1 4748 153 NOVEL MUTATIONS AND THEIR FUNCTIONAL AND CLINICAL RELEVANCE IN MYELOPROLIFERATIVE NEOPLASMS: JAK2, MPL, TET2, ASXL1, CBL, IDH AND IKZF1. MYELOPROLIFERATIVE NEOPLASMS (MPNS) ORIGINATE FROM GENETICALLY TRANSFORMED HEMATOPOIETIC STEM CELLS THAT RETAIN THE CAPACITY FOR MULTILINEAGE DIFFERENTIATION AND EFFECTIVE MYELOPOIESIS. BEGINNING IN EARLY 2005, A NUMBER OF NOVEL MUTATIONS INVOLVING JANUS KINASE 2 (JAK2), MYELOPROLIFERATIVE LEUKEMIA VIRUS (MPL), TET ONCOGENE FAMILY MEMBER 2 (TET2), ADDITIONAL SEX COMBS-LIKE 1 (ASXL1), CASITAS B-LINEAGE LYMPHOMA PROTO-ONCOGENE (CBL), ISOCITRATE DEHYDROGENASE (IDH) AND IKAROS FAMILY ZINC FINGER 1 (IKZF1) HAVE BEEN DESCRIBED IN BCR-ABL1-NEGATIVE MPNS. HOWEVER, NONE OF THESE MUTATIONS WERE MPN SPECIFIC, DISPLAYED MUTUAL EXCLUSIVITY OR COULD BE TRACED BACK TO A COMMON ANCESTRAL CLONE. JAK2 AND MPL MUTATIONS APPEAR TO EXERT A PHENOTYPE-MODIFYING EFFECT AND ARE DISTINCTLY ASSOCIATED WITH POLYCYTHEMIA VERA, ESSENTIAL THROMBOCYTHEMIA AND PRIMARY MYELOFIBROSIS; THE CORRESPONDING MUTATIONAL FREQUENCIES ARE APPROXIMATELY 99, 55 AND 65% FOR JAK2 AND 0, 3 AND 10% FOR MPL MUTATIONS. THE INCIDENCE OF TET2, ASXL1, CBL, IDH OR IKZF1 MUTATIONS IN THESE DISORDERS RANGES FROM 0 TO 17%; THESE LATTER MUTATIONS ARE MORE COMMON IN CHRONIC (TET2, ASXL1, CBL) OR JUVENILE (CBL) MYELOMONOCYTIC LEUKEMIAS, MASTOCYTOSIS (TET2), MYELODYSPLASTIC SYNDROMES (TET2, ASXL1) AND SECONDARY ACUTE MYELOID LEUKEMIA, INCLUDING BLAST-PHASE MPN (IDH, ASXL1, IKZF1). THE FUNCTIONAL CONSEQUENCES OF MPN-ASSOCIATED MUTATIONS INCLUDE UNREGULATED JAK-STAT (JANUS KINASE/SIGNAL TRANSDUCER AND ACTIVATOR OF TRANSCRIPTION) SIGNALING, EPIGENETIC MODULATION OF TRANSCRIPTION AND ABNORMAL ACCUMULATION OF ONCOPROTEINS. HOWEVER, IT IS NOT CLEAR AS TO WHETHER AND HOW THESE ABNORMALITIES CONTRIBUTE TO DISEASE INITIATION, CLONAL EVOLUTION OR BLASTIC TRANSFORMATION. 2010 2 3521 35 IKAROS: FROM CHROMATIN ORGANIZATION TO TRANSCRIPTIONAL ELONGATION CONTROL. IKAROS IS A MASTER REGULATOR OF CELL FATE DETERMINATION IN LYMPHOID AND OTHER HEMATOPOIETIC CELLS. THIS TRANSCRIPTION FACTOR ORCHESTRATES THE ASSOCIATION OF EPIGENETIC REGULATORS WITH CHROMATIN, ENSURING THE EXPRESSION PATTERN OF TARGET GENES IN A DEVELOPMENTAL AND LINEAGE-SPECIFIC MANNER. DISRUPTION OF IKAROS FUNCTION HAS BEEN ASSOCIATED WITH THE DEVELOPMENT OF ACUTE LYMPHOCYTIC LEUKEMIA, LYMPHOMA, CHRONIC MYELOID LEUKEMIA AND IMMUNE DISORDERS. PARADOXICALLY, WHILE IKAROS HAS BEEN SHOWN TO BE A TUMOR SUPPRESSOR, IT HAS ALSO BEEN IDENTIFIED AS A KEY THERAPEUTIC TARGET IN THE TREATMENT OF VARIOUS FORMS OF HEMATOLOGICAL MALIGNANCIES, INCLUDING MULTIPLE MYELOMA. INDEED, TARGETED PROTEOLYSIS OF IKAROS IS ASSOCIATED WITH DECREASED PROLIFERATION AND INCREASED DEATH OF MALIGNANT CELLS. ALTHOUGH THE MOLECULAR MECHANISMS HAVE NOT BEEN ELUCIDATED, THE EXPRESSION LEVELS OF IKAROS ARE VARIABLE DURING HEMATOPOIESIS AND COULD THEREFORE BE A KEY DETERMINANT IN EXPLAINING HOW ITS ABSENCE CAN HAVE SEEMINGLY OPPOSITE EFFECTS. MECHANISTICALLY, IKAROS