1 5405 135 REGULATED EXPRESSION OF P210 BCR-ABL DURING EMBRYONIC STEM CELL DIFFERENTIATION STIMULATES MULTIPOTENTIAL PROGENITOR EXPANSION AND MYELOID CELL FATE. P210 BCR-ABL IS AN ACTIVATED TYROSINE KINASE ONCOGENE ENCODED BY THE PHILADELPHIA CHROMOSOME ASSOCIATED WITH HUMAN CHRONIC MYELOGENOUS LEUKEMIA (CML). THE DISEASE REPRESENTS A CLONAL DISORDER ARISING IN THE PLURIPOTENT HEMATOPOIETIC STEM CELL. DURING THE CHRONIC PHASE, PATIENTS PRESENT WITH A DRAMATIC EXPANSION OF MYELOID CELLS AND A MILD ANEMIA. RETROVIRAL GENE TRANSFER AND TRANSGENIC EXPRESSION IN RODENTS HAVE DEMONSTRATED THE ABILITY OF BCR-ABL TO INDUCE VARIOUS TYPES OF LEUKEMIA. HOWEVER, STUDY OF HUMAN CML OR RODENT MODELS HAS NOT DETERMINED THE DIRECT AND IMMEDIATE EFFECTS OF BCR-ABL ON HEMATOPOIETIC CELLS FROM THOSE REQUIRING SECONDARY GENETIC OR EPIGENETIC CHANGES SELECTED DURING THE PATHOGENIC PROCESS. WE UTILIZED TETRACYCLINE-REGULATED EXPRESSION OF BCR-ABL FROM A PROMOTER ENGINEERED FOR ROBUST EXPRESSION IN PRIMITIVE STEM CELLS THROUGH MULTILINEAGE BLOOD CELL DEVELOPMENT IN COMBINATION WITH THE IN VITRO DIFFERENTIATION OF EMBRYONAL STEM CELLS INTO HEMATOPOIETIC ELEMENTS. OUR RESULTS DEMONSTRATE THAT BCR-ABL EXPRESSION ALONE IS SUFFICIENT TO INCREASE THE NUMBER OF MULTIPOTENT AND MYELOID LINEAGE COMMITTED PROGENITORS IN A DOSE-DEPENDENT MANNER WHILE SUPPRESSING THE DEVELOPMENT OF COMMITTED ERYTHROID PROGENITORS. THESE EFFECTS ARE REVERSIBLE UPON EXTINGUISHING BCR-ABL EXPRESSION. THESE FINDINGS ARE CONSISTENT WITH BCR-ABL BEING THE SOLE GENETIC CHANGE NEEDED FOR THE ESTABLISHMENT OF THE CHRONIC PHASE OF CML AND PROVIDE A POWERFUL SYSTEM FOR THE ANALYSIS OF ANY GENETIC CHANGE THAT ALTERS CELL GROWTH AND LINEAGE CHOICES OF THE HEMATOPOIETIC STEM CELL. 2000 2 3234 41 HEMATOPOIETIC AND CHRONIC MYELOID LEUKEMIA STEM CELLS: MULTI-STABILITY VERSUS LINEAGE RESTRICTION. THERE IS COMPELLING EVIDENCE TO SUPPORT THE VIEW THAT THE CELL-OF-ORIGIN FOR CHRONIC MYELOID LEUKEMIA IS A HEMATOPOIETIC STEM CELL. UNLIKE NORMAL HEMATOPOIETIC STEM CELLS, THE PROGENY OF THE LEUKEMIA STEM CELLS ARE PREDOMINANTLY NEUTROPHILS DURING THE DISEASE CHRONIC PHASE AND THERE IS A MILD ANEMIA. THE HALLMARK ONCOGENE FOR CHRONIC MYELOID LEUKEMIA IS THE BCR-ABLP210 FUSION GENE. VARIOUS STUDIES HAVE EXCLUDED A ROLE FOR BCR-ABLP210 EXPRESSION IN MAINTAINING THE POPULATION OF LEUKEMIA STEM CELLS. STUDIES OF BCR-ABLP210 EXPRESSION IN EMBRYONAL STEM CELLS THAT WERE DIFFERENTIATED INTO HEMATOPOIETIC STEM CELLS AND OF THE EXPRESSION IN TRANSGENIC MICE HAVE REVEALED THAT BCR-ABLP210 IS ABLE TO VEER HEMATOPOIETIC STEM AND PROGENITOR CELLS TOWARDS A MYELOID FATE. FOR THE TRANSGENIC MICE, GLOBAL CHANGES TO THE EPIGENETIC LANDSCAPE WERE OBSERVED. IN CHRONIC MYELOID LEUKEMIA, THE ABILITY OF THE LEUKEMIA STEM CELLS TO CHOOSE FROM THE MANY FATES THAT ARE AVAILABLE TO NORMAL HEMATOPOIETIC STEM CELLS APPEARS TO BE DEREGULATED BY BCR-ABLP210 AND CHANGES TO THE EPIGENOME ARE ALSO IMPORTANT. EVEN SO, WE STILL DO NOT HAVE A PRECISE PICTURE AS TO WHY NEUTROPHILS ARE ABUNDANTLY PRODUCED IN CHRONIC MYELOID LEUKEMIA. 