1 5061 131 PHF6 FUNCTIONS AS A TUMOR SUPPRESSOR BY RECRUITING METHYLTRANSFERASE SUV39H1 TO NUCLEOLAR REGION AND OFFERS A NOVEL THERAPEUTIC TARGET FOR PHF6-MUNTANT LEUKEMIA. MUTATIONS IN THE PLANT HOMEODOMAIN-LIKE FINGER PROTEIN 6 (PHF6) GENE ARE STRONGLY ASSOCIATED WITH ACUTE MYELOID (AML) AND T-CELL ACUTE LYMPHOBLASTIC LEUKEMIA (T-ALL). IN THIS STUDY, WE DEMONSTRATED THAT PHF6 CAN BIND TO H3K9ME3 AND H3K27ME1 ON THE NUCLEOLAR CHROMATIN AND RECRUIT HISTONE METHYLTRANSFERASE SUV39H1 TO THE RDNA LOCUS. THE DELETION OF PHF6 CAUSED A DECREASE IN THE RECRUITMENT OF SUV39H1 TO RDNA GENE LOCI, RESULTING IN A REDUCTION IN THE LEVEL OF H3K9ME3 AND THE PROMOTION OF RDNA TRANSCRIPTION. THE KNOCKDOWN OF EITHER SUV39H1 OR PHF6 SIGNIFICANTLY ATTENUATED THE EFFECTS OF INCREASE IN H3K9ME3 AND SUPPRESSED THE TRANSCRIPTION OF RDNA INDUCED BY THE OVEREXPRESSION OF THE OTHER INTERACTING PARTNER, THEREBY ESTABLISHING AN INTERDEPENDENT RELATIONSHIP BETWEEN PHF6 AND SUV39H1 IN THEIR CONTROL OF RRNA TRANSCRIPTION. THE PHF6 CLINICAL MUTANTS SIGNIFICANTLY IMPAIRED THE ABILITY TO BIND AND RECRUIT SUV39H1 TO THE RDNA LOCI, RESULTING IN AN INCREASE IN RDNA TRANSCRIPTION ACTIVITY, THE PROLIFERATION OF IN VITRO LEUKEMIA CELLS, AND THE GROWTH OF IN VIVO MOUSE XENOGRAFTS. IMPORTANTLY, SIGNIFICANTLY ELEVATED LEVELS OF PRE-RRNA WERE OBSERVED IN CLINICAL AML PATIENTS WHO POSSESSED A MUTATED VERSION OF PHF6. THE SPECIFIC RDNA TRANSCRIPTION INHIBITOR CX5461 SIGNIFICANTLY REDUCED THE RESISTANCE OF U937 AML CELLS DEFICIENT IN PHF6 TO CYTARABINE, THE DRUG THAT IS MOST COMMONLY USED TO TREAT AML. COLLECTIVELY, WE REVEALED A NOVEL MOLECULAR MECHANISM BY WHICH PHF6 RECRUITS METHYLTRANSFERASE SUV39H1 TO THE NUCLEOLAR REGION IN LEUKEMIA AND PROVIDED A POTENTIAL THERAPEUTIC TARGET FOR PHF6-MUTANT LEUKEMIA. 2022 2 6383 39 THE ROLE OF PHF6 IN HEMATOPOIESIS AND HEMATOLOGIC MALIGNANCIES. EPIGENETIC REGULATION OF GENE EXPRESSION REPRESENTS AN IMPORTANT MECHANISM IN THE MAINTENANCE OF STEM CELL FUNCTION. ALTERATIONS IN EPIGENETIC REGULATION CONTRIBUTE TO THE PATHOGENESIS OF HEMATOLOGICAL MALIGNANCIES. PLANT HOMEODOMAIN FINGER PROTEIN 6 (PHF6) IS A MEMBER OF THE PLANT HOMEODOMAIN (PHD)-LIKE ZINC FINGER FAMILY OF PROTEINS THAT IS INVOLVED IN TRANSCRIPTIONAL REGULATION THROUGH THE MODIFICATION OF THE CHROMATIN STATE. GERMLINE MUTATION OF PHF6 IS THE CAUSATIVE GENETIC ALTERATION OF THE X-LINKED MENTAL RETARDATION BORJESON-FORSSMAN-LEHMANN SYNDROME (BFLS). SOMATIC MUTATIONS IN PHF6 ARE IDENTIFIED IN HUMAN LEUKEMIA, SUCH AS ADULT T-CELL ACUTE LYMPHOBLASTIC LEUKEMIA (T-ALL, ~ 38%), PEDIATRIC T-ALL (~ 16%), ACUTE MYELOID LEUKEMIA (AML, ~ 3%), CHRONIC MYELOID LEUKEMIA (CML, ~ 2.5%), MIXED PHENOTYPE ACUTE