COLLABORATES WITH A VARIETY OF PROTEINS AND COMPLEXES CONTROLLING CHROMATIN ORGANIZATION AT GENE REGULATORY REGIONS, INCLUDING THE NUCLEOSOME REMODELING AND DEACETYLASE COMPLEX, AND MAY FACILITATE TRANSCRIPTIONAL REPRESSION OR ACTIVATION OF SPECIFIC GENES. SEVERAL TRANSCRIPTIONAL REGULATORY FUNCTIONS OF IKAROS HAVE BEEN PROPOSED. AN EMERGING MECHANISM OF ACTION INVOLVES THE ABILITY OF IKAROS TO PROMOTE GENE REPRESSION OR ACTIVATION THROUGH ITS INTERACTION WITH THE RNA POLYMERASE II MACHINERY, WHICH INFLUENCES PAUSING AND PRODUCTIVE TRANSCRIPTION AT SPECIFIC GENES. THIS CONTROL APPEARS TO BE INFLUENCED BY IKAROS EXPRESSION LEVELS AND ISOFORM PRODUCTION. IN HERE, WE SUMMARIZE THE CURRENT STATE OF KNOWLEDGE ABOUT THE BIOLOGICAL ROLES AND MECHANISMS BY WHICH IKAROS REGULATES GENE EXPRESSION. WE HIGHLIGHT THE DYNAMIC REGULATION OF THIS FACTOR BY POST-TRANSLATIONAL MODIFICATIONS. FINALLY, POTENTIAL AVENUES TO EXPLAIN HOW IKAROS DESTRUCTION MAY BE FAVORABLE IN THE TREATMENT OF CERTAIN HEMATOLOGICAL MALIGNANCIES ARE ALSO EXPLORED. 2023 3 3998 21 LOSS OF EPIGENETIC MODIFICATION DRIVEN BY THE FOXP3 TRANSCRIPTION FACTOR LEADS TO REGULATORY T CELL INSUFFICIENCY. REGULATORY T (TREG) CELLS, DRIVEN BY THE FOXP3 TRANSCRIPTION FACTOR, ARE RESPONSIBLE FOR LIMITING AUTOIMMUNITY AND CHRONIC INFLAMMATION. WE SHOWED THAT A WELL-CHARACTERIZED FOXP3(GFP) REPORTER MOUSE, WHICH EXPRESSES AN N-TERMINAL GFP-FOXP3 FUSION PROTEIN, IS A HYPOMORPH THAT CAUSES PROFOUNDLY ACCELERATED AUTOIMMUNE DIABETES ON A NOD BACKGROUND. ALTHOUGH NATURAL TREG CELL DEVELOPMENT AND IN VITRO FUNCTION ARE NOT MARKEDLY ALTERED IN FOXP3(GFP) NOD AND C57BL/6 MICE, TREG CELL FUNCTION IN INFLAMMATORY ENVIRONMENTS WAS PERTURBED AND TGF-BETA-INDUCED TREG CELL DEVELOPMENT WAS REDUCED. FOXP3(GFP) WAS UNABLE TO INTERACT WITH THE HISTONE ACETYLTRANSFERASE TIP60, THE HISTONE DEACETYLASE HDAC7, AND THE IKAROS FAMILY ZINC FINGER 4, EOS, WHICH LED TO REDUCED FOXP3 ACETYLATION AND ENHANCED K48-LINKED POLYUBIQUITYLATION. COLLECTIVELY THIS RESULTS IN AN ALTERED TRANSCRIPTIONAL LANDSCAPE AND REDUCED FOXP3-MEDIATED GENE REPRESSION, NOTABLY AT THE HALLMARK IL-2 PROMOTER. LOSS OF CONTROLLED FOXP3-DRIVEN EPIGENETIC MODIFICATION LEADS TO TREG CELL INSUFFICIENCY THAT ENABLES AUTOIMMUNITY IN SUSCEPTIBLE ENVIRONMENTS. 2012 4 5965 36 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 3373 24 HISTONE MODULATION BLOCKS TREG-INDUCED FOXP3 BINDING TO THE IL-2 PROMOTER OF VIRUS-SPECIFIC CD8(+) T CELLS FROM FELINE IMMUNODEFICIENCY VIRUS-INFECTED CATS. CD8(+) T CELLS ARE CRITICAL FOR CONTROLLING HIV INFECTION. DURING THE CHRONIC PHASE OF LENTIVIRAL INFECTION, CD8(+) T CELLS LOSE THEIR PROLIFERATIVE CAPACITY AND EXHIBIT IMPAIRED ANTIVIRAL FUNCTION. THIS LOSS OF CD8(+) T CELL FUNCTION IS DUE, IN PART, TO CD4(+)CD25(+) T REGULATORY (TREG) CELL-MEDIATED SUPPRESSION. OUR RESEARCH GROUP HAS DEMONSTRATED THAT LENTIVIRUS-ACTIVATED CD4(+)CD25(+) TREG CELLS INDUCE THE REPRESSIVE TRANSCRIPTION FACTOR FORKHEAD BOX P3 (FOXP3) IN AUTOLOGOUS CD8(+) T CELLS FOLLOWING