1 3871 95 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 2 3617 19 IN VITRO MODELING OF CD8(+) T CELL EXHAUSTION ENABLES CRISPR SCREENING TO REVEAL A ROLE FOR BHLHE40. IDENTIFYING MOLECULAR MECHANISMS OF EXHAUSTED CD8 T CELLS (T(EX)) IS A KEY GOAL OF IMPROVING IMMUNOTHERAPY OF CANCER AND OTHER DISEASES. HOWEVER, HIGH-THROUGHPUT INTERROGATION OF IN VIVO T(EX) CAN BE COSTLY AND INEFFICIENT. IN VITRO MODELS OF T(EX) ARE EASILY CUSTOMIZABLE AND QUICKLY GENERATE HIGH CELLULAR YIELD, ENABLING CRISPR SCREENING AND OTHER HIGH-THROUGHPUT ASSAYS. WE ESTABLISHED AN IN VITRO MODEL OF CHRONIC STIMULATION AND BENCHMARKED KEY PHENOTYPIC, FUNCTIONAL, TRANSCRIPTIONAL, AND EPIGENETIC FEATURES AGAINST BONA FIDE IN VIVO T(EX). WE LEVERAGED THIS MODEL OF IN VITRO CHRONIC STIMULATION IN COMBINATION WITH CRISPR SCREENING TO IDENTIFY TRANSCRIPTIONAL REGULATORS OF T CELL EXHAUSTION. THIS APPROACH IDENTIFIED SEVERAL TRANSCRIPTION FACTORS, INCLUDING BHLHE40. IN VITRO AND IN VIVO VALIDATION DEFINED A ROLE FOR BHLHE40 IN REGULATING A KEY DIFFERENTIATION CHECKPOINT BETWEEN PROGENITOR AND INTERMEDIATE T(EX) SUBSETS. BY DEVELOPING AND BENCHMARKING AN IN VITRO MODEL OF T(EX), THEN APPLYING HIGH-THROUGHPUT CRISPR SCREENING, WE DEMONSTRATE THE UTILITY OF MECHANISTICALLY ANNOTATED IN VITRO MODELS OF T(EX). 2023 3 3616 19 IN VITRO MODELING OF CD8 T CELL EXHAUSTION ENABLES CRISPR SCREENING TO REVEAL A ROLE FOR BHLHE40. IDENTIFYING NOVEL MOLECULAR MECHANISMS OF EXHAUSTED CD8 T CELLS (T (EX) ) IS A KEY GOAL OF IMPROVING IMMUNOTHERAPY OF CANCER AND OTHER DISEASES. HOWEVER, HIGH-THROUGHPUT INTERROGATION OF IN VIVO T (EX) CAN BE COSTLY AND INEFFICIENT. IN VITRO MODELS OF T (EX) ARE EASILY CUSTOMIZABLE AND QUICKLY GENERATE HIGH CELLULAR YIELD, OFFERING AN OPPORTUNITY TO PERFORM CRISPR SCREENING AND OTHER HIGH-THROUGHPUT ASSAYS. WE ESTABLISHED AN IN VITRO MODEL OF CHRONIC STIMULATION AND BENCHMARKED KEY PHENOTYPIC, FUNCTIONAL, TRANSCRIPTIONAL, AND EPIGENETIC FEATURES AGAINST BONA FIDE IN VIVO T (EX) . WE LEVERAGED THIS MODEL OF IN VITRO CHRONIC STIMULATION IN COMBINATION WITH POOLED CRISPR SCREENING TO UNCOVER TRANSCRIPTIONAL REGULATORS OF T CELL EXHAUSTION. THIS APPROACH IDENTIFIED SEVERAL TRANSCRIPTION FACTORS, INCLUDING BHLHE40. IN VITRO AND IN VIVO VALIDATION DEFINED A ROLE FOR BHLHE40 IN REGULATING A KEY DIFFERENTIATION CHECKPOINT BETWEEN PROGENITOR AND INTERMEDIATE SUBSETS OF T (EX) . BY DEVELOPING AND BENCHMARKING AN IN VITRO MODEL OF T (EX) , WE DEMONSTRATE THE UTILITY OF MECHANISTICALLY ANNOTATED IN VITRO MODELS OF T (EX) , IN COMBINATION WITH HIGH-THROUGHPUT APPROACHES, AS A DISCOVERY PIPELINE TO UNCOVER NOVEL T (EX) BIOLOGY. 2023 4 3115 22 GEROMETABOLITES: THE PSEUDOHYPOXIC AGING SIDE OF CANCER ONCOMETABOLITES. ONCOMETABOLITES ARE DEFINED AS SMALL-MOLECULE COMPONENTS (OR ENANTIOMERS) OF NORMAL METABOLISM WHOSE ACCUMULATION CAUSES SIGNALING DYSREGULATION TO ESTABLISH A MILIEU THAT INITIATES CARCINOGENESIS. IN A SIMILAR MANNER, WE PROPOSE THE TERM "GEROMETABOLITES" TO REFER TO SMALL-MOLECULE COMPONENTS OF NORMAL METABOLISM WHOSE DEPLETION CAUSES SIGNALING DYSREGULATION TO ESTABLISH A MILIEU THAT DRIVES AGING. IN AN INVESTIGATION OF THE PATHOGENIC ACTIVITIES OF THE CURRENTLY RECOGNIZED ONCOMETABOLITES R(-)-2-HYDROXYGLUTARATE (2-HG), FUMARATE, AND SUCCINATE, WHICH ACCUMULATE DUE TO