2022 3 5965 35 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 4 559 28 BACH2 ENFORCES THE TRANSCRIPTIONAL AND EPIGENETIC PROGRAMS OF STEM-LIKE CD8(+) T CELLS. DURING CHRONIC INFECTION AND CANCER, A SELF-RENEWING CD8(+) T CELL SUBSET MAINTAINS LONG-TERM IMMUNITY AND IS CRITICAL TO THE EFFECTIVENESS OF IMMUNOTHERAPY. THESE STEM-LIKE CD8(+) T CELLS DIVERGE FROM OTHER CD8(+) SUBSETS EARLY AFTER CHRONIC VIRAL INFECTION. HOWEVER, PATHWAYS GUARDING STEM-LIKE CD8(+) T CELLS AGAINST TERMINAL EXHAUSTION REMAIN UNCLEAR. HERE, WE SHOW THAT THE GENE ENCODING TRANSCRIPTIONAL REPRESSOR BACH2 IS TRANSCRIPTIONALLY AND EPIGENETICALLY ACTIVE IN STEM-LIKE CD8(+) T CELLS BUT NOT TERMINALLY EXHAUSTED CELLS EARLY AFTER INFECTION. BACH2 OVEREXPRESSION ENFORCED STEM-LIKE CELL FATE, WHEREAS BACH2 DEFICIENCY IMPAIRED STEM-LIKE CD8(+) T CELL DIFFERENTIATION. SINGLE-CELL TRANSCRIPTOMIC AND EPIGENOMIC APPROACHES REVEALED THAT BACH2 ESTABLISHED THE TRANSCRIPTIONAL AND EPIGENETIC PROGRAMS OF STEM-LIKE CD8(+) T CELLS. IN ADDITION, BACH2 SUPPRESSED THE MOLECULAR PROGRAM DRIVING TERMINAL EXHAUSTION THROUGH TRANSCRIPTIONAL REPRESSION AND EPIGENETIC SILENCING. THUS, OUR STUDY REVEALS A NEW PATHWAY THAT ENFORCES COMMITMENT TO STEM-LIKE CD8(+) LINEAGE AND PREVENTS AN ALTERNATIVE TERMINALLY EXHAUSTED CELL FATE. 2021 5 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 6 1092 33 COHESIN MUTATIONS IN MYELOID MALIGNANCIES. COHESIN IS A MULTISUBUNIT PROTEIN COMPLEX THAT FORMS A RING-LIKE STRUCTURE AROUND DNA. IT IS ESSENTIAL FOR SISTER CHROMATID COHESION, CHROMATIN ORGANIZATION, TRANSCRIPTIONAL REGULATION, AND DNA DAMAGE REPAIR AND PLAYS A MAJOR ROLE IN DYNAMICALLY SHAPING THE GENOME ARCHITECTURE AND MAINTAINING DNA INTEGRITY. THE CORE COMPLEX SUBUNITS STAG2, RAD21, SMC1, AND SMC3, AS WELL AS ITS MODULATORS PDS5A/B, WAPL, AND NIPBL, HAVE BEEN FOUND TO BE RECURRENTLY MUTATED IN HEMATOLOGIC AND SOLID MALIGNANCIES. THESE MUTATIONS ARE FOUND ACROSS THE FULL SPECTRUM OF MYELOID NEOPLASIA, INCLUDING PEDIATRIC DOWN SYNDROME-ASSOCIATED ACUTE MEGAKARYOBLASTIC LEUKEMIA, MYELODYSPLASTIC SYNDROMES, CHRONIC MYELOMONOCYTIC LEUKEMIA, AND DE NOVO AND SECONDARY ACUTE MYELOID LEUKEMIAS. THE MECHANISMS BY WHICH COHESIN MUTATIONS ACT AS DRIVERS OF CLONAL EXPANSION AND DISEASE PROGRESSION ARE STILL POORLY UNDERSTOOD. RECENT STUDIES HAVE DESCRIBED THE IMPACT OF COHESIN ALTERATIONS ON SELF-RENEWAL AND DIFFERENTIATION OF HEMATOPOIETIC STEM AND PROGENITOR CELLS, WHICH ARE ASSOCIATED WITH CHANGES IN CHROMATIN AND EPIGENETIC STATE DIRECTING LINEAGE COMMITMENT, AS WELL AS GENOMIC INTEGRITY. HEREIN, WE REVIEW THE ROLE OF THE COHESIN COMPLEX IN HEALTHY AND MALIGNANT HEMATOPOIESIS. WE DISCUSS CLINICAL IMPLICATIONS OF COHESIN MUTATIONS IN MYELOID MALIGNANCIES AND DISCUSS OPPORTUNITIES FOR THERAPEUTIC TARGETING. 