CO-CULTURE. WE HAVE RECENTLY REPORTED THAT TREG-INDUCED FOXP3 BINDS THE INTERLEUKIN-2 (IL-2), INTERFERON-GAMMA (IFN- GAMMA), AND TUMOR NECROSIS FACTOR-ALPHA (TNF-ALPHA) PROMOTERS IN VIRUS-SPECIFIC CD8(+) T CELLS. THESE DATA SUGGEST AN IMPORTANT ROLE OF FOXP3-MEDIATED CD8(+) T CELL DYSFUNCTION IN LENTIVIRAL INFECTION. TO ELUCIDATE THE MECHANISM OF THIS SUPPRESSION, WE PREVIOUSLY REPORTED THAT DECREASED METHYLATION FACILITATES FOXP3 BINDING IN MITOGEN-ACTIVATED CD8(+) T CELLS FROM FELINE IMMUNODEFICIENCY VIRUS (FIV)-INFECTED CATS. WE DEMONSTRATED THE REDUCED BINDING OF FOXP3 TO THE IL-2 PROMOTER BY INCREASING METHYLATION OF CD8(+) T CELLS. IN THE STUDIES PRESENTED HERE, WE ASK IF ANOTHER FORM OF EPIGENETIC MODULATION MIGHT ALLEVIATE FOXP3-MEDIATED SUPPRESSION IN CD8(+) T CELLS. WE HYPOTHESIZED THAT DECREASING HISTONE ACETYLATION IN VIRUS-SPECIFIC CD8(+) T CELLS WOULD DECREASE TREG-INDUCED FOXP3 BINDING TO THE IL-2 PROMOTER. INDEED, USING ANACARDIC ACID (AA), A KNOWN HISTONE ACETYL TRANSFERASE (HAT) INHIBITOR, WE DEMONSTRATE A REDUCTION IN FOXP3 BINDING TO THE IL-2 PROMOTER IN VIRUS-SPECIFIC CD8(+) T CELLS CO-CULTURED WITH AUTOLOGOUS TREG CELLS. THESE DATA IDENTIFY A NOVEL MECHANISM OF FOXP3-MEDIATED CD8(+) T CELL DYSFUNCTION DURING LENTIVIRAL INFECTION. 2018 6 3111 34 GENOTYPE-PHENOTYPE INTERACTIONS IN THE MYELOPROLIFERATIVE NEOPLASMS. THE CHRONIC MYELOPROLIFERATIVE NEOPLASMS (MPNS) ARE CLONAL DISORDERS CHARACTERIZED BY OVERPRODUCTION OF MATURE MYELOID CELLS. THEY SHARE ASSOCIATIONS WITH MOLECULAR ABNORMALITIES SUCH AS THE JAK2V617F MUTATION BUT ARE DISTINGUISHED BY IMPORTANT PHENOTYPIC DIFFERENCES. THIS REVIEW FIRST CONSIDERS THE FACTORS THAT MAY INFLUENCE PHENOTYPE IN JAK2-MUTATED MPNS, ESPECIALLY POLYCYTHEMIA VERA (PV) AND ESSENTIAL THROMBOCYTHEMIA (ET), AND THEN DISCUSSES THE MUTATIONS IMPLICATED IN JAK2-NEGATIVE MPNS SUCH AS IN MPL AND EPIGENETIC REGULATORS. CURRENT EVIDENCE SUPPORTS A MODEL WHERE ET AND PV ARE DISORDERS OF RELATIVELY LOW GENETIC COMPLEXITY, WHEREAS EVOLUTION TO MYELOFIBROSIS OR BLAST-PHASE DISEASE REFLECTS ACCUMULATION OF A HIGHER MUTATION BURDEN. 2012 7 6856 45 [NOT AVAILABLE]. BIOLOGICAL ASPECTS OF JAK/STAT SIGNALING IN BCR-ABL-NEGATIVE MYELOPROLIFERATIVE NEOPLASMS: MYELOPROLIFERATIVE DISORDERS MORE RECENTLY NAMED MYELOPROLIFERATIVE NEOPLASMS (MPN) DISPLAY SEVERAL CLINICAL ENTITIES: CHRONIC MYELOID LEUKEMIA (CML), THE CLASSICAL MPN INCLUDING POLYCYTHEMIA VERA (PV), ESSENTIAL THROMBOCYTHEMIA (ET), PRIMARY MYELOFIBROSIS (PMF) AND ATYPICAL AND UNCLASSIFIABLE NMP. THE TERM MPN IS MOSTLY USED FOR CLASSICAL BCR-ABL-NEGATIVE (MYELOPROLIFERATIVE DISORDER) (ET, PV, PMF). THESE ARE CLONAL DISEASES RESULTING FROM THE TRANSFORMATION OF AN HEMATOPOIETIC STEM CELL AND LEADING TO AN ABNORMAL PRODUCTION OF MYELOID CELLS. THE GENETIC DEFECTS RESPONSIBLE FOR THE MYELOPROLIFERATIVE ABNORMALITIES ARE CALLED << DRIVER >> MUTATIONS AND ALL RESULT IN DEREGULATION OF THE CYTOKINE RECEPTOR / JAK2 / STAT AXIS. AMONG THEM, JAK2, THE THROMBOPOIETIN RECEPTOR (MPL) AND