LEUKEMIA (MPAL, ~ 20%), AND HIGH-GRADE B-CELL LYMPHOMA (HGBCL, ~ 3%). MORE RECENT STUDIES IMPLY AN ONCOGENIC EFFECT OF PHF6 IN B-CELL ACUTE LYMPHOBLASTIC LEUKEMIA (B-ALL) AND SOLID TUMORS. THESE DATA DEMONSTRATE THAT PHF6 COULD ACT AS A DOUBLE-EDGED SWORD, EITHER A TUMOR SUPPRESSOR OR AN ONCOGENE, IN A LINEAGE-DEPENDENT MANNER. HOWEVER, THE UNDERLYING MECHANISMS OF PHF6 IN NORMAL HEMATOPOIESIS AND LEUKEMOGENESIS REMAIN LARGELY UNKNOWN. IN THIS REVIEW, WE SUMMARIZE CURRENT KNOWLEDGE OF PHF6, EMPHASIZING THE ROLE OF PHF6 IN HEMATOLOGICAL MALIGNANCIES. EPIGENETIC REGULATION OF PHF6 IN B-ALL. PHF6 MAINTAINS A CHROMATIN STRUCTURE THAT IS PERMISSIVE TO B-CELL IDENTITY GENES, BUT NOT T-CELL-SPECIFIC GENES (LEFT). LOSS OF PHF6 LEADS TO ABERRANT EXPRESSION OF B-CELL- AND T-CELL-SPECIFIC GENES RESULTING FROM LINEAGE PROMISCUITY AND BINDING OF T-CELL TRANSCRIPTION FACTORS (RIGHT). 2023 3 3415 35 HSP90 INHIBITION INCREASES SOCS3 TRANSCRIPT AND REGULATES MIGRATION AND CELL DEATH IN CHRONIC LYMPHOCYTIC LEUKEMIA. EPIGENETIC OR TRANSCRIPTIONAL SILENCING OF IMPORTANT TUMOR SUPPRESSORS HAS BEEN DESCRIBED TO CONTRIBUTE TO CELL SURVIVAL AND TUMORIGENESIS IN CHRONIC LYMPHOCYTIC LEUKEMIA (CLL). USING GENE EXPRESSION MICROARRAY ANALYSIS, WE FOUND THAT THOUSANDS OF GENES ARE REPRESSED MORE THAN 2-FOLD IN CLL COMPARED TO NORMAL B CELLS; HOWEVER THERAPEUTIC APPROACHES TO REVERSE THIS HAVE BEEN LIMITED IN CLL. FOLLOWING TREATMENT WITH THE HSP90 INHIBITOR 17-DMAG, A SIGNIFICANT NUMBER OF THESE REPRESSED GENES WERE SIGNIFICANTLY RE-EXPRESSED. ONE OF THE GENES SIGNIFICANTLY REPRESSED IN CLL AND UP-REGULATED BY 17-DMAG WAS SUPPRESSOR OF CYTOKINE SIGNALING 3, (SOCS3). SOCS3 HAS BEEN SHOWN TO BE SILENCED IN SOLID TUMORS AS WELL AS MYELOID LEUKEMIA; HOWEVER LITTLE IS KNOWN ABOUT THE REGULATION IN CLL. WE FOUND THAT 17-DMAG INDUCES EXPRESSION OF SOCS3 BY VIA THE ACTIVATION OF P38 SIGNALING, AND SUBSEQUENTLY INHIBITS AKT AND STAT3 PHOSPHORYLATION RESULTING IN DOWNSTREAM EFFECTS ON CELL MIGRATION AND SURVIVAL. WE THEREFORE SUGGEST THAT SOCS3 IS AN IMPORTANT SIGNALING PROTEIN IN CLL, AND HSP90 INHIBITORS REPRESENT A NOVEL APPROACH TO TARGET TRANSCRIPTIONAL REPRESSION IN B CELL LYMPHOPROLIFERATIVE DISORDERS WHICH EXHIBIT A SUBSTANTIAL DEGREE OF GENE REPRESSION. 2016 4 1669 40 DOWNREGULATION OF THE HISTONE METHYLTRANSFERASE SETD2 PROMOTES IMATINIB RESISTANCE IN CHRONIC MYELOID LEUKAEMIA CELLS. OBJECTIVES: EPIGENETIC MODIFIERS WERE IMPORTANT PLAYERS IN THE DEVELOPMENT OF HAEMATOLOGICAL MALIGNANCIES AND SENSITIVITY TO THERAPY. MUTATIONS OF SET DOMAIN-CONTAINING 2 (SETD2), A METHYLTRANSFERASE THAT CATALYSES THE TRIMETHYLATION OF HISTONE 3 ON LYSINE 36 (H3K36ME3), WERE FOUND IN VARIOUS MYELOID