2021 7 952 31 CHRONIC MYELOID LEUKEMIA STEM CELL BIOLOGY. LEUKEMIA PROGRESSION AND RELAPSE IS FUELED BY LEUKEMIA STEM CELLS (LSC) THAT ARE RESISTANT TO CURRENT TREATMENTS. IN THE PROGRESSION OF CHRONIC MYELOID LEUKEMIA (CML), BLAST CRISIS PROGENITORS ARE CAPABLE OF ADOPTING MORE PRIMITIVE BUT DEREGULATED STEM CELL FEATURES WITH ACQUIRED RESISTANCE TO TARGETED THERAPIES. THIS IN TURN PROMOTES LSC BEHAVIOR CHARACTERIZED BY ABERRANT SELF-RENEWAL, DIFFERENTIATION, AND SURVIVAL CAPACITY. MULTIPLE REPORTS SUGGEST THAT CELL CYCLE ALTERATIONS, ACTIVATION OF CRITICAL SIGNALING PATHWAYS, ABERRANT MICROENVIRONMENTAL CUES FROM THE HEMATOPOIETIC NICHE, AND ABERRANT EPIGENETIC EVENTS AND DEREGULATION OF RNA PROCESSING MAY FACILITATE THE ENHANCED SURVIVAL AND MALIGNANT TRANSFORMATION OF CML PROGENITORS. HERE WE REVIEW THE MOLECULAR EVOLUTION OF CML LSC THAT PROMOTES CML PROGRESSION AND RELAPSE. RECENT ADVANCES IN THESE AREAS HAVE IDENTIFIED NOVEL TARGETS THAT REPRESENT IMPORTANT AVENUES FOR FUTURE THERAPEUTIC APPROACHES AIMED AT SELECTIVELY ERADICATING THE LSC POPULATION WHILE SPARING NORMAL HEMATOPOIETIC PROGENITORS IN PATIENTS SUFFERING FROM CHRONIC MYELOID MALIGNANCIES. 2012 8 1359 39 DEVELOPMENT REFRACTORINESS OF MLL-REARRANGED HUMAN B CELL ACUTE LEUKEMIAS TO REPROGRAMMING INTO PLURIPOTENCY. INDUCED PLURIPOTENT STEM CELLS (IPSCS) ARE A POWERFUL TOOL FOR DISEASE MODELING. THEY ARE ROUTINELY GENERATED FROM HEALTHY DONORS AND PATIENTS FROM MULTIPLE CELL TYPES AT DIFFERENT DEVELOPMENTAL STAGES. HOWEVER, REPROGRAMMING LEUKEMIAS IS AN EXTREMELY INEFFICIENT PROCESS. FEW STUDIES GENERATED IPSCS FROM PRIMARY CHRONIC MYELOID LEUKEMIAS, BUT IPSC GENERATION FROM ACUTE MYELOID OR LYMPHOID LEUKEMIAS (ALL) HAS NOT BEEN ACHIEVED. WE ATTEMPTED TO GENERATE IPSCS FROM DIFFERENT SUBTYPES OF B-ALL TO ADDRESS THE DEVELOPMENTAL IMPACT OF LEUKEMIC FUSION GENES. OKSM(L)-EXPRESSING MONO/POLYCISTRONIC-, RETROVIRAL/LENTIVIRAL/EPISOMAL-, AND SENDAI VIRUS VECTOR-BASED REPROGRAMMING STRATEGIES FAILED TO RENDER IPSCS IN VITRO AND IN VIVO. ADDITION OF TRANSCRIPTOMIC-EPIGENETIC REPROGRAMMING "BOOSTERS" ALSO FAILED TO GENERATE IPSCS FROM B CELL BLASTS AND B-ALL LINES, AND WHEN IPSCS EMERGED THEY LACKED LEUKEMIC FUSION GENES, DEMONSTRATING NON-LEUKEMIC MYELOID ORIGIN. CONVERSELY, MLL-AF4-OVEREXPRESSING HEMATOPOIETIC STEM CELLS/B PROGENITORS WERE SUCCESSFULLY REPROGRAMMED, INDICATING THAT B CELL ORIGIN AND LEUKEMIC FUSION GENE WERE NOT REPROGRAMMING BARRIERS. GLOBAL TRANSCRIPTOME/DNA METHYLOME PROFILING SUGGESTED A DEVELOPMENTAL/DIFFERENTIATION REFRACTORINESS OF MLL-REARRANGED B-ALL TO REPROGRAMMING INTO PLURIPOTENCY. 2016 9 4838 36 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 10 2928 33 GENERATION OF IPSCS FROM CULTURED HUMAN MALIGNANT CELLS. INDUCED PLURIPOTENT STEM CELLS (IPSCS) CAN BE GENERATED FROM VARIOUS DIFFERENTIATED CELL TYPES BY THE EXPRESSION OF A SET OF DEFINED TRANSCRIPTION FACTORS. SO FAR, IPSCS HAVE BEEN GENERATED FROM PRIMARY CELLS, BUT IT IS UNCLEAR WHETHER HUMAN CANCER CELL LINES CAN BE REPROGRAMMED. HERE WE DESCRIBE THE GENERATION AND CHARACTERIZATION OF IPSCS DERIVED FROM HUMAN CHRONIC MYELOID LEUKEMIA CELLS. WE SHOW THAT, DESPITE THE PRESENCE OF ONCOGENIC MUTATIONS, THESE CELLS ACQUIRED PLURIPOTENCY BY THE EXPRESSION OF 4 TRANSCRIPTION FACTORS AND UNDERWENT DIFFERENTIATION INTO