MUTATIONS IN ISOCITRATE DEHYDROGENASES (IDH), FUMARATE HYDRATASE (FH), AND SUCCINATE DEHYDROGENASE (SDH), RESPECTIVELY, WE ILLUSTRATE THE FACT THAT METABOLIC PSEUDOHYPOXIA, THE ACCUMULATION OF HYPOXIA-INDUCIBLE FACTOR (HIFALPHA) UNDER NORMOXIC CONDITIONS, AND THE SUBSEQUENT WARBURG-LIKE REPROGRAMMING THAT SHIFTS GLUCOSE METABOLISM FROM THE OXIDATIVE PATHWAY TO AEROBIC GLYCOLYSIS ARE THE SAME MECHANISMS THROUGH WHICH THE DECLINE OF THE "GEROMETABOLITE" NICOTINAMIDE ADENINE DINUCLEOTIDE (NAD)(+) REVERSIBLY DISRUPTS NUCLEAR-MITOCHONDRIAL COMMUNICATION AND CONTRIBUTES TO THE DECLINE IN MITOCHONDRIAL FUNCTION WITH AGE. FROM AN EVOLUTIONARY PERSPECTIVE, IT IS REASONABLE TO VIEW NAD(+)-DRIVEN MITOCHONDRIAL HOMEOSTASIS AS A CONSERVED RESPONSE TO CHANGES IN ENERGY SUPPLIES AND OXYGEN LEVELS. SIMILARLY, THE NATURAL ABILITY OF 2-HG TO SIGNIFICANTLY ALTER EPIGENETICS MIGHT REFLECT AN EVOLUTIONARILY ANCIENT ROLE OF CERTAIN METABOLITES TO SIGNAL FOR ELEVATED GLUTAMINE/GLUTAMATE METABOLISM AND/OR OXYGEN DEFICIENCY. HOWEVER, WHEN CHRONICALLY ALTERED, THESE RESPONSES BECOME CONSERVED CAUSES OF AGING AND CANCER. BECAUSE HIFALPHA-DRIVEN PSEUDOHYPOXIA MIGHT DRIVE THE OVERPRODUCTION OF 2-HG, THE INTRIGUING POSSIBILITY EXISTS THAT THE DECLINE OF GEROMETABOLITES SUCH AS NAD(+) COULD PROMOTE THE CHRONIC ACCUMULATION OF ONCOMETABOLITES IN NORMAL CELLS DURING AGING. IF THE SOLE ACTIVATION OF A WARBURG-LIKE METABOLIC REPROGRAMMING IN NORMAL TISSUES MIGHT BE ABLE TO SIGNIFICANTLY INCREASE THE ENDOGENOUS PRODUCTION OF BONA FIDE ETIOLOGICAL DETERMINANTS IN CANCER, SUCH AS ONCOMETABOLITES, THIS UNDESIRABLE TRADE-OFF BETWEEN MITOCHONDRIAL DYSFUNCTION AND ACTIVATION OF ONCOMETABOLITES PRODUCTION MIGHT THEN PAVE THE WAY FOR THE EPIGENETIC INITIATION OF CARCINOGENESIS IN A STRICTLY METABOLIC-DEPENDENT MANNER. PERHAPS IT IS TIME TO DEFINITELY ADOPT THE VIEW THAT AGING AND AGING DISEASES INCLUDING CANCER ARE GOVERNED BY A PIVOTAL REGULATORY ROLE OF METABOLIC REPROGRAMMING IN CELL FATE DECISIONS. 2014 5 5971 25 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 6 1078 24 CLONAL NON-MALIGNANT HEMATOLOGICAL DISORDERS: UNRAVELING MOLECULAR PATHOGENIC MECHANISMS TO DEVELOP NOVEL TARGETED THERAPEUTICS. CLONAL NON-MALIGNANT HEMATOLOGICAL DISORDERS ARE A HETEROGENEOUS GROUP OF DISEASES THAT ARE PARTICULARLY CHALLENGING FOR HEMATOLOGISTS. INDEED, MOST OBVIOUS AND FREQUENT HEMATOLOGICAL DISEASES INCLUDE A BROAD SPECTRUM OF MALIGNANCIES, SUCH AS LEUKEMIAS, LYMPHOMAS, MYELOMA, AND OTHER MYELOPROLIFERATIVE OR LYMPHOPROLIFERATIVE DISORDERS. IN RECENT YEARS, ALL THESE DISEASES HAVE BEEN CATEGORIZED BY THE WHO ACCORDING TO A NOVEL CLASSIFICATION OF MYELOID AND LYMPHOID MALIGNANCIES, WHICH TAKES IN ACCOUNT THE OUTSTANDING PROGRESS IN OUR UNDERSTANDING OF MOLECULAR DEFECTS UNDERLYING HEMATOLOGICAL MALIGNANCIES. REGARDLESS OF A NUMBER OF NOVEL TECHNOLOGIES, HEMATOLOGISTS CONTINUE TO DEAL DAILY WITH CONDITIONS WHERE A CLEAR DIAGNOSIS OF A MALIGNANCY IS MISSING: THIS IS THE CASE OF SEVERAL CLONAL HEMATOLOGICAL DISORDERS, WHICH ARE CONSIDERED BONA FIDE NON-MALIGNANT. SOME MYELODYSPLASTIC SYNDROMES, CHRONIC T AND NK DISORDERS OF GRANULAR LYMPHOCYTES, MYELOFIBROSIS, MONOCLONAL GAMMOPATHIES, MONOCLONAL B-CEL LYMPHOCYTOSIS, MASTOCYTOSIS AND PAROXYSMAL NOCTURNAL HEMOGLOBINURIA ARE PARADIGMATIC EXAMPLES OF HOW CLONAL