CALRETICULIN (CALR) MUTATIONS ARE FOUND IN AROUND 90% OF THE CASES. THESE DRIVER MPN MUTATIONS CAN BE ASSOCIATED WITH OTHER DRIVER MUTATIONS ALSO FOUND IN OTHER HEMATOLOGICAL MALIGNANCIES, ESPECIALLY IN PMFS. THESE ARE CHRONIC DISEASES WITH MAJOR RISKS BEING THROMBOSIS, HEMORRHAGE AND CYTOPENIAS FOR PMF AND THE LONG-TERM PROGRESSION TO MYELOFIBROSIS AND THE TRANSFORMATION TO LEUKEMIA. MOST RECENT THERAPEUTIC HAVE FOCUSED ON TARGETING THE JAK2 SIGNALING PATHWAY DIRECTLY BY INHIBITORS OF JAK2 OR INDIRECTLY. INTERFERON A ALLOWS IN SOME CASES HEMATOLOGIC AND MOLECULAR REMISSION PATIENTS. 2016 8 4680 48 NEW MUTATIONS AND PATHOGENESIS OF MYELOPROLIFERATIVE NEOPLASMS. MYELOPROLIFERATIVE NEOPLASMS (MPNS) ARE CLONAL DISORDERS CHARACTERIZED BY EXCESSIVE PRODUCTION OF MATURE BLOOD CELLS. IN THE MAJORITY OF CLASSIC MPN--POLYCYTHEMIA VERA, ESSENTIAL THROMBOCYTHEMIA, AND PRIMITIVE MYELOFIBROSIS--DRIVER ONCOGENIC MUTATIONS AFFECTING JANUS KINASE 2 (JAK2) OR MPL LEAD TO CONSTITUTIVE ACTIVATION OF CYTOKINE-REGULATED INTRACELLULAR SIGNALING PATHWAYS. LNK, C-CBL, OR SOCSS (ALL NEGATIVE REGULATORS OF SIGNALING PATHWAYS), ALTHOUGH INFREQUENTLY TARGETED, MAY EITHER DRIVE THE DISEASE OR SYNERGIZE WITH JAK2 AND MPL MUTATIONS. IZF1 DELETIONS OR TP53 MUTATIONS ARE MAINLY FOUND AT TRANSFORMATION PHASES AND ARE PRESENT AT GREATER FREQUENCY THAN IN DE NOVO ACUTE MYELOID LEUKEMIAS. LOSS-OF-FUNCTION MUTATIONS IN 3 GENES INVOLVED IN EPIGENETIC REGULATION, TET2, ASXL1, AND EZH2, MAY BE EARLY EVENTS PRECEDING JAK2V617F BUT MAY ALSO OCCUR LATE DURING DISEASE PROGRESSION. THEY ARE MORE FREQUENTLY OBSERVED IN PMF THAN PV AND ET AND ARE ALSO PRESENT IN OTHER TYPES OF MALIGNANT MYELOID DISEASES. A LIKELY HYPOTHESIS IS THAT THEY FACILITATE CLONAL SELECTION, ALLOWING THE DOMINANCE OF THE JAK2V617F SUBCLONE DURING THE CHRONIC PHASE AND, TOGETHER WITH COOPERATING MUTATIONS, PROMOTE BLAST CRISIS. THEIR PRECISE ROLES IN HEMATOPOIESIS AND IN THE PATHOGENESIS OF MPN, AS WELL AS THEIR PROGNOSTIC IMPACT AND POTENTIAL AS A THERAPEUTIC TARGET, ARE CURRENTLY UNDER INVESTIGATION. 2011 9 4557 25 MUTATIONS IN ASXL1 ARE ASSOCIATED WITH POOR PROGNOSIS ACROSS THE SPECTRUM OF MALIGNANT MYELOID DISEASES. THE ASXL1 GENE IS ONE OF THE MOST FREQUENTLY MUTATED GENES IN MALIGNANT MYELOID DISEASES. THE ASXL1 PROTEIN BELONGS TO PROTEIN COMPLEXES INVOLVED IN THE EPIGENETIC REGULATION OF GENE EXPRESSION. ASXL1 MUTATIONS ARE FOUND IN MYELOPROLIFERATIVE NEOPLASMS (MPN), MYELODYSPLASTIC SYNDROMES (MDS), CHRONIC MYELOMONOCYTIC LEUKEMIA (CMML) AND ACUTE MYELOID LEUKEMIA (AML). THEY ARE GENERALLY ASSOCIATED WITH SIGNS OF AGGRESSIVENESS AND POOR CLINICAL OUTCOME. BECAUSE OF THIS, A SYSTEMATIC DETERMINATION OF ASXL1 MUTATIONAL STATUS IN MYELOID MALIGNANCIES SHOULD HELP IN PROGNOSIS ASSESSMENT. 