CELL TYPES DERIVED OF ALL 3 GERM LAYERS DURING TERATOMA FORMATION. INTERESTINGLY, ALTHOUGH THE PARENTAL CELL LINE WAS STRICTLY DEPENDENT ON CONTINUOUS SIGNALING OF THE BCR-ABL ONCOGENE, ALSO TERMED ONCOGENE ADDICTION, REPROGRAMMED CELLS LOST THIS DEPENDENCY AND BECAME RESISTANT TO THE BCR-ABL INHIBITOR IMATINIB. THIS FINDING INDICATES THAT THE THERAPEUTIC AGENT IMATINIB TARGETS CELLS IN A SPECIFIC EPIGENETIC DIFFERENTIATED CELL STATE, AND THIS MAY CONTRIBUTE TO ITS INABILITY TO FULLY ERADICATE DISEASE IN CHRONIC MYELOID LEUKEMIA PATIENTS. 2010 11 2072 31 EPIGENETIC CONVERSION OF HUMAN ADULT BONE MESODERMAL STROMAL CELLS INTO NEUROECTODERMAL CELL TYPES FOR REPLACEMENT THERAPY OF NEURODEGENERATIVE DISORDERS. TISSUE-SPECIFIC STEM CELLS, SUCH AS BONE MARROW-DERIVED MESODERMAL STROMAL CELLS (MSCS), ARE THOUGHT TO BE LINEAGE RESTRICTED AND, THEREFORE, COULD ONLY BE DIFFERENTIATED INTO CELL TYPES OF THE TISSUE OF ORIGIN. SEVERAL RECENT STUDIES, HOWEVER, SUGGEST THAT THESE TYPES OF STEM CELLS MIGHT BE ABLE TO BREAK BARRIERS OF GERM LAYER COMMITMENT AND DIFFERENTIATE IN VITRO AND/OR IN VIVO INTO CELLS OF DIFFERENT TISSUES, SUCH AS NEUROECTODERMAL CELL TYPES. RECENTLY, PROTOCOLS FOR HIGH-YIELD GENERATION OF UNDIFFERENTIATED NEURAL STEM CELL (NSC)-LIKE CELLS FROM MSCS OF PRIMATE AND HUMAN ORIGIN WERE REPORTED. UNDIFFERENTIATED NSCS ARE COMMONLY USED AND ARE MORE SUITABLE FOR NEUROTRANSPLANTATION COMPARED WITH FULLY DIFFERENTIATED NEURAL CELLS, AS DIFFERENTIATED NEURAL CELLS ARE WELL KNOWN TO POORLY SURVIVE DETACHMENT AND SUBSEQUENT TRANSPLANTATION PROCEDURES. THESE HUMAN MSC-DERIVED NSC-LIKE CELLS (MSC-NSCS) GROW IN NEUROSPHERE-LIKE STRUCTURES AND EXPRESS HIGH LEVELS OF EARLY NEUROECTODERMAL MARKERS, BUT LOSE CHARACTERISTICS OF MSCS. IN THE PRESENCE OF SELECTED GROWTH FACTORS, HUMAN MSC-NSCS CAN BE DIFFERENTIATED INTO THE THREE MAIN NEURAL PHENOTYPES: ASTROGLIA, OLIGODENDROGLIA AND NEURONS. COMPARED WITH DIRECT DIFFERENTIATION OF HUMAN MSCS INTO MATURE NEURAL CELLS, THE CONVERSION STEP SEEMS TO BE ESSENTIAL TO GENERATE MATURE FUNCTIONAL NEUROECTODERMAL CELLS. THIS REVIEW DESCRIBES THE TECHNIQUES FOR THE CONVERSION OF HUMAN MSCS INTO NSCS AND SUMMARISES THE DATA ON EPIGENETIC CONVERSION OF HUMAN MSCS INTO IMMATURE NEUROECTODERMAL CELLS. THESE CELLS PROVIDE A POWERFUL TOOL FOR INVESTIGATING THE MOLECULAR MECHANISMS OF NEURAL DIFFERENTIATION, AND MIGHT SERVE AS AN AUTOLOGOUS CELL SOURCE TO TREAT ACUTE AND CHRONIC NEURODEGENERATIVE DISEASES. 2006 12 5320 33 PU.1 IS REQUIRED TO RESTRAIN MYELOPOIESIS DURING CHRONIC INFLAMMATORY STRESS. CHRONIC INFLAMMATION IS A COMMON FEATURE OF AGING AND NUMEROUS DISEASES SUCH AS DIABETES, OBESITY, AND AUTOIMMUNE SYNDROMES AND HAS BEEN LINKED TO THE DEVELOPMENT OF HEMATOLOGICAL MALIGNANCY. BLOOD-FORMING HEMATOPOIETIC STEM CELLS (HSC) CAN CONTRIBUTE TO THESE DISEASES VIA THE PRODUCTION OF TISSUE-DAMAGING MYELOID CELLS AND/OR THE ACQUISITION OF MUTATIONS IN EPIGENETIC AND TRANSCRIPTIONAL REGULATORS THAT INITIATE EVOLUTION TOWARD LEUKEMOGENESIS. WE PREVIOUSLY SHOWED THAT THE MYELOID "MASTER