MALIGNANCIES. HOWEVER, THE DETAILED MECHANISMS THROUGH WHICH SETD2 CONFERS CHRONIC MYELOID LEUKAEMIA PROGRESSION AND RESISTANCE TO THERAPY TARGETING ON BCR-ABL REMAIN UNCLEAR. MATERIALS AND METHODS: THE LEVEL OF SETD2 IN IMATINIB-SENSITIVE AND IMATINIB-RESISTANT CHRONIC MYELOID LEUKAEMIA (CML) CELLS WAS EXAMINED BY IMMUNOBLOTTING AND QUANTITATIVE REAL-TIME PCR. WE ANALYSED CD34(+) CD38(-) LEUKAEMIC STEM CELLS BY FLOW CYTOMETRY AND COLONY FORMATION ASSAYS UPON SETD2 KNOCKDOWN OR OVEREXPRESSION. THE IMPACT OF SETD2 EXPRESSION ALTERATIONS OR SMALL-MOLECULE INHIBITOR JIB-04 TARGETING H3K36ME3 LOSS ON IMATINIB SENSITIVITY WAS ASSESSED BY IC50, CELL APOPTOSIS AND PROLIFERATION ASSAYS. FINALLY, RNA SEQUENCING AND CHIP-QUANTITATIVE PCR WERE PERFORMED TO VERIFY PUTATIVE DOWNSTREAM TARGETS. RESULTS: SETD2 WAS FOUND TO ACT AS A TUMOUR SUPPRESSOR IN CML. THE NOVEL ONCOGENIC TARGETS MYCN AND ERG WERE SHOWN TO BE THE DIRECT DOWNSTREAM TARGETS OF SETD2, WHERE THEIR OVEREXPRESSION INDUCED BY SETD2 KNOCKDOWN CAUSED IMATINIB INSENSITIVITY AND LEUKAEMIC STEM CELL ENRICHMENT IN CML CELL LINES. TREATMENT WITH JIB-04, AN INHIBITOR THAT RESTORES H3K36ME3 LEVELS THROUGH BLOCKADE OF ITS DEMETHYLATION, SUCCESSFULLY IMPROVED THE CELL IMATINIB SENSITIVITY AND ENHANCED THE CHEMOTHERAPEUTIC EFFECT. CONCLUSIONS: OUR STUDY NOT ONLY EMPHASIZES THE REGULATORY MECHANISM OF SETD2 IN CML, BUT ALSO PROVIDES PROMISING THERAPEUTIC STRATEGIES FOR OVERCOMING THE IMATINIB RESISTANCE IN PATIENTS WITH CML. 2019 5 825 29 CHARACTERIZATION OF FUNCTIONAL TRANSPOSABLE ELEMENT ENHANCERS IN ACUTE MYELOID LEUKEMIA. TRANSPOSABLE ELEMENTS (TES) HAVE BEEN SHOWN TO HAVE IMPORTANT GENE REGULATORY FUNCTIONS AND THEIR ALTERATION COULD LEAD TO DISEASE PHENOTYPES. ACUTE MYELOID LEUKEMIA (AML) DEVELOPS AS A CONSEQUENCE OF A SERIES OF GENETIC CHANGES IN HEMATOPOIETIC PRECURSOR CELLS, INCLUDING MUTATIONS IN EPIGENETIC FACTORS. HERE, WE SET OUT TO STUDY THE GENE REGULATORY ROLE OF TES IN AML. WE FIRST EXPLORED THE EPIGENETIC LANDSCAPE OF TES IN AML PATIENTS USING ATAC-SEQ DATA. WE SHOW THAT A LARGE NUMBER OF TES IN GENERAL, AND MORE SPECIFICALLY MAMMALIAN-WIDE INTERSPERSED REPEATS (MIRS), ARE MORE ENRICHED IN AML CELLS THAN IN NORMAL BLOOD CELLS. WE OBTAINED A SIMILAR FINDING WHEN ANALYZING HISTONE MODIFICATION DATA IN AML PATIENTS. GENE ONTOLOGY ENRICHMENT ANALYSIS SHOWED THAT GENES NEAR MIRS IN OPEN CHROMATIN REGIONS ARE INVOLVED IN LEUKEMOGENESIS. TO FUNCTIONALLY VALIDATE THEIR REGULATORY ROLE, WE SELECTED 19 MIR REGIONS IN AML CELLS, AND TESTED THEM FOR ENHANCER ACTIVITY IN AN AML CELL LINE (KASUMI-1) AND A CHRONIC MYELOID LEUKEMIA (CML) CELL LINE (K562); THE RESULTS REVEALED SEVERAL MIRS TO BE FUNCTIONAL ENHANCERS. TAKEN TOGETHER, OUR RESULTS SUGGEST THAT TES ARE POTENTIALLY INVOLVED IN MYELOID LEUKEMOGENESIS AND HIGHLIGHT THESE SEQUENCES AS POTENTIAL CANDIDATES HARBORING AML-ASSOCIATED VARIATION. 