DISORDERS ARE CLEARLY DIFFERENT FROM CANCERS, EVEN IF THEY MAY SHARE WITH HEMATOLOGICAL MALIGNANCIES SIMILAR MOLECULAR, GENETIC, EPIGENETIC AND IMMUNOLOGICAL PROCESSES. INDEED, IT IS NOT ENTIRELY CLEAR WHETHER IN INDIVIDUAL CONDITIONS SUCH PATHOGENIC MECHANISMS MAY REPRESENT INITIAL STEP(S) OF MALIGNANT TRANSFORMATION, MAKING A BRIDGE BETWEEN THESE CLONAL NON-MALIGNANT DISORDERS AND TYPICAL HEMATOLOGICAL CANCERS. SOME OF THESE NON-MALIGNANT DISORDERS IMPLY SPECIFIC PATHOGENIC MECHANISMS AND/OR CLINICAL COURSE, AND SO THEY HAVE BEEN DEFINITELY ESTABLISHED WITH THEIR OWN BIOLOGICAL AND CLINICAL IDENTITY. HOWEVER, THE OBVIOUS QUESTION WHETHER SOME OF THESE CLONAL NON-MALIGNANT HEMATOLOGICAL DISEASES FORM SOME A KIND OF DISEASE-CONTINUUM WITH THEIR CORRESPONDING MALIGNANT COUNTERPART IS STILL TO BE ANSWERED. 2014 7 3155 14 GLUTAMINE METABOLISM IN ADIPOCYTES: A BONA FIDE EPIGENETIC MODULATOR OF INFLAMMATION. A CHRONIC LOW-GRADE INFLAMMATION OF WHITE ADIPOSE TISSUE (WAT) IS ONE OF THE HALLMARKS OF OBESITY AND IS PROPOSED TO CONTRIBUTE TO INSULIN RESISTANCE AND TYPE 2 DIABETES. DESPITE THIS, THE CAUSAL MECHANISMS UNDERLYING WAT INFLAMMATION REMAIN UNCLEAR. BASED ON METABOLOMIC ANALYSES OF HUMAN WAT, PETRUS ET AL. SHOWED THAT THE AMINO ACID GLUTAMINE WAS THE MOST MARKEDLY REDUCED POLAR METABOLITE IN THE OBESE STATE. REDUCED GLUTAMINE LEVELS IN ADIPOCYTES INDUCE AN INCREASE OF URIDINE DIPHOSPHATE N-ACETYLGLUCOSAMINE (UDP-GLCNAC) LEVELS VIA INDUCTION OF GLYCOLYSIS AND THE HEXOSAMINE BIOSYNTHETIC PATHWAYS. THIS PROMOTES NUCLEAR O-GLCNACYLATION, A POSTTRANSLATIONAL MODIFICATION THAT ACTIVATES THE TRANSCRIPTION OF PRO-INFLAMMATORY GENES. CONVERSELY, GLUTAMINE SUPPLEMENTATION IN VITRO AND IN VIVO, REVERSED THESE EFFECTS. ALTOGETHER, DYSREGULATION OF INTRACELLULAR GLUTAMINE METABOLISM IN WAT ESTABLISHES AN EPIGENETIC LINK BETWEEN ADIPOCYTES AND INFLAMMATION. THIS COMMENTARY DISCUSSES THESE FINDINGS AND THEIR POSSIBLY THERAPEUTIC RELEVANCE IN RELATION TO INSULIN RESISTANCE AND TYPE 2 DIABETES. 2020 8 1866 20 EMERGING CROSSTALK BETWEEN LONG NON-CODING RNAS AND NRF2 SIGNALING. DIVERSE STIMULI TRIGGER NRF2 SIGNALING, WHICH IN TURN TRANSCRIPTIONALLY REGULATES AN ARRAY OF DOWNSTREAM TARGETS, PROVIDING FOR MULTIPLE LAYERS OF CONTROL. WHILE NRF2 ACTIVITY LARGELY IS GOVERNED BY POSTTRANSLATIONAL MODIFICATION OF CRITICAL THIOL RESIDUES IN THE PROTEIN PARTNER AND REDOX SENSOR KEAP1, FINE-TUNING IS PROVIDED BY ADDITIONAL MECHANISMS - INCLUDING EPIGENETIC REGULATION. HEREIN, WE REVIEW THE EMERGING SIGNIFICANCE OF LONG NON-CODING RNAS (LNCRNA) AS DOWNSTREAM TARGETS AND UPSTREAM REGULATORS OF THE NRF2 SIGNALING PATHWAY. AMONG THE ~16000 LNCRNAS IN GENCODE, SOME HAVE BEEN VALIDATED AS TRANSCRIPTIONALLY REGULATED BY NRF2 (E.G., LUCAT1, NMRAL2P, ODRUL, ROR AND TUG1), AND OTHERS HAVE BEEN IDENTIFIED AS UPSTREAM REGULATORS OF NRF2 EXPRESSION (E.G., HOTAIR, MALAT1, MEG1, NRAL AND UCA1). BIOINFORMATIC ANALYSES OF ANNOTATED HUMAN LNCRNAS IDENTIFIED PUTATIVE NRF2 BINDING SITES IN THE PROMOTER REGIONS OF 13,285 LNCRNAS. FURTHER INVESTIGATION IS WARRANTED TO VALIDATE THE MANY NOVEL LNCRNAS AS BONA FIDE NRF2-REGULATED TARGETS, AND THEIR ROLES IN NRF2 SIGNALING. NRF2 IS CONSIDERED A PROMISING THERAPEUTIC CANDIDATE FOR CANCER AND OTHER CHRONIC DISEASES; THUS, TARGETING THE ASSOCIATED LNCRNAS MIGHT PROVIDE FOR A MORE REFINED FINE-TUNING OF THE SYSTEM, DEPENDING ON CELLULAR AND PATHOPHYSIOLOGICAL CONTEXT. 