REGULATOR" TRANSCRIPTION FACTOR PU.1 IS ROBUSTLY INDUCED IN HSC BY PRO-INFLAMMATORY CYTOKINES SUCH AS INTERLEUKIN (IL)-1BETA AND LIMITS THEIR PROLIFERATIVE ACTIVITY. HERE, WE USED A PU.1-DEFICIENT MOUSE MODEL TO INVESTIGATE THE BROADER ROLE OF PU.1 IN REGULATING HEMATOPOIETIC ACTIVITY IN RESPONSE TO CHRONIC INFLAMMATORY CHALLENGES. WE FOUND THAT PU.1 IS CRITICAL IN RESTRAINING INFLAMMATORY MYELOPOIESIS VIA SUPPRESSION OF CELL CYCLE AND SELF-RENEWAL GENE PROGRAMS IN MYELOID-BIASED MULTIPOTENT PROGENITOR (MPP) CELLS. OUR DATA SHOW THAT WHILE PU.1 FUNCTIONS AS A KEY DRIVER OF MYELOID DIFFERENTIATION, IT PLAYS AN EQUALLY CRITICAL ROLE IN TAILORING HEMATOPOIETIC RESPONSES TO INFLAMMATORY STIMULI WHILE LIMITING EXPANSION AND SELF-RENEWAL GENE EXPRESSION IN MPPS. THESE DATA IDENTIFY PU.1 AS A KEY REGULATOR OF "EMERGENCY" MYELOPOIESIS RELEVANT TO INFLAMMATORY DISEASE AND LEUKEMOGENESIS. 2023 13 1759 29 EARLY PRECURSOR T CELLS ESTABLISH AND PROPAGATE T CELL EXHAUSTION IN CHRONIC INFECTION. CD8(+) T CELLS RESPONDING TO CHRONIC INFECTIONS OR TUMORS ACQUIRE AN 'EXHAUSTED' STATE ASSOCIATED WITH ELEVATED EXPRESSION OF INHIBITORY RECEPTORS, INCLUDING PD-1, AND IMPAIRED CYTOKINE PRODUCTION. EXHAUSTED T CELLS ARE CONTINUOUSLY REPLENISHED BY T CELLS WITH PRECURSOR CHARACTERISTICS THAT SELF-RENEW AND DEPEND ON THE TRANSCRIPTION FACTOR TCF1; HOWEVER, THEIR DEVELOPMENTAL REQUIREMENTS ARE POORLY UNDERSTOOD. IN THE PRESENT STUDY, WE DEMONSTRATE THAT HIGH ANTIGEN LOAD PROMOTED THE DIFFERENTIATION OF PRECURSOR T CELLS, WHICH ACQUIRED HALLMARKS OF EXHAUSTION WITHIN DAYS OF INFECTION, WHEREAS EARLY EFFECTOR CELLS RETAINED POLYFUNCTIONAL FEATURES. EARLY PRECURSOR T CELLS SHOWED EPIGENETIC IMPRINTING CHARACTERISTIC OF T CELL RECEPTOR-DEPENDENT TRANSCRIPTION FACTOR BINDING AND WERE RESTRICTED TO THE GENERATION OF CELLS DISPLAYING EXHAUSTION CHARACTERISTICS. TRANSCRIPTION FACTORS BACH2 AND BATF WERE KEY REGULATORS WITH OPPOSING FUNCTIONS IN THE GENERATION OF EARLY PRECURSOR T CELLS. OVERALL, WE DEMONSTRATE THAT EXHAUSTION MANIFESTS FIRST IN TCF1(+) PRECURSOR T CELLS AND IS PROPAGATED SUBSEQUENTLY TO THE POOL OF ANTIGEN-SPECIFIC T CELLS. 2020 14 2421 26 EPIGENETIC SIGNATURE OF PD-1+ TCF1+ CD8 T CELLS THAT ACT AS RESOURCE CELLS DURING CHRONIC VIRAL INFECTION AND RESPOND TO PD-1 BLOCKADE. WE HAVE RECENTLY DEFINED A NOVEL POPULATION OF PD-1 (PROGRAMMED CELL DEATH 1)+ TCF1 (T CELL FACTOR 1)+ VIRUS-SPECIFIC CD8 T CELLS THAT FUNCTION AS RESOURCE CELLS DURING CHRONIC LCMV INFECTION AND PROVIDE THE PROLIFERATIVE BURST SEEN AFTER PD-1 BLOCKADE. SUCH CD8 T CELLS HAVE BEEN FOUND IN OTHER CHRONIC INFECTIONS AND ALSO IN CANCER IN MICE AND HUMANS. THESE CD8 T CELLS EXHIBIT STEM-LIKE PROPERTIES UNDERGOING SELF-RENEWAL AND ALSO DIFFERENTIATING INTO THE TERMINALLY EXHAUSTED CD8 T CELLS. HERE WE COMPARED THE EPIGENETIC SIGNATURE OF STEM-LIKE CD8 T CELLS WITH EXHAUSTED CD8 T CELLS. ATAC-SEQ ANALYSIS SHOWED THAT STEM-LIKE CD8 T CELLS HAD A UNIQUE SIGNATURE IMPLICATING ACTIVITY OF HMG (TCF) AND RHD (NF-KAPPAB) TRANSCRIPTION FACTOR FAMILY MEMBERS IN CONTRAST TO HIGHER