2020 6 5475 33 RESTORING MLL REACTIVATES LATENT TUMOR SUPPRESSION-MEDIATED VULNERABILITY TO PROTEASOME INHIBITORS. MLL UNDERGOES MULTIPLE DISTINCT CHROMOSOMAL TRANSLOCATIONS TO YIELD AGGRESSIVE LEUKEMIA WITH DISMAL OUTCOMES. BESIDES THEIR WELL-ESTABLISHED ROLE IN LEUKEMOGENESIS, MLL FUSIONS ALSO POSSESS LATENT TUMOR-SUPPRESSIVE ACTIVITY, WHICH CAN BE EXPLOITED AS EFFECTIVE CANCER TREATMENT STRATEGIES USING PHARMACOLOGICAL MEANS SUCH AS PROTEASOME INHIBITORS (PIS). HERE, USING MLL-REARRANGED XENOGRAFTS AND MLL LEUKEMIC CELLS AS MODELS, WE SHOW THAT WILD-TYPE MLL IS INDISPENSABLE FOR THE LATENT TUMOR-SUPPRESSIVE ACTIVITY OF MLL FUSIONS. MLL DYSFUNCTION, SHOWN AS LOSS OF THE CHROMATIN ACCUMULATION AND SUBSEQUENT DEGRADATION OF MLL, COMPROMISES THE LATENT TUMOR SUPPRESSION OF MLL-AF4 AND IS INSTRUMENTAL FOR THE ACQUIRED PI RESISTANCE. MECHANISTICALLY, MLL DYSFUNCTION IS CAUSED BY CHRONIC PI TREATMENT-INDUCED EPIGENETIC REPROGRAMMING THROUGH THE H2BUB-ASH2L-MLL AXIS AND CAN BE SPECIFICALLY RESTORED BY HISTONE DEACETYLASE (HDAC) INHIBITORS, WHICH INDUCE HISTONE ACETYLATION AND RECRUITS MLL ON CHROMATIN TO PROMOTE CELL CYCLE GENE EXPRESSION. OUR FINDINGS NOT ONLY DEMONSTRATE THE MECHANISM UNDERLYING THE INEVITABLE ACQUISITION OF PI RESISTANCE IN MLL LEUKEMIC CELLS, BUT ALSO ILLUSTRATE THAT PREVENTING THE EMERGENCE OF PI-RESISTANT CELLS CONSTITUTES A NOVEL RATIONALE FOR COMBINATION THERAPY WITH PIS AND HDAC INHIBITORS IN MLL LEUKEMIAS. 2020 7 926 40 CHRONIC INFLAMMATION PATHWAY NF-KAPPAB COOPERATES WITH EPIGENETIC REPROGRAMMING TO DRIVE THE MALIGNANT PROGRESSION OF GLIOBLASTOMA. WITHOUT AN EFFECTIVE STRATEGY FOR TARGETED THERAPY, GLIOBLASTOMA IS STILL INCURABLE WITH A MEDIAN SURVIVAL OF ONLY 15 MONTHS. BOTH CHRONIC INFLAMMATION AND EPIGENETIC REPROGRAMMING ARE HALLMARKS OF CANCER. HOWEVER, THE MECHANISMS AND CONSEQUENCES OF THEIR COOPERATION IN GLIOBLASTOMA REMAIN UNKNOWN. HERE, WE DISCOVER THAT CHRONIC INFLAMMATION GOVERNS H3K27ME3 REPROGRAMMING IN GLIOBLASTOMA THROUGH THE CANONICAL NF-KAPPAB PATHWAY TO TARGET EZH2. BEING A CRUCIAL MEDIATOR OF CHRONIC INFLAMMATION, THE CANONICAL NF-KAPPAB SIGNALLING SPECIFICALLY DIRECTS THE EXPRESSION AND REDISTRIBUTION OF H3K27ME3 BUT NOT H3K4ME3, H3K9ME3 AND H3K36ME3. USING RNA-SEQ SCREENING TO FOCUS ON GENES ENCODING METHYLTRANSFERASES AND DEMETHYLASES OF HISTONE, WE IDENTIFY EZH2 AS A KEY METHYLTRANSFERASE TO CONTROL INFLAMMATION-TRIGGERED EPIGENETIC REPROGRAMMING IN GLIOMAGENESIS. MECHANISTICALLY, NF-KAPPAB SELECTIVELY