAL ENHANCERS. TAKEN TOGETHER, OUR RESULTS SUGGEST THAT TES ARE POTENTIALLY INVOLVED IN MYELOID LEUKEMOGENESIS AND HIGHLIGHT THESE SEQUENCES AS POTENTIAL CANDIDATES HARBORING AML-ASSOCIATED VARIATION. 2020 17 5985 41 TET2-MEDIATED CLONAL HEMATOPOIESIS ACCELERATES HEART FAILURE THROUGH A MECHANISM INVOLVING THE IL-1BETA/NLRP3 INFLAMMASOME. BACKGROUND: RECENT STUDIES HAVE SHOWN THAT HEMATOPOIETIC STEM CELLS CAN UNDERGO CLONAL EXPANSION SECONDARY TO SOMATIC MUTATIONS IN LEUKEMIA-RELATED GENES, THUS LEADING TO AN AGE-DEPENDENT ACCUMULATION OF MUTANT LEUKOCYTES IN THE BLOOD. THIS SOMATIC MUTATION-RELATED CLONAL HEMATOPOIESIS IS COMMON IN HEALTHY OLDER INDIVIDUALS, BUT IT HAS BEEN ASSOCIATED WITH AN INCREASED INCIDENCE OF FUTURE CARDIOVASCULAR DISEASE. THE EPIGENETIC REGULATOR TET2 IS FREQUENTLY MUTATED IN BLOOD CELLS OF INDIVIDUALS EXHIBITING CLONAL HEMATOPOIESIS. OBJECTIVES: THIS STUDY INVESTIGATED WHETHER TET2 MUTATIONS WITHIN HEMATOPOIETIC CELLS CAN CONTRIBUTE TO HEART FAILURE IN 2 MODELS OF CARDIAC INJURY. METHODS: HEART FAILURE WAS INDUCED IN MICE BY PRESSURE OVERLOAD, ACHIEVED BY TRANSVERSE AORTIC CONSTRICTION OR CHRONIC ISCHEMIA INDUCED BY THE PERMANENT LIGATION OF THE LEFT ANTERIOR DESCENDING ARTERY. COMPETITIVE BONE MARROW TRANSPLANTATION STRATEGIES WITH TET2-DEFICIENT CELLS WERE USED TO MIMIC TET2 MUTATION-DRIVEN CLONAL HEMATOPOIESIS. ALTERNATIVELY, TET2 WAS SPECIFICALLY ABLATED IN MYELOID CELLS USING CRE RECOMBINASE EXPRESSED FROM THE LYSM PROMOTER. RESULTS: IN BOTH EXPERIMENTAL HEART FAILURE MODELS, HEMATOPOIETIC OR MYELOID TET2 DEFICIENCY WORSENED CARDIAC REMODELING AND FUNCTION, IN PARALLEL WITH INCREASED INTERLEUKIN-1BETA (IL-1BETA) EXPRESSION. TREATMENT WITH A SELECTIVE NLRP3 INFLAMMASOME INHIBITOR PROTECTED AGAINST THE DEVELOPMENT OF HEART FAILURE AND ELIMINATED THE DIFFERENCES IN CARDIAC PARAMETERS BETWEEN TET2-DEFICIENT AND WILD-TYPE MICE. CONCLUSIONS: TET2 DEFICIENCY IN HEMATOPOIETIC CELLS IS ASSOCIATED WITH GREATER CARDIAC DYSFUNCTION IN MURINE MODELS OF HEART FAILURE AS A RESULT OF ELEVATED IL-1BETA SIGNALING. THESE DATA SUGGEST THAT INDIVIDUALS WITH TET2-MEDIATED CLONAL HEMATOPOIESIS MAY BE AT GREATER RISK OF DEVELOPING HEART FAILURE AND RESPOND BETTER TO IL-1BETA-NLRP3 INFLAMMASOME INHIBITION. 