ACCESSIBILITY TO ETS AND RUNX MOTIFS IN EXHAUSTED CD8 T CELLS. IN ADDITION, REGULATORY REGIONS OF THE TRANSCRIPTION FACTORS TCF7 AND ID3 WERE MORE ACCESSIBLE IN STEM-LIKE CELLS WHEREAS PRDM1 AND ID2 WERE MORE ACCESSIBLE IN EXHAUSTED CD8 T CELLS. WE ALSO COMPARED THE EPIGENETIC SIGNATURES OF THE 2 CD8 T CELL SUBSETS FROM CHRONICALLY INFECTED MICE WITH EFFECTOR AND MEMORY CD8 T CELLS GENERATED AFTER AN ACUTE LCMV INFECTION. BOTH CD8 T CELL SUBSETS GENERATED DURING CHRONIC INFECTION WERE STRIKINGLY DIFFERENT FROM CD8 T CELL SUBSETS FROM ACUTE INFECTION. INTERESTINGLY, THE STEM-LIKE CD8 T CELL SUBSET FROM CHRONIC INFECTION, DESPITE SHARING KEY FUNCTIONAL PROPERTIES WITH MEMORY CD8 T CELLS, HAD A VERY DISTINCT EPIGENETIC PROGRAM. THESE RESULTS SHOW THAT THE CHRONIC STEM-LIKE CD8 T CELL PROGRAM REPRESENTS A SPECIFIC ADAPTATION OF THE T CELL RESPONSE TO PERSISTENT ANTIGENIC STIMULATION. 2019 15 2786 29 EZH2 RESTRICTS THE SMOOTH MUSCLE LINEAGE DURING MOUSE LUNG MESOTHELIAL DEVELOPMENT. DURING DEVELOPMENT, THE LUNG MESODERM GENERATES A VARIETY OF CELL LINEAGES, INCLUDING AIRWAY AND VASCULAR SMOOTH MUSCLE. EPIGENETIC CHANGES IN ADULT LUNG MESODERMAL LINEAGES ARE THOUGHT TO CONTRIBUTE TOWARDS DISEASES SUCH AS IDIOPATHIC PULMONARY FIBROSIS AND CHRONIC OBSTRUCTIVE PULMONARY DISEASE, ALTHOUGH THE FACTORS THAT REGULATE EARLY LUNG MESODERM DEVELOPMENT ARE UNKNOWN. WE SHOW IN MOUSE THAT THE PRC2 COMPONENT EZH2 IS REQUIRED TO RESTRICT SMOOTH MUSCLE DIFFERENTIATION IN THE DEVELOPING LUNG MESOTHELIUM. MESODERMAL LOSS OF EZH2 LEADS TO THE FORMATION OF ECTOPIC SMOOTH MUSCLE IN THE SUBMESOTHELIAL REGION OF THE DEVELOPING LUNG MESODERM. LOSS OF EZH2 SPECIFICALLY IN THE DEVELOPING MESOTHELIUM REVEALS A MESOTHELIAL CELL-AUTONOMOUS ROLE FOR EZH2 IN REPRESSION OF THE SMOOTH MUSCLE DIFFERENTIATION PROGRAM. LOSS OF EZH2 DEREPRESSES EXPRESSION OF MYOCARDIN AND TBX18, WHICH ARE IMPORTANT REGULATORS OF SMOOTH MUSCLE DIFFERENTIATION FROM THE MESOTHELIUM AND RELATED CELL LINEAGES. TOGETHER, THESE FINDINGS UNCOVER AN EZH2-DEPENDENT MECHANISM TO RESTRICT THE SMOOTH MUSCLE GENE EXPRESSION PROGRAM IN THE DEVELOPING MESOTHELIUM AND ALLOW APPROPRIATE CELL FATE DECISIONS TO OCCUR IN THIS MULTIPOTENT MESODERM LINEAGE. 2016 16 5704 23 SINGLE-CELL RNA-SEQ REVEALS TOX AS A KEY REGULATOR OF CD8(+) T CELL PERSISTENCE IN CHRONIC INFECTION. PROGENITOR-LIKE CD8(+) T CELLS MEDIATE LONG-TERM IMMUNITY TO CHRONIC INFECTION AND CANCER AND RESPOND POTENTLY TO IMMUNE CHECKPOINT BLOCKADE. THESE CELLS SHARE TRANSCRIPTIONAL REGULATORS WITH MEMORY PRECURSOR CELLS, INCLUDING T CELL-SPECIFIC TRANSCRIPTION FACTOR 1 (TCF1), BUT IT IS UNCLEAR WHETHER THEY ADOPT DISTINCT PROGRAMS TO ADAPT TO THE IMMUNOSUPPRESSIVE ENVIRONMENT. BY COMPARING THE SINGLE-CELL TRANSCRIPTOMES AND EPIGENETIC PROFILES OF CD8(+) T CELLS RESPONDING TO ACUTE AND CHRONIC VIRAL INFECTIONS, WE FOUND THAT PROGENITOR-LIKE CD8(+) T CELLS BECAME DISTINCT FROM MEMORY PRECURSOR CELLS BEFORE THE PEAK OF THE T CELL RESPONSE. WE DISCOVERED A COEXPRESSION GENE MODULE CONTAINING TOX THAT EXHIBITED HIGHER TRANSCRIPTIONAL