2020 9 1311 40 DEFINITIONS, BIOLOGY, AND CURRENT THERAPEUTIC LANDSCAPE OF MYELODYSPLASTIC/MYELOPROLIFERATIVE NEOPLASMS. MYELODYSPLASTIC/MYELOPROLIFERATIVE NEOPLASMS (MDS/MPN) ARE HEMATOLOGICAL DISORDERS CHARACTERIZED BY BOTH PROLIFERATIVE AND DYSPLASTIC FEATURES. ACCORDING TO THE 2022 INTERNATIONAL CONSENSUS CLASSIFICATION (ICC), MDS/MPN CONSISTS OF CLONAL MONOCYTOSIS OF UNDETERMINED SIGNIFICANCE (CMUS), CHRONIC MYELOMONOCYTIC LEUKEMIA (CMML), ATYPICAL CHRONIC MYELOID LEUKEMIA (ACML), MDS/MPN WITH SF3B1 MUTATION (MDS/MPN-T-SF3B1), MDS/MPN WITH RING SIDEROBLASTS AND THROMBOCYTOSIS NOT OTHERWISE SPECIFIED (MDS/MPN-RS-T-NOS), AND MDS/MPN-NOS. THESE DISORDERS EXHIBIT A DIVERSE RANGE OF GENETIC ALTERATIONS INVOLVING VARIOUS TRANSCRIPTION FACTORS (E.G., RUNX1), SIGNALING MOLECULES (E.G., NRAS, JAK2), SPLICING FACTORS (E.G., SF3B, SRSF2), AND EPIGENETIC REGULATORS (E.G., TET2, ASXL1, DNMT3A), AS WELL AS SPECIFIC CYTOGENETIC ABNORMALITIES (E.G., 8 TRISOMIES, 7 DELETIONS/MONOSOMIES). CLINICAL STUDIES EXPLORING THERAPEUTIC OPTIONS FOR HIGHER-RISK MDS/MPN OVERLAP SYNDROMES MOSTLY INVOLVE HYPOMETHYLATING AGENTS, BUT OTHER TREATMENTS SUCH AS LENALIDOMIDE AND TARGETED AGENTS SUCH AS JAK INHIBITORS AND INHIBITORS TARGETING PARP, HISTONE DEACETYLASES, AND THE RAS PATHWAY ARE UNDER INVESTIGATION. WHILE THESE TREATMENT MODALITIES CAN PROVIDE PARTIAL DISEASE CONTROL, ALLOGENEIC BONE MARROW TRANSPLANTATION (ALLO-BMT) IS THE ONLY POTENTIALLY CURATIVE OPTION FOR PATIENTS. IMPORTANT PROGNOSTIC FACTORS CORRELATING WITH OUTCOMES AFTER ALLO-BMT INCLUDE COMORBIDITIES, SPLENOMEGALY, KARYOTYPE ALTERATIONS, AND THE BONE MARROW BLASTS PERCENTAGE AT THE TIME OF TRANSPLANTATION. FUTURE RESEARCH IS IMPERATIVE TO OPTIMIZING THERAPEUTIC STRATEGIES AND ENHANCING PATIENT OUTCOMES IN MDS/MPN NEOPLASMS. IN THIS REVIEW, WE SUMMARIZE MDS/MPN DIAGNOSTIC CRITERIA, BIOLOGY, AND CURRENT AND FUTURE TREATMENT OPTIONS, INCLUDING BONE MARROW TRANSPLANTATION. 2023 10 4442 25 MOLECULAR GENETICS OF MDS/MPN OVERLAP SYNDROMES. THE MYELODYSPLASTIC/MYELOPROLIFERATIVE NEOPLASMS (MDS/MPN) ARE A HETEROGENOUS GROUP OF MYELOID MALIGNANCIES HALLMARKED BY CLINICOPATHOLOGIC FEATURES THAT OVERLAP WITH MYELODYSPLASTIC SYNDROMES AND MYELOPROLIFERATIVE NEOPLASMS. FORMALLY RECOGNIZED BY THE WORLD HEALTH ORGANIZATION, THIS GROUP INCLUDES THE ENTITIES CHRONIC MYELOMONOCYTIC LEUKEMIA, JUVENILE MYELOMONOCYTIC LEUKEMIA, ATYPICAL CHRONIC MYELOID LEUKEMIA, MDS/MPN WITH RING SIDEROBLASTS AND THROMBOCYTOSIS AND MDS/MPN, UNCLASSIFIABLE. ADVANCEMENTS IN NEXT GENERATION SEQUENCING HAVE BEGUN TO UNRAVEL THE MOLECULAR UNDERPINNINGS OF THESE DISEASES, IDENTIFYING AN ARRAY OF RECURRENTLY MUTATED GENES INVOLVED IN EPIGENETIC REGULATION, RNA SPLICING, TRANSCRIPTION, AND CELL SIGNALING. DESPITE MOLECULAR OVERLAP WITH OTHER MYELOID MALIGNANCIES, EACH ENTITY DISPLAYS A UNIQUE SPECTRUM OF SOMATIC MUTATIONS SUPPORTING THEIR UNIQUE PATHOBIOLOGY AND CLINICAL FEATURES. IMPORTANTLY, MOLECULAR PROFILING IS BECOMING AN INTEGRAL TOOL UTILIZED IN ROUTINE CLINICAL PRACTICE. THIS REVIEW SUMMARIZES OUR CURRENT UNDERSTANDING OF THE MOLECULAR PATHOGENESIS OF OVERLAP SYNDROMES AND DETAILS THE IMPACT OF SOMATIC MUTATIONS IN DIAGNOSTIC, PROGNOSTIC, AND THERAPEUTIC DECISION-MAKING. 