DRIVES THE EXPRESSION OF EZH2 BY ACTIVATING ITS TRANSCRIPTION, CONSEQUENTLY RESULTING IN A GLOBAL CHANGE IN H3K27ME3 EXPRESSION AND DISTRIBUTION. FURTHERMORE, WE FIND THAT CO-ACTIVATION OF NF-KAPPAB AND EZH2 CONFERS THE POOREST CLINICAL OUTCOME, AND THAT THE RISK FOR GLIOBLASTOMA CAN BE ACCURATELY MOLECULARLY STRATIFIED BY NF-KAPPAB AND EZH2. IT IS NOTABLE THAT NF-KAPPAB CAN POTENTIALLY COOPERATE WITH EZH2 IN MORE THAN ONE WAY, AND MOST IMPORTANTLY, WE DEMONSTRATE A SYNERGISTIC EFFECT OF CANCER CELLS INDUCED BY COMBINATORY INHIBITION OF NF-KAPPAB AND EZH2, WHICH BOTH ARE FREQUENTLY OVER-ACTIVATED IN GLIOBLASTOMA. IN SUMMARY, WE UNCOVER A FUNCTIONAL COOPERATION BETWEEN CHRONIC INFLAMMATION AND EPIGENETIC REPROGRAMMING IN GLIOBLASTOMA, COMBINED TARGETING OF WHICH BY INHIBITORS GUARANTEED IN SAFETY AND AVAILABILITY FURNISHES A POTENT STRATEGY FOR EFFECTIVE TREATMENT OF THIS FATAL DISEASE. 2022 8 6773 32 [ADVANCES OF RESEARCH ON DEMETHYLATION THERAPY FOR HEMATOLOGIC MALIGNANCIES]. DNA METHYLATION IS AN IMPORTANT AND REVERSIBLE EPIGENETIC MODIFICATION WHICH REGULATES GENOMIC STABILITY. METHYLATION IS ESSENTIAL FOR MAMMALIAN DEVELOPMENT. GENERALLY, GENE EXPRESSION LEVEL AND DNA METHYLATION ARE NEGATIVE CORRELATION. TRANSCRIPTIONAL SILENCING VIA METHYLATION OF CPG ISLANDS IN THE PROMOTER IS IMPORTANT FOR CELL GROWTH AND DIFFERENTIATION AND PLAYS A KEY ROLE IN TUMORIGENESIS. DEMETHYLATION DRUG CAN MODIFY CHROMATIN AND RESTORE THE ABILITY OF ANTI-ONCOGENE. DEMETHYLATION THERAPY AS A NEW THERAPY MAY TREAT EFFICIENTLY HEMATOLOGICAL MALIGNANCIES WITH RESISTANCE AND RELAPSE. IN THIS REVIEW, DNA METHYLATION MECHANISM, RELATIONSHIP BETWEEN ABERRANT METHYLATION AND HEMATOLOGIC MALIGNANCIES, MECHANISM OF DEMETHYLATION THERAPY, THE ADVANCE OF RESEARCH ON THE DEMETHYLATION THERAPY OF HEMATOLOGICAL MALIGNANCIES, SUCH AS ACUTE AND CHRONIC LEUKEMIA, LYMPHOMA, MYELODYSPLASTIC SYNDROME WERE SUMMARIZED. 2009 9 2747 35 EXPRESSION ANALYSIS OF THE EPIGENETIC METHYLTRANSFERASES AND METHYL-CPG BINDING PROTEIN FAMILIES IN THE NORMAL B-CELL AND B-CELL CHRONIC LYMPHOCYTIC LEUKEMIA (CLL). THE IMPORTANCE OF EPIGENETIC MODIFICATIONS IN CARCINOGENESIS HAS BEEN A SOURCE OF CONTROVERSY FOR SOME TIME. THERE IS LITTLE DOUBT THAT CHANGES IN GENOMIC HYPERMETHYLATION CONTRIBUTE TO THE SILENCING OF TUMOR SUPPRESSOR GENES. FURTHERMORE, RECENT STUDIES HAVE ALSO IDENTIFIED THE SIGNIFICANCE OF GENOMIC HYPOMETHYLATION ASSOCIATED WITH CHROMOSOMAL INSTABILITY AND TUMORIGENESIS. ONE OF THE MOST PERPLEXING QUESTIONS REGARDING EPIGENETIC MODIFICATIONS AND LEUKEMOGENESIS IS THE RELATIONSHIP WITH DNA METHYLTRANSFERASES (DNMT'S). THE PRIMARY FUNCTION OF THE DNMT ENZYMES IS TO METHYLATE GENOMIC DNA, WHEREAS