ACTIVITY ASSOCIATED WITH MORE ABUNDANT ACTIVE HISTONE MARKS IN PROGENITOR-LIKE CELLS THAN MEMORY PRECURSOR CELLS. MOREOVER, THYMOCYTE SELECTION-ASSOCIATED HIGH MOBILITY GROUP BOX PROTEIN TOX (TOX) PROMOTED THE PERSISTENCE OF ANTIVIRAL CD8(+) T CELLS AND WAS REQUIRED FOR THE PROGRAMMING OF PROGENITOR-LIKE CD8(+) T CELLS. THUS, LONG-TERM CD8(+) T CELL IMMUNITY TO CHRONIC VIRAL INFECTION REQUIRES UNIQUE TRANSCRIPTIONAL AND EPIGENETIC PROGRAMS ASSOCIATED WITH THE TRANSCRIPTION FACTOR TOX. 2019 17 1674 33 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 18 359 30 ALWAYS STRESSED BUT NEVER EXHAUSTED: HOW STEM CELLS IN MYELOID NEOPLASMS AVOID EXTINCTION IN INFLAMMATORY CONDITIONS. CHRONIC OR RECURRENT EPISODES OF ACUTE INFLAMMATION CAUSE ATTRITION OF NORMAL HEMATOPOIETIC STEM CELLS (HSCS) THAT CAN LEAD TO HEMATOPOIETIC FAILURE BUT THEY DRIVE PROGRESSION IN MYELOID MALIGNANCIES AND THEIR PRECURSOR CLONAL HEMATOPOIESIS. MECHANISTIC PARALLELS EXIST BETWEEN HEMATOPOIESIS IN CHRONIC INFLAMMATION AND THE CONTINUOUSLY INCREASED PROLIFERATION OF MYELOID MALIGNANCIES, PARTICULARLY MYELOPROLIFERATIVE NEOPLASMS (MPNS). THE ABILITY TO ENTER DORMANCY, A STATE OF DEEP QUIESCENCE CHARACTERIZED BY LOW OXIDATIVE PHOSPHORYLATION, LOW GLYCOLYSIS, REDUCED PROTEIN SYNTHESIS, AND INCREASED AUTOPHAGY IS CENTRAL TO THE PRESERVATION OF LONG-TERM HSCS AND LIKELY MPN SCS. THE METABOLIC FEATURES OF DORMANCY RESEMBLE THOSE OF DIAPAUSE, A STATE OF ARRESTED EMBRYONIC DEVELOPMENT TRIGGERED BY ADVERSE ENVIRONMENTAL CONDITIONS. TO OUTCOMPETE THEIR NORMAL COUNTERPARTS IN THE INFLAMMATORY MPN ENVIRONMENT, MPN SCS CO-OPT MECHANISMS USED BY HSCS TO AVOID EXHAUSTION, INCLUDING SIGNAL ATTENUATION BY NEGATIVE REGULATORS, INSULATION FROM ACTIVATING CYTOKINE SIGNALS, ANTI-INFLAMMATORY SIGNALING, AND EPIGENETIC REPROGRAMMING. WE PROPOSE THAT NEW THERAPEUTIC STRATEGIES MAY BE DERIVED FROM CONCEPTUALIZING MYELOID MALIGNANCIES AS AN ECOSYSTEM OUT OF BALANCE, IN WHICH RESIDUAL NORMAL AND MALIGNANT HEMATOPOIETIC CELLS INTERACT IN MULTIPLE WAYS, ONLY FEW OF WHICH HAVE BEEN CHARACTERIZED IN DETAIL. DISRUPTING MPN SC INSULATION TO OVERCOME DORMANCY, INTERFERING WITH ABERRANT CYTOKINE CIRCUITS THAT FAVOR MPN CELLS, AND DIRECTLY BOOSTING RESIDUAL NORMAL HSCS ARE POTENTIAL STRATEGIES TO TIP THE BALANCE IN FAVOR OF NORMAL HEMATOPOIESIS. ALTHOUGH ERADICATING THE MALIGNANT CELL CLONES REMAINS THE GOAL OF THERAPY, REBALANCING THE ECOSYSTEM MAY BE A MORE ATTAINABLE OBJECTIVE IN THE SHORT TERM. 2023 19 3702 31 INFLAMMATORY SIGNALING PATHWAYS IN PRELEUKEMIC AND LEUKEMIC STEM CELLS. HEMATOPOIETIC STEM CELLS (HSCS) ARE A RARE SUBSET OF BONE MARROW CELLS THAT USUALLY EXIST IN A QUIESCENT STATE, ONLY ENTERING THE CELL CYCLE TO REPLENISH THE BLOOD COMPARTMENT, THEREBY LIMITING THE POTENTIAL FOR ERRORS IN REPLICATION. INFLAMMATORY SIGNALS THAT ARE RELEASED IN RESPONSE TO ENVIRONMENTAL STRESSORS, SUCH AS INFECTION, TRIGGER ACTIVE CYCLING OF HSCS. THESE INFLAMMATORY SIGNALS CAN ALSO DIRECTLY INDUCE HSCS TO RELEASE CYTOKINES INTO THE BONE MARROW ENVIRONMENT, PROMOTING MYELOID