2020 11 3872 45 JUVENILE MYELOMONOCYTIC LEUKEMIA-A COMPREHENSIVE REVIEW AND RECENT ADVANCES IN MANAGEMENT. JUVENILE MYELOMONOCYTIC LEUKEMIA (JMML) IS A RARE PEDIATRIC MYELODYSPLASTIC/MYELOPROLIFERATIVE NEOPLASM OVERLAP DISEASE. JMML IS ASSOCIATED WITH MUTATIONS IN THE RAS PATHWAY GENES RESULTING IN THE MYELOID PROGENITORS BEING SENSITIVE TO GRANULOCYTE MONOCYTE COLONY-STIMULATING FACTOR (GM-CSF). KARYOTYPE ABNORMALITIES AND ADDITIONAL EPIGENETIC ALTERATIONS CAN ALSO BE FOUND IN JMML. NEUROFIBROMATOSIS AND NOONAN'S SYNDROME HAVE A PREDISPOSITION FOR JMML. IN A FEW PATIENTS, THE RAS GENES (NRAS, KRAS, AND PTPN11) ARE MUTATED AT THE GERMLINE AND THIS USUALLY RESULTS IN A TRANSIENT MYELOPROLIFERATIVE DISORDER WITH A GOOD PROGNOSIS. JMML WITH SOMATIC RAS MUTATION BEHAVES AGGRESSIVELY. JMML PRESENTS WITH CYTOPENIAS AND LEUKEMIC INFILTRATION INTO ORGANS. THE LABORATORY FINDINGS INCLUDE HYPERLEUKOCYTOSIS, MONOCYTOSIS, INCREASED HEMOGLOBIN-F LEVELS, AND CIRCULATING MYELOID PRECURSORS. THE BLAST CELLS IN THE PERIPHERAL BLOOD/BONE-MARROW ASPIRATE ARE LESS THAN 20% AND THE ABSENCE OF THE BCR-ABL TRANSLOCATION HELPS TO DIFFERENTIATE FROM CHRONIC MYELOID LEUKEMIA. JMML SHOULD BE DIFFERENTIATED FROM IMMUNODEFICIENCIES, VIRAL INFECTIONS, INTRAUTERINE INFECTIONS, HEMOPHAGOLYMPHOHISTIOCYTOSIS, OTHER MYELOPROLIFERATIVE DISORDERS, AND LEUKEMIAS. CHEMOTHERAPY IS EMPLOYED AS A BRIDGE TO HSCT, EXCEPT IN FEW WITH LESS AGGRESSIVE DISEASE, IN WHICH CHEMOTHERAPY ALONE CAN RESULT IN LONG TERM REMISSION. AZACITIDINE HAS SHOWN PROMISE AS A SINGLE AGENT TO STABILIZE THE DISEASE. THE PROGNOSIS OF JMML IS POOR WITH ABOUT 50% OF PATIENTS SURVIVING AFTER AN ALLOGENEIC HEMATOPOIETIC STEM CELL TRANSPLANT (HSCT). ALLOGENEIC HSCT IS THE ONLY KNOWN CURE FOR JMML TO DATE. MYELOABLATIVE CONDITIONING IS MOST COMMONLY USED WITH GRAFT VERSUS HOST DISEASE (GVHD) PROPHYLAXIS TAILORED TO THE AGGRESSIVENESS OF THE DISEASE. RELAPSES ARE COMMON EVEN AFTER HSCT AND A SECOND HSCT CAN SALVAGE A THIRD OF THESE PATIENTS. NOVEL OPTIONS IN THE TREATMENT OF JMML E.G., HYPOMETHYLATING AGENTS, MEK INHIBITORS, JAK INHIBITORS, TYROSINE KINASE INHIBITORS, ETC. ARE BEING EXPLORED. 2021 12 4565 29 MYELOID MALIGNANCIES: MUTATIONS, MODELS AND MANAGEMENT. MYELOID MALIGNANT DISEASES COMPRISE CHRONIC (INCLUDING MYELODYSPLASTIC SYNDROMES, MYELOPROLIFERATIVE NEOPLASMS AND CHRONIC MYELOMONOCYTIC LEUKEMIA) AND ACUTE (ACUTE MYELOID LEUKEMIA) STAGES. THEY ARE CLONAL DISEASES ARISING IN HEMATOPOIETIC STEM OR PROGENITOR CELLS. MUTATIONS RESPONSIBLE FOR THESE DISEASES OCCUR IN SEVERAL GENES WHOSE ENCODED PROTEINS BELONG PRINCIPALLY TO FIVE CLASSES: SIGNALING PATHWAYS PROTEINS (E.G. CBL, FLT3, JAK2, RAS), TRANSCRIPTION FACTORS (E.G. CEBPA, ETV6, RUNX1), EPIGENETIC REGULATORS (E.G. ASXL1, DNMT3A, EZH2, IDH1, IDH2, SUZ12, TET2, UTX), TUMOR SUPPRESSORS (E.G. TP53), AND COMPONENTS OF THE SPLICEOSOME (E.G. SF3B1, SRSF2). LARGE-SCALE SEQUENCING EFFORTS WILL SOON LEAD TO THE ESTABLISHMENT OF A COMPREHENSIVE REPERTOIRE OF THESE MUTATIONS, ALLOWING FOR A BETTER DEFINITION AND CLASSIFICATION OF MYELOID MALIGNANCIES, THE IDENTIFICATION OF NEW PROGNOSTIC MARKERS AND THERAPEUTIC TARGETS, AND THE DEVELOPMENT OF NOVEL THERAPIES. GIVEN THE IMPORTANCE OF EPIGENETIC DEREGULATION IN MYELOID DISEASES, THE USE OF DRUGS TARGETING EPIGENETIC REGULATORS APPEARS AS A MOST PROMISING THERAPEUTIC APPROACH. 