2018 18 18 28 5-AZACYTIDINE MODULATES CPG METHYLATION LEVELS OF EZH2 AND NOTCH1 IN MYELODYSPLASTIC SYNDROMES. PURPOSE: MOLECULAR MECHANISMS OF RESPONSE TO HYPOMETHYLATING AGENTS IN PATIENTS WITH MYELODYSPLASTIC SYNDROMES (MDS) AND CHRONIC MYELOMONOCYTIC LEUKEMIA (CMML) STILL REMAIN LARGELY UNKNOWN. THEREFORE, THE EFFECTS OF 5-AZACYTIDINE (AZA) ON CLONAL ARCHITECTURE AND DNA METHYLATION WERE INVESTIGATED IN THIS STUDY. METHODS: USING NEXT-GENERATION SEQUENCING (NGS), 30 MYELOID LEUKEMIA-ASSOCIATED GENES WERE ANALYZED IN 15 MDS/CMML PATIENTS WITH EXCELLENT RESPONSE TO AZA. EFFECTS ON METHYLATION LEVELS WERE ANALYZED BY QUANTITATIVE METHYLATION ANALYSIS USING PYROSEQUENCING FOR THE GLOBAL METHYLATION MARKER LINE-1 IN PATIENTS AND MYELOID CELL LINES. VARIOUS MYELOID CELL LINES AND A HEALTHY COHORT WERE SCREENED FOR METHYLATION LEVELS IN 23 GENES. SELECTED TARGETS WERE VERIFIED ON THE MDS/CMML COHORT. RESULTS: THE STUDY PRESENTED HERE SHOWED A STABLE VARIANT ALLELE FREQUENCY AND STABLE GLOBAL METHYLATION LEVELS IN RESPONDING PATIENTS. A SIGNIFICANT DEMETHYLATION OF EZH2 AND NOTCH1 WAS REVEALED IN PATIENTS WITH AZA RESPONSE. CONCLUSIONS: A RESPONSE TO AZA IS NOT ASSOCIATED WITH ERADICATION OF MALIGNANT CLONES, BUT RATHER WITH A STABILIZATION OF THE CLONAL ARCHITECTURE. WE SUGGEST CHANGES IN CPG METHYLATION LEVELS OF EZH2 AND NOTCH1 AS POTENTIAL TARGETS OF EPIGENETIC RESPONSE TO AZA TREATMENT WHICH MAY ALSO SERVE AS USEFUL BIOMARKERS AFTER CLINICAL EVALUATION. 2019 19 2277 30 EPIGENETIC REGULATION BY ASXL1 IN MYELOID MALIGNANCIES. MYELOID MALIGNANCIES ARE CLONAL HEMATOPOIETIC DISORDERS THAT ARE COMPRISED OF A SPECTRUM OF GENETICALLY HETEROGENEOUS DISORDERS, INCLUDING MYELODYSPLASTIC SYNDROMES (MDS), MYELOPROLIFERATIVE NEOPLASMS (MPN), CHRONIC MYELOMONOCYTIC LEUKEMIA (CMML), AND ACUTE MYELOID LEUKEMIA (AML). MYELOID MALIGNANCIES ARE CHARACTERIZED BY EXCESSIVE PROLIFERATION, ABNORMAL SELF-RENEWAL, AND/OR DIFFERENTIATION DEFECTS OF HEMATOPOIETIC STEM CELLS (HSCS) AND MYELOID PROGENITOR CELLS HEMATOPOIETIC STEM/PROGENITOR CELLS (HSPCS). MYELOID MALIGNANCIES CAN BE CAUSED BY GENETIC AND EPIGENETIC ALTERATIONS THAT PROVOKE KEY CELLULAR FUNCTIONS, SUCH AS SELF-RENEWAL, PROLIFERATION, BIASED LINEAGE COMMITMENT, AND DIFFERENTIATION. ADVANCES IN NEXT-GENERATION SEQUENCING LED TO THE IDENTIFICATION OF MULTIPLE MUTATIONS IN MYELOID NEOPLASMS, AND MANY NEW GENE MUTATIONS WERE IDENTIFIED AS KEY FACTORS IN DRIVING THE PATHOGENESIS OF MYELOID MALIGNANCIES. THE POLYCOMB PROTEIN ASXL1 WAS IDENTIFIED TO BE FREQUENTLY MUTATED IN ALL FORMS OF MYELOID MALIGNANCIES, WITH MUTATIONAL FREQUENCIES OF 20%, 43%, 10%, AND 20% IN MDS, CMML, MPN, AND AML, RESPECTIVELY. SIGNIFICANTLY, ASXL1 MUTATIONS ARE ASSOCIATED WITH A POOR PROGNOSIS IN ALL FORMS OF MYELOID MALIGNANCIES. THE FACT THAT ASXL1 MUTATIONS ARE ASSOCIATED WITH POOR PROGNOSIS IN PATIENTS WITH CMML, MDS, AND AML, POINTS TO THE POSSIBILITY THAT ASXL1 MUTATION IS A KEY FACTOR IN THE DEVELOPMENT OF MYELOID MALIGNANCIES. THIS REVIEW SUMMARIZES THE RECENT ADVANCES IN UNDERSTANDING MYELOID MALIGNANCIES WITH A SPECIFIC FOCUS ON ASXL1 MUTATIONS. 