THE METHYL-CPG BINDING DOMAIN PROTEINS (MBD) INTERPRET THIS METHYLATION SIGNAL AND REGULATE GENE EXPRESSION AND CHROMATIN BEHAVIOR. IN THIS STUDY WE ANALYSE THESE GENE FAMILIES BY QUANTITATIVE REAL-TIME PCR TO INVESTIGATE WHETHER EXPRESSION LEVELS AND THE B-CELL CHRONIC LYMPHOCYTIC LEUKEMIA (B-CLL) PHENOTYPE ARE ASSOCIATED. FURTHERMORE, GIVEN THE EPIGENETIC CROSSTALK BETWEEN GENOME STABILITY AND THE HISTONE CHROMATIN CODE WE HAVE ANALYSED EUKARYOTIC HISTONE METHYLTRANSFERASE (EU-HMTASEI). SURPRISINGLY, WE DID NOT OBSERVE SIGNIFICANT CHANGES IN DNMT1 EXPRESSION IN B-CLL CASES WHEN COMPARED TO NORMAL LYMPHOCYTES, REGARDLESS OF WHETHER WE NORMALISE AGAINST GAPDH OR PCNA AS REFERENCE STANDARDS. INDEED, EXPRESSION OF THE MAINTENANCE AND DE NOVO METHYLASES WERE INDEPENDENTLY REGULATED. OF PARTICULAR NOTE WAS THE SIGNIFICANT DOWN REGULATION OF DNMT3B. FURTHERMORE, WE OBSERVED A POSITIVE CORRELATION BETWEEN HMTASEI EXPRESSION LEVELS AND STAGE OF LEUKEMIA SUGGESTING THAT CHANGES IN THE METHYLATION PATTERNS IN B-CLL MAY REPRESENT DEREGULATION OF THE EPIGENETIC REPERTOIRE THAT ALSO INCLUDE THE METHYLATION DEPENDENT BINDING PROTEINS, MBD2 AND MECP2. WE ENVISAGE CHANGES IN THE EPIGENETIC PROGRAM ARE MULTIFACTORIAL IN NATURE AND POSTULATE THAT THE PREVALENT GENOMIC METHYLASES JUST ONE COMPONENT OF A LARGER EPIGENETIC REPERTOIRE. 2004 10 3527 29 IL-6 ENHANCES THE NUCLEAR TRANSLOCATION OF DNA CYTOSINE-5-METHYLTRANSFERASE 1 (DNMT1) VIA PHOSPHORYLATION OF THE NUCLEAR LOCALIZATION SEQUENCE BY THE AKT KINASE. THE EPIGENETIC PROGRAMMING OF GENOMIC DNA IS ACCOMPLISHED, IN PART, BY SEVERAL DNA CYTOSINE-5-METHYLTRANSFERASES THAT ACT BY COVALENTLY MODIFYING CYTOSINES WITH THE ADDITION OF A METHYL GROUP. THIS COVALENT MODIFICATION IS MAINTAINED BY THE DNA CYTOSINE-5-METHYLTRANSFERASE-1 ENZYME (DNMT1), WHICH IS CAPABLE OF ACTING IN CONCERT WITH OTHER SIMILAR ENZYMES TO SILENCE IMPORTANT TUMOR SUPPRESSOR GENES. IL-6 IS A MULTIFUNCTIONAL MEDIATOR OF INFLAMMATION, ACTING THROUGH SEVERAL MAJOR SIGNALING CASCADES, INCLUDING THE PHOSPHATIDYLINOSITOL-3-KINASE PATHWAY (PI-3-K), WHICH ACTIVATES PROTEIN KINASE B (AKT/PKB) DOWNSTREAM. HERE, WE SHOW THAT THE SUBCELLULAR LOCALIZATION OF DNMT1 CAN BE ALTERED BY THE ADDITION OF IL-6, INCREASING THE RATE OF NUCLEAR TRANSLOCATION OF THE ENZYME FROM THE CYTOSOLIC COMPARTMENT. THE MECHANISM OF NUCLEAR TRANSLOCATION OF DNMT1 IS GREATLY ENHANCED BY PHOSPHORYLATION OF THE DNMT1 NUCLEAR LOCALIZATION SIGNAL (NLS) BY PKB/AKT KINASE. MUTAGENIC ALTERATION OF THE TWO AKT TARGET AMINO ACIDS WITHIN THE NLS RESULTS IN A MAJOR LOSS OF DNMT1 NUCLEAR TRANSLOCATION, WHILE THE CREATION OF A "PHOSPHO-MIMIC" AMINO ACID (MUTATION TO ACIDIC RESIDUES) RESTORES