2012 13 4748 31 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 14 4471 29 MOLECULAR PATHOGENESIS OF ATYPICAL CML, CMML AND MDS/MPN-UNCLASSIFIABLE. ACCORDING TO THE 2008 WHO CLASSIFICATION, THE CATEGORY OF MYELODYSPLASTIC/MYELOPROLIFERATIVE NEOPLASMS (MDS/MPN) INCLUDES ATYPICAL CHRONIC MYELOID LEUKAEMIA (ACML), CHRONIC MYELOMONOCYTIC LEUKAEMIA (CMML), MDS/MPN-UNCLASSIFIABLE (MDS/MPN-U), JUVENILE MYELOMONOCYTIC LEUKAEMIA (JMML) AND A "PROVISIONAL" ENTITY, REFRACTORY ANAEMIA WITH RING SIDEROBLASTS AND THROMBOCYTOSIS (RARS-T). THE REMARKABLE PROGRESS IN OUR UNDERSTANDING OF THE SOMATIC PATHOGENESIS OF MDS/MPN HAS MADE IT CLEAR THAT THERE IS CONSIDERABLE OVERLAP AMONG THESE DISEASES AT THE MOLECULAR LEVEL, AS WELL AS LAYERS OF UNEXPECTED COMPLEXITY. DEREGULATION OF SIGNALLING PLAYS AN IMPORTANT ROLE IN MANY CASES, AND IS CLEARLY LINKED TO MORE HIGHLY PROLIFERATIVE DISEASE. OTHER MUTATIONS AFFECT A RANGE OF OTHER ESSENTIAL, INTERRELATED CELLULAR MECHANISMS, INCLUDING EPIGENETIC REGULATION, RNA SPLICING, TRANSCRIPTION, AND DNA DAMAGE RESPONSE. THE VARIOUS COMBINATIONS OF MUTATIONS INDICATE A MULTI-STEP PATHOGENESIS, WHICH LIKELY CONTRIBUTES TO THE MARKED CLINICAL HETEROGENEITY OF THESE DISORDERS. THE DELINEATION OF COMPLEX CLONAL ARCHITECTURES MAY SERVE AS THE CORNERSTONE FOR THE IDENTIFICATION OF NOVEL THERAPEUTIC TARGETS AND LEAD TO BETTER PATIENT OUTCOMES. THIS REVIEW SUMMARIZES SOME OF THE CURRENT KNOWLEDGE OF MOLECULAR PATHOGENETIC LESIONS IN THE MDS/MPN SUBTYPES THAT ARE SEEN IN ADULTS: ATYPICAL CML, CMML AND MDS/MPN-U. 2015 15 3819 17 INTRINSIC MUTAGENIC PROPERTIES OF 5-CHLOROCYTOSINE: A MECHANISTIC CONNECTION BETWEEN CHRONIC INFLAMMATION AND CANCER. DURING CHRONIC INFLAMMATION, NEUTROPHIL-SECRETED HYPOCHLOROUS ACID CAN DAMAGE NEARBY CELLS INDUCING THE GENOMIC ACCUMULATION OF 5-CHLOROCYTOSINE (5CLC), A KNOWN INFLAMMATION BIOMARKER. ALTHOUGH 5CLC HAS BEEN SHOWN TO PROMOTE EPIGENETIC CHANGES, IT HAS BEEN UNKNOWN HERETOFORE IF 5CLC DIRECTLY PERPETRATES A MUTAGENIC OUTCOME WITHIN THE CELL. THE PRESENT WORK SHOWS THAT 5CLC IS INTRINSICALLY MUTAGENIC, BOTH IN VITRO AND, AT A LEVEL OF A SINGLE MOLECULE PER CELL, IN VIVO. USING BIOCHEMICAL AND GENETIC APPROACHES, WE HAVE QUANTIFIED THE MUTAGENIC AND TOXIC PROPERTIES OF 5CLC, SHOWING THAT THIS LESION CAUSED C-->T TRANSITIONS AT FREQUENCIES RANGING FROM 3-9% DEPENDING ON THE POLYMERASE TRAVERSING THE LESION. X-RAY CRYSTALLOGRAPHIC STUDIES PROVIDED A MOLECULAR BASIS FOR THE MUTAGENICITY OF 5CLC; A SNAPSHOT OF HUMAN POLYMERASE BETA REPLICATING ACROSS A PRIMED 5CLC-CONTAINING TEMPLATE UNCOVERED 5CLC ENGAGED IN A NASCENT BASE PAIR WITH AN INCOMING DATP ANALOG. ACCOMMODATION OF THE CHLORINE SUBSTITUENT IN THE TEMPLATE MAJOR GROOVE ENABLED A UNIQUE INTERACTION BETWEEN 5CLC AND THE INCOMING DATP, WHICH WOULD FACILITATE MUTAGENIC LESION BYPASS. THE TYPE OF MUTATION INDUCED BY 5CLC, THE C-->T TRANSITION, HAS BEEN PREVIOUSLY SHOWN TO OCCUR IN SUBSTANTIAL AMOUNTS BOTH IN TISSUES UNDER INFLAMMATORY STRESS AND IN THE GENOMES OF MANY INFLAMMATION-ASSOCIATED CANCERS. IN FACT, MANY SEQUENCE-SPECIFIC MUTATIONAL SIGNATURES UNCOVERED IN SEQUENCED CANCER GENOMES FEATURE C-->T MUTATIONS. THEREFORE, THE MUTAGENIC ABILITY OF 5CLC DOCUMENTED IN THE PRESENT STUDY MAY CONSTITUTE A DIRECT FUNCTIONAL LINK BETWEEN CHRONIC INFLAMMATION AND THE GENETIC CHANGES THAT ENABLE AND PROMOTE MALIGNANT TRANSFORMATION. 