2023 20 2911 26 GENE EXPRESSION PROFILING OF LOSS OF TET2 AND/OR JAK2V617F MUTANT HEMATOPOIETIC STEM CELLS FROM MOUSE MODELS OF MYELOPROLIFERATIVE NEOPLASMS. MYELOPROLIFERATIVE NEOPLASMS (MPNS) ARE CLINICALLY CHARACTERIZED BY THE CHRONIC OVERPRODUCTION OF DIFFERENTIATED PERIPHERAL BLOOD CELLS AND THE GRADUAL EXPANSION OF MALIGNANT INTRAMEDULLARY/EXTRAMEDULLARY HEMATOPOIESIS. IN MPNS MUTATIONS IN JAK2 MPL OR CALR ARE DETECTED MUTUALLY EXCLUSIVE IN MORE THAN 90% OF CASES [1,2]. MUTATIONS IN THEM LEAD TO THE ABNORMAL ACTIVATION OF JAK/STAT SIGNALING AND THE AUTONOMOUS GROWTH OF DIFFERENTIATED CELLS THEREFORE THEY ARE CONSIDERED AS "DRIVER" GENE MUTATIONS. IN ADDITION TO THE ABOVE DRIVER GENE MUTATIONS MUTATIONS IN EPIGENETIC REGULATORS SUCH AS TET2 DNMT3A ASXL1 EZH2 OR IDH1/2 ARE DETECTED IN ABOUT 5%-30% OF CASES RESPECTIVELY [3]. MUTATIONS IN TET2 DNMT3A EZH2 OR IDH1/2 COMMONLY CONFER THE INCREASED SELF-RENEWAL CAPACITY ON NORMAL HEMATOPOIETIC STEM CELLS (HSCS) BUT THEY DO NOT LEAD TO THE AUTONOMOUS GROWTH OF DIFFERENTIATED CELLS AND ONLY EXHIBIT SUBTLE CLINICAL PHENOTYPES [4,6-8,5]. IT WAS UNCLEAR HOW MUTATIONS IN SUCH EPIGENETIC REGULATORS INFLUENCED ABNORMAL HSCS WITH DRIVER GENE MUTATIONS HOW THEY INFLUENCED THE DISEASE PHENOTYPE OR WHETHER A SINGLE DRIVER GENE MUTATION WAS SUFFICIENT FOR THE INITIATION OF HUMAN MPNS. THEREFORE WE FOCUSED ON JAK2V617F AND LOSS OF TET2-THE FORMER AS A REPRESENTATIVE OF DRIVER GENE MUTATIONS AND THE LATTER AS A REPRESENTATIVE OF MUTATIONS IN EPIGENETIC REGULATORS-AND EXAMINED THE INFLUENCE OF SINGLE OR DOUBLE MUTATIONS ON HSCS (LINEAGE(-)SCA-1(+)C-KIT(+) CELLS (LSKS)) BY FUNCTIONAL ANALYSES AND MICROARRAY WHOLE-GENOME EXPRESSION ANALYSES [9]. GENE EXPRESSION PROFILING SHOWED THAT THE HSC FINGERPRINT GENES [10] WAS STATISTICALLY EQUALLY ENRICHED IN TET2-KNOCKDOWN-LSKS BUT NEGATIVELY ENRICHED IN JAK2V617F-LSKS COMPARED TO THAT IN WILD-TYPE-LSKS. DOUBLE-MUTANT-LSKS SHOWED THE SAME TENDENCY AS JAK2V617F-LSKS IN TERMS OF THEIR HSC FINGERPRINT GENES BUT THE EXPRESSION OF INDIVIDUAL GENES DIFFERED BETWEEN THE TWO GROUPS. AMONG 245 HSC FINGERPRINT GENES 100 WERE MORE HIGHLY EXPRESSED IN DOUBLE-MUTANT-LSKS THAN IN JAK2V617F-LSKS. THESE ALTERED GENE EXPRESSIONS MIGHT PARTLY EXPLAIN THE MECHANISMS OF INITIATION AND PROGRESSION OF MPNS WHICH WAS OBSERVED IN THE FUNCTIONAL ANALYSES [9]. HERE WE DESCRIBE GENE EXPRESSION PROFILES DEPOSITED AT THE GENE EXPRESSION OMNIBUS (GEO) UNDER THE ACCESSION NUMBER GSE62302 INCLUDING EXPERIMENTAL METHODS AND QUALITY CONTROL ANALYSES. 2015