2012 10 1268 29 CYTOPLASMATIC COMPARTMENTALIZATION BY BCR-ABL PROMOTES TET2 LOSS-OF-FUNCTION IN CHRONIC MYELOID LEUKEMIA. THE LOSS-OF-FUNCTION OF TEN-ELEVEN-TRANSLOCATION (TET) 2, A FE(2+) -OXOGLUTARATE-DEPENDENT DIOXYGENASE CATALYZING 5 METHYL CYTOSINE (5MC) CONVERSION INTO 5-HYDROXYMETHYLCYTOSINE (5HMC), CONTRIBUTES TO THE HEMATOPOIETIC TRANSFORMATION IN VIVO. THE AIM OF OUR STUDY WAS TO ELUCIDATE ITS ROLE IN THE PHENOTYPE OF CHRONIC MYELOID LEUKEMIA (CML), A MYELOPROLIFERATIVE DISEASE CAUSED BY THE BCR-ABL REARRANGED GENE. WE FIRST CONFIRMED TET2 INTERACTION WITH THE BCR-ABL PROTEIN PREDICTED BY A FOURIER-BASED BIOINFORMATIC METHOD. SUCH INTERACTION LED TO TET2 CYTOPLASMATIC COMPARTMENTALIZATION IN A COMPLEX TETHERED BY THE FUSION PROTEIN TYROSINE KINASE (TK) AND ENCOMPASSING THE FORKHEAD BOX O3A (FOXO3A) TRANSCRIPTION FACTOR. WE THEN FOCUSED THE IMPACT OF TET2 LOSS-OF-FUNCTION ON EPIGENETIC TRANSCRIPTIONAL REGULATION OF BCL2-INTERACTING MEDIATOR (BIM), A PRO-APOPTOTIC PROTEIN TRANSCRIPTIONALLY REGULATED BY FOXO3A. BIM DOWNREGULATION IS A CRITICAL COMPONENT OF CML PROGENITOR EXTENDED SURVIVAL AND IS ALSO INVOLVED IN THE DISEASE RESISTANCE TO IMATINIB (IM). HERE WE REPORTED THAT TET2 RELEASE FROM BCR-ABL PROTEIN FOLLOWING TK INHIBITION IN RESPONSE TO IM TRIGGERS A CHAIN OF EVENTS INCLUDING TET2 NUCLEAR TRANSLOCATION, RE-ACTIVATION OF ITS ENZYMATIC FUNCTION AT 5MC AND RECRUITMENT AT THE BIM PROMOTER FOLLOWED BY BIM TRANSCRIPTIONAL INDUCTION. 5HMC INCREMENT FOLLOWING TET2 RE-ACTIVATION WAS ASSOCIATED WITH THE REDUCTION OF HISTONE H3 TRI-METHYLATION AT LYSINE 9 (H3K9ME3), WHICH MAY CONTRIBUTE WITH DNA DE-METHYLATION REPORTED ELSEWHERE TO RECAST A PERMISSIVE EPIGENETIC "LANDSCAPE" FOR FOXO3A TRANSCRIPTIONAL ACTIVITY. 2012 11 5953 43 TARGETS IN MPNS AND POTENTIAL THERAPEUTICS. PHILADELPHIA-NEGATIVE CLASSICAL MYELOPROLIFERATIVE NEOPLASMS (MPNS), INCLUDING POLYCYTHEMIA VERA (PV), ESSENTIAL THROMBOCYTHEMIA (ET) AND PRIMARY MYELOFIBROSIS (PMF), ARE CLONAL HEMOPATHIES THAT EMERGE IN THE HEMATOPOIETIC STEM CELL (HSC) COMPARTMENT. MPN DRIVER MUTATIONS ARE RESTRICTED TO SPECIFIC EXONS (14 AND 12) OF JANUS KINASE 2 (JAK2), THROMBOPOIETIN RECEPTOR (MPL/TPOR) AND CALRETICULIN (CALR) GENES, ARE INVOLVED DIRECTLY IN CLONAL MYELOPROLIFERATION AND GENERATE THE MPN PHENOTYPE. AS A RESULT, AN INCREASED NUMBER OF FULLY FUNCTIONAL ERYTHROCYTES, PLATELETS AND LEUKOCYTES IS OBSERVED IN THE PERIPHERAL BLOOD. NEVERTHELESS, THE COMPLEXITY AND HETEROGENEITY OF MPN CLINICAL PHENOTYPES CANNOT BE SOLELY EXPLAINED BY THE TYPE OF DRIVER MUTATION. OTHER FACTORS, SUCH AS ADDITIONAL SOMATIC MUTATIONS AFFECTING EPIGENETIC REGULATORS OR SPLICEOSOMES COMPONENTS, MUTANT ALLELE BURDENS AND MODIFIERS OF SIGNALING BY DRIVER MUTANTS, CLONAL ARCHITECTURE AND THE ORDER OF MUTATION ACQUISITION, SIGNALING EVENTS THAT OCCUR DOWNSTREAM OF A DRIVER MUTATION, THE PRESENCE OF SPECIFIC GERM-LINE VARIANTS, THE INTERACTION OF THE NEOPLASTIC CLONE WITH BONE MARROW MICROENVIRONMENT AND CHRONIC INFLAMMATION, ALL CAN MODULATE THE DISEASE PHENOTYPE, INFLUENCE THE MPN CLINICAL COURSE AND THEREFORE, MIGHT BE USEFUL THERAPEUTIC TARGETS. 