2015 16 2956 37 GENETIC AND EPIGENETIC FACTORS INTERACTING WITH CLONAL HEMATOPOIESIS RESULTING IN CHRONIC MYELOMONOCYTIC LEUKEMIA. PURPOSE OF REVIEW: SINCE 2016, THE WHO HAS RECOGNIZED THE SIGNIFICANT PHENOTYPIC HETEROGENEITY OF CHRONIC MYELOMONOCYTIC LEUKEMIA (CMML) AS A MYELODYSPLASTIC SYNDROME/MYELOPROLIFERATIVE NEOPLASM (MDS/MPN) OVERLAP DISEASE. ALTHOUGH SHARING MANY SOMATIC MUTATIONS WITH MDS AND MPN, THE PURPOSE OF THIS REVIEW IS TO PUT RECENT BIOLOGICAL FINDINGS OF CMML IN THE CONTEXT OF EVOLUTIONARY THEORY, HIGHLIGHTING IT AS A DISTINCT EVOLUTIONARY TRAJECTORY OCCURRING IN THE CONTEXT OF CLONAL HEMATOPOIESIS. RECENT FINDINGS: CLONAL HEMATOPOIESIS OF INDETERMINATE POTENTIAL (CHIP), WITH A MUTATIONAL SPECTRUM AND PREVALENCE CORRELATED WITH AGE, HAS BEEN DEFINED. ENRICHED IN DNMT3A, TET2, AND ASXL1 MUTATIONS, CLONAL EVOLUTION CAN PROGRESS INTO VARIOUS EVOLUTIONARY TRAJECTORIES INCLUDING CMML. IMPACT OF FOUNDER MUTATIONS (PRIMARILY TET2) ON INCREASED HEMATOPOIETIC STEM CELL FITNESS HAS BEEN WELL CHARACTERIZED. EPISTATIC INTERACTIONS BETWEEN MUTATIONS AND EPIGENETIC EVENTS HAVE BEEN EXPLORED, BOTH IN CMML AND ITS PEDIATRIC COUNTERPART JUVENILE MYELOMONOCYTIC LEUKEMIA, INCLUDING CMML TRANSFORMATION TO ACUTE MYELOID LEUKEMIA. TOGETHER, THESE FINDINGS HAVE CONTRIBUTED SIGNIFICANTLY TOWARD CMML EVOLUTIONARY DYNAMICS. SUMMARY: DESPITE RELATIVELY FEW 'DRIVER' MUTATIONS IN CMML, EVOLUTIONARY DEVELOPMENT OF CHRONIC LEUKEMIA REMAINS INCOMPLETELY UNDERSTOOD. RECENT STUDIES HAVE SHED LIGHT ON THE IMPORTANCE OF STUDYING EPIGENETIC CONSEQUENCES OF MUTATIONS AND EPISTASIS BETWEEN KEY MUTATIONS TO BETTER UNDERSTAND CLONAL ARCHITECTURE AND EVOLUTIONARY DYNAMICS. 2020 17 961 37 CHRONIC MYELOMONOCYTIC LEUKEMIA: A GENETIC AND CLINICAL UPDATE. CHRONIC MYELOMONOCYTIC LEUKEMIA (CMML) IS A CLONAL STEM CELL DISORDER, CHARACTERIZED BY PERIPHERAL BLOOD MONOCYTOSIS AND OVERLAPPING FEATURES BETWEEN MYELODYSPLASTIC SYNDROMES (MDS) AND MYELOPROLIFERATIVE NEOPLASMS (MPNS). CLONAL CYTOGENETIC CHANGES ARE SEEN IN UP TO 30 % PATIENTS, WHILE APPROXIMATELY 90 % HAVE DETECTABLE MOLECULAR ABNORMALITIES. MOST PATIENTS ARE DIAGNOSED IN THE SEVENTH DECADE OF LIFE. GENE MUTATIONS IN TEN-ELEVEN TRANSLOCATION (TET) ONCOGENE FAMILY MEMBER 2 (TET2) (60 %), SRSF2 (50 %), ASXL1 (40 %), AND RAS (20-30 %) ARE FREQUENT, WITH ONLY FRAME SHIFT AND NONSENSE ASXL1 MUTATIONS NEGATIVELY IMPACTING OVERALL SURVIVAL. WITH THE LACK OF FORMAL GUIDELINES, MANAGEMENT AND RESPONSE CRITERIA ARE OFTEN EXTRAPOLATED FROM MDS AND MPN. CONTEMPORARY MOLECULARLY INTEGRATED CMML-SPECIFIC PROGNOSTIC MODELS INCLUDE THE GROUPE FRANCAIS DES MYELODYSPLASIES (GFM) MODEL AND THE MOLECULAR MAYO MODEL, BOTH INCORPORATING ASXL1 MUTATIONAL STATUS. HYPOMETHYLATING AGENTS AND ALLOGENEIC STEM CELL TRANSPLANT REMAIN THE TWO MOST COMMONLY USED TREATMENT STRATEGIES, WITH SUBOPTIMAL RESULTS. CLINICAL TRIALS EXPLOITING EPIGENETIC AND SIGNAL PATHWAY ABNORMALITIES, FREQUENT IN CMML, OFFER HOPE AND PROMISE. 