THIS COMPARTMENTATION ABILITY. THESE OBSERVATIONS SUGGEST AN INTERESTING HYPOTHESIS REGARDING HOW MEDIATORS OF CHRONIC INFLAMMATION MAY DISTURB THE DELICATE BALANCE OF CELLULAR COMPARTMENTALIZATION OF IMPORTANT PROTEINS, AND REVEALS A POTENTIAL MECHANISM FOR THE INDUCTION OR ENHANCEMENT OF TUMOR GROWTH VIA ALTERATION OF THE COMPONENTS INVOLVED IN THE EPIGENETIC PROGRAMMING OF A CELL. 2007 11 2114 29 EPIGENETIC HETEROCHROMATIN MARKERS DISTINGUISH TERMINALLY DIFFERENTIATED LEUKOCYTES FROM INCOMPLETELY DIFFERENTIATED LEUKEMIA CELLS IN HUMAN BLOOD. OBJECTIVE: DURING TERMINAL CELL DIFFERENTIATION, NUCLEAR CHROMATIN BECOMES CONDENSED AND THE REPERTOIRE OF EPIGENTIC HETEROCHROMATIN PROTEINS RESPONSIBLE FOR CHROMATIN CONDENSATION IS DRAMATICALLY CHANGED. IN ORDER TO IDENTIFY THE CHROMATIN REGULATORY FACTORS ASSOCIATED WITH INCOMPLETE CELL DIFFERENTIATION AND IMPAIRED CHROMATIN CONDENSATION IN HEMATOLOGICAL MALIGNANCIES, WE EXAMINED EXPRESSION LEVELS OF MAJOR HETEROCHROMATIN PROTEINS IN NORMAL BLOOD CELLS AND CELLS DERIVED FROM A NUMBER OF CHRONIC AND ACUTE MYELOID LEUKEMIA PATIENTS EXHIBITING DIFFERENT DEGREES OF DIFFERENTIATION. METHODS: WE USED IMMUNOBLOTTING AND IMMUNOFLUORESCENCE TO EXAMINE THE LEVELS AND LOCALIZATION OF EPIGENETIC HETEROCHROMATIN FACTORS IN ISOLATED CELL NUCLEI AND FRACTIONATED PERIPHERAL BLOOD CELLS. RESULTS: WHILE THE MAJOR EPIGENETIC HETEROCHROMATIN FACTOR, HISTONE H3 METHYLATED AT LYSINE 9, IS PRESENT IN ALL CELL TYPES, ITS MAIN COUNTERPARTS, NONHISTONE PROTEINS, HETEROCHROMATIN PROTEINS 1 (HP1) ALPHA, BETA, AND GAMMA, ARE DRAMATICALLY REDUCED IN PERIPHERAL BLOOD LEUKOCYTES OF NORMAL DONORS AND CHRONIC MYELOID LEUKEMIA PATIENTS, BUT ARE SUBSTANTIALLY INCREASED IN THE BLOOD OF ACCELERATED PHASE AND BLAST CRISIS PATIENTS. IN THE TERMINALLY DIFFERENTIATED CELLS, NUCLEAR CHROMATIN ACCUMULATES A NUCLEOCYTOPLASMIC SERPIN, MONOCYTE AND NEUTROPHIL ELASTASE INHIBITOR (MNEI). HP1 AND MNEI LEVELS INVERSELY CORRELATE IN A NUMBER OF NORMAL AND LEUKEMIA MYELOID CELLS AND SHOW STRIKINGLY OPPOSITE COORDINATED CHANGES DURING DIFFERENTIATION OF U937 CELL LINE INDUCED BY RETINOIC ACID. CONCLUSIONS: OUR RESULTS SUGGEST THAT REPRESSION OF HP1 AND ACCUMULATION OF MNEI ARE LINKED TO TERMINAL CELL DIFFERENTIATION AND THAT THEIR LEVELS MAY BE MONITORED IN BLOOD CELL POPULATIONS TO DETECT TRANSITIONS IN CELL DIFFERENTIATION ASSOCIATED WITH LEUKEMIA PROGRESSION AND TREATMENT. 