2022 12 2277 40 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 13 4485 36 MOLECULAR SIMILARITY BETWEEN MYELODYSPLASTIC FORM OF CHRONIC MYELOMONOCYTIC LEUKEMIA AND REFRACTORY ANEMIA WITH RING SIDEROBLASTS. CHRONIC MYELOMONOCYTIC LEUKEMIA IS SIMILAR TO BUT A SEPARATE ENTITY FROM BOTH MYELOPROLIFERATIVE NEOPLASMS AND MYELODYSPLASTIC SYNDROMES, AND SHOWS EITHER MYELOPROLIFERATIVE OR MYELODYSPLASTIC FEATURES. WE ASK WHETHER THIS DISTINCTION MAY HAVE A MOLECULAR BASIS. WE ESTABLISHED THE GENE EXPRESSION PROFILES OF 39 SAMPLES OF CHRONIC MYELOMONOCYTIC LEUKEMIA (INCLUDING 12 CD34-POSITIVE) AND 32 CD34-POSITIVE SAMPLES OF MYELODYSPLASTIC SYNDROMES BY USING AFFYMETRIX MICROARRAYS, AND STUDIED THE STATUS OF 18 GENES BY SANGER SEQUENCING AND ARRAY-COMPARATIVE GENOMIC HYBRIDIZATION IN 53 SAMPLES. ANALYSIS OF 12 MRNAS FROM CHRONIC MYELOMONOCYTIC LEUKEMIA ESTABLISHED A GENE EXPRESSION SIGNATURE OF 122 PROBE SETS DIFFERENTIALLY EXPRESSED BETWEEN PROLIFERATIVE AND DYSPLASTIC CASES OF CHRONIC MYELOMONOCYTIC LEUKEMIA. AS COMPARED TO PROLIFERATIVE CASES, DYSPLASTIC CASES OVER-EXPRESSED GENES INVOLVED IN RED BLOOD CELL BIOLOGY. WHEN APPLIED TO 32 MYELODYSPLASTIC SYNDROMES, THIS GENE EXPRESSION SIGNATURE WAS ABLE TO DISCRIMINATE REFRACTORY ANEMIAS WITH RING SIDEROBLASTS FROM REFRACTORY ANEMIAS WITH EXCESS OF BLASTS. BY COMPARING MRNAS FROM THESE TWO FORMS OF MYELODYSPLASTIC SYNDROMES WE DERIVED A SECOND GENE EXPRESSION SIGNATURE. THIS SIGNATURE SEPARATED THE MYELODYSPLASTIC AND MYELOPROLIFERATIVE FORMS OF CHRONIC MYELOMONOCYTIC LEUKEMIAS. THESE RESULTS WERE VALIDATED USING TWO INDEPENDENT GENE EXPRESSION DATA SETS. WE FOUND THAT MYELODYSPLASTIC CHRONIC MYELOMONOCYTIC LEUKEMIAS ARE CHARACTERIZED BY MUTATIONS IN TRANSCRIPTION/EPIGENETIC REGULATORS (ASXL1, RUNX1, TET2) AND SPLICING GENES (SRSF2) AND THE ABSENCE OF MUTATIONS IN SIGNALING GENES. MYELODYSPLASTIC CHRONIC MYELOMONOCYTIC LEUKEMIAS AND REFRACTORY ANEMIAS WITH RING SIDEROBLASTS SHARE A COMMON EXPRESSION PROGRAM SUGGESTING THEY ARE PART OF A CONTINUUM, WHICH IS NOT TOTALLY EXPLAINED BY THEIR SIMILAR BUT NOT, HOWEVER, IDENTICAL MUTATION SPECTRUM. 2013 14 472 37 ARRAY COMPARATIVE GENOMIC HYBRIDIZATION AND SEQUENCING OF 23 GENES IN 80 PATIENTS WITH MYELOFIBROSIS AT CHRONIC OR ACUTE PHASE. MYELOFIBROSIS IS A MYELOPROLIFERATIVE NEOPLASM THAT OCCURS DE NOVO (PRIMARY MYELOFIBROSIS) OR RESULTS FROM THE PROGRESSION OF POLYCYTHEMIA VERA OR ESSENTIAL THROMBOCYTEMIA (HEREAFTER DESIGNATED AS SECONDARY MYELOFIBROSIS OR POST-POLYCYTHEMIA VERA/ ESSENTIAL THROMBOCYTHEMIA MYELOFIBROSIS). TO PROGRESS IN THE UNDERSTANDING OF MYELOFIBROSIS AND TO FIND MOLECULAR PROGNOSTIC MARKERS WE STUDIED 104 SAMPLES OF PRIMARY AND SECONDARY MYELOFIBROSIS AT CHRONIC (N=68) AND ACUTE PHASES (N=12) FROM 80 PATIENTS, BY USING ARRAY-COMPARATIVE GENOMIC HYBRIDIZATION AND SEQUENCING OF 23 GENES (ASXL1, BMI1, CBL, DNMT3A, EZH2, IDH1/2, JAK2, K/NRAS, LNK, MPL, NF1, PPP1R16B, PTPN11, RCOR1, SF3B1, SOCS2, SRSF2, SUZ12, TET2, TP53, TRPS1). WE FOUND COPY NUMBER ABERRATIONS IN 54% OF SAMPLES, OFTEN INVOLVING GENES WITH A KNOWN OR POTENTIAL ROLE IN LEUKEMOGENESIS. WE SHOW THAT CASES CARRYING A DEL(20Q), DEL(17) OR