2015 18 2277 27 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 19 4838 23 ONCOGENIC N-RAS AND TET2 HAPLOINSUFFICIENCY COLLABORATE TO DYSREGULATE HEMATOPOIETIC STEM AND PROGENITOR CELLS. CONCURRENT GENETIC LESIONS EXIST IN A MAJORITY OF PATIENTS WITH HEMATOLOGIC MALIGNANCIES. AMONG THESE, SOMATIC MUTATIONS THAT ACTIVATE RAS ONCOGENES AND INACTIVATE THE EPIGENETIC MODIFIER TEN-ELEVEN TRANSLOCATION 2 (TET2) FREQUENTLY CO-OCCUR IN HUMAN CHRONIC MYELOMONOCYTIC LEUKEMIAS (CMMLS) AND ACUTE MYELOID LEUKEMIAS, SUGGESTING A COOPERATIVITY IN MALIGNANT TRANSFORMATION. TO TEST THIS, WE APPLIED A CONDITIONAL MURINE MODEL THAT ENDOGENOUSLY EXPRESSED ONCOGENIC NRAS(G12D) AND MONOALLELIC LOSS OF TET2 AND EXPLORED THE COLLABORATIVE ROLE SPECIFICALLY WITHIN HEMATOPOIETIC STEM AND PROGENITOR CELLS (HSPCS) AT DISEASE INITIATION. WE DEMONSTRATE THAT THE 2 MUTATIONS COLLABORATED TO ACCELERATE A TRANSPLANTABLE CMML-LIKE DISEASE IN VIVO, WITH AN OVERALL SHORTENED SURVIVAL AND INCREASED DISEASE PENETRANCE COMPARED WITH SINGLE MUTANTS. AT PRELEUKEMIC STAGE, N-RAS(G12D) AND TET2 HAPLOINSUFFICIENCY TOGETHER INDUCED BALANCED HEMATOPOIETIC STEM CELL (HSC) PROLIFERATION AND ENHANCED COMPETITIVENESS. NRAS(G12D/+)/TET2(+/-) HSCS DISPLAYED INCREASED SELF-RENEWAL IN PRIMARY AND SECONDARY TRANSPLANTATIONS, WITH SIGNIFICANTLY HIGHER RECONSTITUTION THAN SINGLE MUTANTS. STRIKINGLY, THE 2 MUTATIONS TOGETHER CONFERRED LONG-TERM RECONSTITUTION AND SELF-RENEWAL POTENTIAL TO MULTIPOTENT PROGENITORS, A POOL OF CELLS THAT USUALLY HAVE LIMITED SELF-RENEWAL COMPARED WITH HSCS. MOREOVER, HSPCS FROM NRAS(G12D/+)/TET2(+/-) MICE DISPLAYED INCREASED CYTOKINE SENSITIVITY IN RESPONSE TO THROMBOPOIETIN. THEREFORE, OUR STUDIES ESTABLISH A NOVEL TRACTABLE CMML MODEL AND PROVIDE INSIGHTS INTO HOW DYSREGULATED SIGNALING PATHWAYS AND EPIGENETIC MODIFIERS COLLABORATE TO MODULATE HSPC FUNCTION AND PROMOTE LEUKEMOGENESIS. 2018 20 5789 33 SRSF2(P95H/+) CO-OPERATES WITH LOSS OF TET2 TO PROMOTE MYELOID BIAS AND INITIATE A CHRONIC MYELOMONOCYTIC LEUKEMIA-LIKE DISEASE IN MICE. RECURRENT MUTATIONS IN RNA SPLICING PROTEINS AND EPIGENETIC REGULATORS CONTRIBUTE TO THE DEVELOPMENT OF MYELODYSPLASTIC SYNDROME (MDS) AND RELATED MYELOID NEOPLASMS. IN CHRONIC MYELOMONOCYTIC LEUKEMIA (CMML), SRSF2 MUTATIONS OCCUR IN ~50% OF PATIENTS AND TET2 MUTATIONS IN ~60%. CLONAL ANALYSIS INDICATES THAT EITHER MUTATION CAN ARISE AS THE FOUNDER LESION. BASED ON HUMAN CANCER GENETICS WE CROSSED AN INDUCIBLE SRSF2(P95H/+) MUTANT MODEL WITH TET2(FL/FL) MICE TO MUTATE BOTH CONCOMITANTLY IN HEMATOPOIETIC STEM CELLS. AT 20-24 WEEKS POST MUTATION INDUCTION, WE OBSERVED SUBTLE DIFFERENCES IN THE SRSF2/TET2 MUTANTS COMPARED TO EITHER SINGLE MUTANT. UNDER CONDITIONS OF NATIVE HEMATOPOIESIS WITH AGING, WE SEE A DISTINCT MYELOID BIAS AND MONOCYTOSIS IN THE SRSF2/TET2 MUTANTS. A SUBSET OF THE COMPOUND SRSF2/TET2 MUTANTS DISPLAY AN INCREASED GRANULOCYTIC AND DISTINCTIVE MONOCYTIC PROLIFERATION (MYELOMONOCYTIC HYPERPLASIA), WITH INCREASED IMMATURE PROMONOCYTES AND MONOBLASTS AND BINUCLEATE PROMONOCYTES. EXOME ANALYSIS OF PROGRESSED DISEASE DEMONSTRATED MUTATIONS IN GENES AND PATHWAYS SIMILAR TO THOSE REPORTED IN HUMAN CMML. UPON TRANSPLANTATION, RECIPIENTS DEVELOPED LEUKOCYTOSIS, MONOCYTOSIS, AND SPLENOMEGALY. WE REPRODUCE SRSF2/TET2 CO-OPERATIVITY IN VIVO, YIELDING A DISEASE WITH CORE CHARACTERISTICS OF CMML, UNLIKE SINGLE SRSF2 OR TET2 MUTATION. THIS MODEL REPRESENTS A SIGNIFICANT STEP TOWARD BUILDING HIGH FIDELITY AND GENETICALLY TRACTABLE MODELS OF CMML. 2022