DIFFERENTIATION. AFTER STRESS MYELOPOIESIS IS TRIGGERED, HSCS REQUIRE INTRACELLULAR SIGNALING PROGRAMS TO DEACTIVATE THIS RESPONSE AND RETURN TO STEADY STATE. PROLONGED OR EXCESSIVE EXPOSURE TO INFLAMMATORY CYTOKINES, SUCH AS IN PROLONGED INFECTION OR IN CHRONIC RHEUMATOLOGIC CONDITIONS, CAN LEAD TO CONTINUED HSC CYCLING AND EVENTUAL HSC LOSS. THIS PROMOTES BONE MARROW FAILURE, AND CAN PRECIPITATE PRELEUKEMIC STATES OR LEUKEMIA THROUGH THE ACQUISITION OF GENETIC AND EPIGENETIC CHANGES IN HSCS. THIS CAN OCCUR THROUGH THE INITIATION OF CLONAL HEMATOPOIESIS, FOLLOWED BY THE EMERGENCE PRELEUKEMIC STEM CELLS (PRE-LSCS). IN THIS REVIEW, WE DESCRIBE THE ROLES OF MULTIPLE INFLAMMATORY SIGNALING PATHWAYS IN THE GENERATION OF PRE-LSCS AND IN PROGRESSION TO MYELODYSPLASTIC SYNDROME (MDS), MYELOPROLIFERATIVE NEOPLASMS, AND ACUTE MYELOID LEUKEMIA (AML). IN AML, ACTIVATION OF SOME INFLAMMATORY SIGNALING PATHWAYS CAN PROMOTE THE CYCLING AND DIFFERENTIATION OF LSCS, AND THIS CAN BE EXPLOITED THERAPEUTICALLY. WE ALSO DISCUSS THE THERAPEUTIC POTENTIAL OF MODULATING INFLAMMATORY SIGNALING FOR THE TREATMENT OF MYELOID MALIGNANCIES. 2017 20 3878 33 KDM6B OVEREXPRESSION ACTIVATES INNATE IMMUNE SIGNALING AND IMPAIRS HEMATOPOIESIS IN MICE. KDM6B IS AN EPIGENETIC REGULATOR THAT MEDIATES TRANSCRIPTIONAL ACTIVATION DURING DIFFERENTIATION, INCLUDING IN BONE MARROW (BM) HEMATOPOIETIC STEM AND PROGENITOR CELLS (HSPCS). OVEREXPRESSION OF KDM6B HAS BEEN REPORTED IN BM HSPCS OF PATIENTS WITH MYELODYSPLASTIC SYNDROMES (MDS) AND CHRONIC MYELOMONOCYTIC LEUKEMIA (CMML). WHETHER THE OVEREXPRESSION OF KDM6B CONTRIBUTES TO THE PATHOGENESIS OF THESE DISEASES REMAINS TO BE ELUCIDATED. TO STUDY THIS, WE GENERATED A VAV-KDM6B MOUSE MODEL, WHICH OVEREXPRESSES KDM6B IN THE HEMATOPOIETIC COMPARTMENT. KDM6B OVEREXPRESSION ALONE LED TO MILD HEMATOPOIETIC PHENOTYPE, AND CHRONIC INNATE IMMUNE STIMULATION OF VAV-KDM6B MICE WITH THE TOLL-LIKE RECEPTOR (TLR) LIGAND LIPOPOLYSACCHARIDE (LPS) RESULTED IN SIGNIFICANT HEMATOPOIETIC DEFECTS. THESE DEFECTS RECAPITULATED FEATURES OF MDS AND CMML, INCLUDING LEUKOPENIA, DYSPLASIA, AND COMPROMISED REPOPULATING FUNCTION OF BM HSPCS. TRANSCRIPTOME STUDIES INDICATED THAT KDM6B OVEREXPRESSION ALONE COULD LEAD TO ACTIVATION OF DISEASE-RELEVANT GENES SUCH AS S100A9 IN BM HSPCS, AND WHEN COMBINED WITH INNATE IMMUNE STIMULATION, KDM6B OVEREXPRESSION RESULTED IN MORE PROFOUND OVEREXPRESSION OF INNATE IMMUNE AND DISEASE-RELEVANT GENES, INDICATING THAT KDM6B WAS INVOLVED IN THE ACTIVATION OF INNATE IMMUNE SIGNALING IN BM HSPCS. FINALLY, PHARMACOLOGIC INHIBITION OF KDM6B WITH THE SMALL MOLECULE INHIBITOR GSK-J4 AMELIORATED THE INEFFECTIVE HEMATOPOIESIS OBSERVED IN VAV-KDM6B MICE. THIS EFFECT WAS ALSO OBSERVED WHEN GSK-J4 WAS APPLIED TO THE PRIMARY BM HSPCS OF PATIENTS WITH MDS BY IMPROVING THEIR REPOPULATING FUNCTION. THESE RESULTS INDICATE THAT OVEREXPRESSION OF KDM6B MEDIATES ACTIVATION OF INNATE IMMUNE SIGNALS AND HAS A ROLE IN MDS AND CMML PATHOGENESIS, AND THAT KDM6B TARGETING HAS THERAPEUTIC POTENTIAL IN THESE MYELOID DISORDERS. 2018