DEL(12P) EVOLVE IN ACUTE MYELOID LEUKEMIA (P=0.03). WE FOUND THAT 88% OF THE CASES WERE MUTATED, MAINLY IN SIGNALING PATHWAY (JAK2 69%, NF1 6%) AND EPIGENETIC GENES (ASXL1 26%, TET2 14%, EZH2 8%). OVERALL SURVIVAL WAS POOR IN PATIENTS WITH MORE THAN ONE MUTATION (P=0.001) AND IN PATIENTS WITH JAK2/ASXL1 MUTATIONS (P=0.02). OUR STUDY HIGHLIGHTS THE HETEROGENEITY OF MYELOFIBROSIS, AND POINTS TO SEVERAL INTERESTING COPY NUMBER ABERRATIONS AND GENES WITH DIAGNOSTIC AND PROGNOSTIC IMPACT. 2014 15 5983 37 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 16 1184 23 COOPERATIVE EPIGENETIC REMODELING BY TET2 LOSS AND NRAS MUTATION DRIVES MYELOID TRANSFORMATION AND MEK INHIBITOR SENSITIVITY. MUTATIONS IN EPIGENETIC MODIFIERS AND SIGNALING FACTORS OFTEN CO-OCCUR IN MYELOID MALIGNANCIES, INCLUDING TET2 AND NRAS MUTATIONS. CONCURRENT TET2 LOSS AND NRAS(G12D) EXPRESSION IN HEMATOPOIETIC CELLS INDUCED MYELOID TRANSFORMATION, WITH A FULLY PENETRANT, LETHAL CHRONIC MYELOMONOCYTIC LEUKEMIA (CMML), WHICH WAS SERIALLY TRANSPLANTABLE. TET2 LOSS AND NRAS MUTATION COOPERATIVELY LED TO DECREASE IN NEGATIVE REGULATORS OF MITOGEN-ACTIVATED PROTEIN KINASE (MAPK) ACTIVATION, INCLUDING SPRY2, THEREBY CAUSING SYNERGISTIC ACTIVATION OF MAPK SIGNALING BY EPIGENETIC SILENCING. TET2/NRAS DOUBLE-MUTANT LEUKEMIA SHOWED PREFERENTIAL SENSITIVITY TO MAPK KINASE (MEK) INHIBITION IN BOTH MOUSE MODEL AND PATIENT SAMPLES. THESE DATA PROVIDE INSIGHTS INTO HOW EPIGENETIC AND SIGNALING MUTATIONS COOPERATE IN MYELOID TRANSFORMATION AND PROVIDE A RATIONALE FOR MECHANISM-BASED THERAPY IN CMML PATIENTS WITH THESE HIGH-RISK GENETIC LESIONS. 2018 17 5908 27 TARGETED DE-METHYLATION OF THE FOXP3-TSDR IS SUFFICIENT TO INDUCE PHYSIOLOGICAL FOXP3 EXPRESSION BUT NOT A FUNCTIONAL TREG PHENOTYPE. CD4+ REGULATORY T CELLS (TREGS) ARE KEY MEDIATORS OF IMMUNOLOGICAL TOLERANCE AND PROMISING EFFECTOR CELLS FOR IMMUNO-SUPPRESSIVE ADOPTIVE CELLULAR THERAPY TO FIGHT AUTOIMMUNITY AND CHRONIC INFLAMMATION. THEIR FUNCTIONAL STABILITY IS CRITICAL FOR THEIR CLINICAL UTILITY AND HAS BEEN CORRELATED TO THE DEMETHYLATED STATE OF THE TSDR/CNS2 ENHANCER ELEMENT IN THE TREG LINEAGE TRANSCRIPTION FACTOR FOXP3. HOWEVER, PROOF FOR A CAUSAL CONTRIBUTION OF THE TSDR DE-METHYLATION TO FOXP3 STABILITY AND TREG INDUCTION IS SO FAR LACKING. WE HERE ESTABLISHED A POWERFUL TRANSIENT-TRANSFECTION CRISPR-CAS9-BASED EPIGENETIC EDITING METHOD FOR THE SELECTIVE DE-METHYLATION OF THE TSDR WITHIN THE ENDOGENOUS CHROMATIN ENVIRONMENT OF A LIVING CELL. THE INDUCED DE-METHYLATED STATE WAS STABLE OVER WEEKS IN CLONAL T CELL PROLIFERATION CULTURES EVEN AFTER EXPRESSION OF THE EDITING COMPLEX HAD CEASED. EPIGENETIC EDITING OF THE TSDR RESULTED IN FOXP3 EXPRESSION, EVEN IN ITS PHYSIOLOGICAL ISOFORM DISTRIBUTION, PROVING A CAUSAL ROLE FOR THE DE-METHYLATED TSDR IN FOXP3 REGULATION. HOWEVER, SUCCESSFUL FOXP3 INDUCTION WAS NOT ASSOCIATED WITH A SWITCH TOWARDS A FUNCTIONAL TREG PHENOTYPE, IN CONTRAST TO WHAT HAS BEEN REPORTED FROM FOXP3 OVEREXPRESSION APPROACHES. THUS, TSDR DE-METHYLATION IS REQUIRED, BUT NOT SUFFICIENT FOR A STABLE TREG PHENOTYPE INDUCTION. THEREFORE, TARGETED DEMETHYLATION OF THE TSDR MAY BE A CRITICAL ADDITION TO PUBLISHED IN VITRO TREG INDUCTION PROTOCOLS WHICH SO FAR LACK FOXP3 STABILITY. 2020 18 3871 31 JUVENILE MYELOMONOCYTIC LEUKEMIA - A BONA FIDE RASOPATHY SYNDROME. JUVENILE MYELOMONOCYTIC LEUKEMIA (JMML) IS A PEDIATRIC MYELODYSPLASTIC/MYELOPROLIFERATIVE NEOPLASM OVERLAP SYNDROME WITH SUSTAINED PERIPHERAL BLOOD MONOCYTOSIS, AGGRESSIVE FEATURES, AND POOR OUTCOMES. IN >90% OF CASES JMML IS DRIVEN BY GERMLINE OR SOMATIC MUTATIONS INVOLVING THE CANONICAL RAS PATHWAY (PTPN11, NRAS, CBL, KRAS AND NF1), WITH SOMATIC MUTATIONS/ALTERATIONS IN RAS PATHWAY GENES (SECOND HIT), SETBP1, ASXL1 AND JAK3 RESULTING IN DISEASE PROGRESSION. WHILE SPONTANEOUS REGRESSION HAS BEEN SEEN IN GERMLINE PTPN11 AND CBL MUTANT JMML, IN MOST PATIENTS, ALLOGENEIC STEM CELL TRANSPLANT IS THE ONLY CURATIVE MODALITY. JMML SHARES SEVERAL PHENOTYPIC FEATURES WITH ITS ADULT COUNTERPART PROLIFERATIVE, CHRONIC MYELOMONOCYTIC LEUKEMIA (PCMML). PCMML LARGELY OCCURS DUE TO RAS PATHWAY MUTATIONS THAT OCCUR IN THE CONTEXT OF AGE RELATED CLONAL HEMATOPOIESIS (TET2, SRSF2, ASXL1), WHILE JMML IS A BONA FIDE RASOPATHY, WITH ADDITIONAL SOMATIC MUTATIONS, INCLUDING IN EPIGENETIC REGULATORS GENES RESULTING IN DISEASE PROGRESSION. 2020 19 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 20 1947 44 EPIGENETIC ABNORMALITIES IN MYELOPROLIFERATIVE NEOPLASMS: A TARGET FOR NOVEL THERAPEUTIC STRATEGIES. THE MYELOPROLIFERATIVE NEOPLASMS (MPNS) ARE A GROUP OF CLONAL HEMATOLOGICAL MALIGNANCIES CHARACTERIZED BY A HYPERCELLULAR BONE MARROW AND A TENDENCY TO DEVELOP THROMBOTIC COMPLICATIONS AND TO EVOLVE TO MYELOFIBROSIS AND ACUTE LEUKEMIA. UNLIKE CHRONIC MYELOGENOUS LEUKEMIA, WHERE A SINGLE DISEASE-INITIATING GENETIC EVENT HAS BEEN IDENTIFIED, A MORE COMPLICATED SERIES OF GENETIC MUTATIONS APPEAR TO BE RESPONSIBLE FOR THE BCR-ABL1-NEGATIVE MPNS WHICH INCLUDE POLYCYTHEMIA VERA, ESSENTIAL THROMBOCYTHEMIA, AND PRIMARY MYELOFIBROSIS. RECENT STUDIES HAVE REVEALED A NUMBER OF EPIGENETIC ALTERATIONS THAT ALSO LIKELY CONTRIBUTE TO DISEASE PATHOGENESIS AND DETERMINE CLINICAL OUTCOME. INCREASING EVIDENCE INDICATES THAT ALTERATIONS IN DNA METHYLATION, HISTONE MODIFICATION, AND MICRORNA EXPRESSION PATTERNS CAN COLLECTIVELY INFLUENCE GENE EXPRESSION AND POTENTIALLY CONTRIBUTE TO MPN PATHOGENESIS. EXAMPLES INCLUDE MUTATIONS IN GENES ENCODING PROTEINS THAT MODIFY CHROMATIN STRUCTURE (EZH2, ASXL1, IDH1/2, JAK2V617F, AND IKZF1) AS WELL AS EPIGENETIC MODIFICATION OF GENES CRITICAL FOR CELL PROLIFERATION AND SURVIVAL (SUPPRESSORS OF CYTOKINE SIGNALING, POLYCYTHEMIA RUBRA VERA-1, CXC CHEMOKINE RECEPTOR 4, AND HISTONE DEACETYLASE (HDAC)). THESE EPIGENETIC LESIONS SERVE AS NOVEL TARGETS FOR EXPERIMENTAL THERAPEUTIC INTERVENTIONS. CLINICAL TRIALS ARE CURRENTLY UNDERWAY EVALUATING HDAC INHIBITORS AND DNA METHYLTRANSFERASE INHIBITORS FOR THE TREATMENT OF PATIENTS WITH MPNS. 2011