2006 12 3532 35 IMATINIB INDEPENDENT ABERRANT METHYLATION OF NOV/CCN3 IN CHRONIC MYELOGENOUS LEUKEMIA PATIENTS: A MECHANISM UPSTREAM OF BCR-ABL1 FUNCTION? BACKGROUND: THE NOV GENE PRODUCT, CCN3, HAS BEEN REPORTED IN A DIVERSE RANGE OF TUMORS TO SERVE AS A NEGATIVE GROWTH REGULATOR, WHILE ACTING AS A TUMOR SUPPRESSOR IN CHRONIC MYELOGENOUS LEUKEMIA (CML). HOWEVER, THE PRECISE MECHANISM OF ITS SILENCING IN CML IS POORLY UNDERSTOOD. IN THE CURRENT STUDY, WE AIMED TO QUERY IF THE GENE REGULATION OF CCN3 IS MEDIATED BY THE PROMOTER METHYLATION IN THE PATIENTS WITH CML. IN ADDITION, TO CLARIFY WHETHER THE EPIGENETIC SILENCING IS AFFECTED BY BCR-ABL1 INHIBITION, WE ASSESSED THE METHYLATION STATUS IN THE PATIENTS AT DIFFERENT TIME INTERVALS FOLLOWING THE TYROSINE KINASE INHIBITION USING IMATINIB THERAPY, AS THE FIRST-LINE TREATMENT FOR THIS TYPE OF LEUKEMIA. METHODS: TO ADDRESS THIS ISSUE, WE APPLIED BISULFITE-SEQUENCING TECHNIQUE AS A HIGH-RESOLUTION METHOD TO STUDY THE REGULATORY SEGMENT OF THE CCN3 GENE. THE RESULTS WERE ANALYZED IN NEWLY DIAGNOSED CML PATIENTS AS WELL AS FOLLOWING IMATINIB THERAPY. WE ALSO EVALUATED THE CORRELATION OF CCN3 PROMOTER METHYLATION WITH BCR-ABL1 LEVELS. RESULTS: OUR FINDINGS REVEALED THAT THE METHYLATION OCCURS FREQUENTLY IN THE PROMOTER REGION OF CML PATIENTS SHOWING A SIGNIFICANT INCREASE OF THE METHYLATED PERCENTAGE AT THE CPG SITES COMPARED TO NORMAL INDIVIDUALS. INTERESTINGLY, THIS HYPERMETHYLATION WAS INDICATED TO BE INDEPENDENT OF BCR-ABL1 TITERS IN BOTH GROUPS, WHICH MIGHT SUGGEST A MECHANISM BEYOND THE BCR-ABL1 FUNCTION. CONCLUSION: DESPITE SUGGESTING THAT THE CCN3 HYPERMETHYLATION ACTS AS A MOLECULAR MECHANISM INDEPENDENT OF BCR-ABL1 FUNCTION IN CML PATIENTS, THIS SCENARIO REQUIRES FURTHER VALIDATION BY COMPLEMENTARY EXPERIMENTS. IN THE CASE OF ACTING UPSTREAM OF BCR-ABL1 SIGNALING, THE METHYLATION MARKER CAN PROVIDE EARLY DETECTION AND A NOVEL PLATFORM FOR TARGETED EPIGENETIC MODIFIERS FOR EFFICIENT TREATMENT IN IMATINIB RESISTANT PATIENTS. 2019 13 535 39 ASXL1 MUTATION CORRECTION BY CRISPR/CAS9 RESTORES GENE FUNCTION IN LEUKEMIA CELLS AND INCREASES SURVIVAL IN MOUSE XENOGRAFTS. RECURRENT SOMATIC MUTATIONS OF THE EPIGENETIC MODIFIER AND TUMOR SUPPRESSOR ASXL1 ARE COMMON IN MYELOID MALIGNANCIES, INCLUDING CHRONIC MYELOID LEUKEMIA (CML), AND ARE ASSOCIATED WITH POOR CLINICAL OUTCOME. CRISPR/CAS9 HAS RECENTLY EMERGED AS A POWERFUL AND VERSATILE GENOME EDITING TOOL FOR GENOME ENGINEERING IN VARIOUS SPECIES. WE HAVE USED THE CRISPR/CAS9 SYSTEM TO CORRECT THE ASXL1 HOMOZYGOUS NONSENSE MUTATION PRESENT IN THE CML CELL LINE KBM5, WHICH LACKS ASXL1 PROTEIN EXPRESSION. CRISPR/CAS9-MEDIATED ASXL1 HOMOZYGOUS CORRECTION RESULTED IN PROTEIN RE-EXPRESSION WITH RESTORED NORMAL FUNCTION, INCLUDING DOWN-REGULATION OF POLYCOMB REPRESSIVE COMPLEX 2 TARGET GENES. SIGNIFICANTLY REDUCED CELL GROWTH AND INCREASED MYELOID DIFFERENTIATION WERE OBSERVED IN ASXL1 MUTATION-CORRECTED CELLS, PROVIDING NEW INSIGHTS INTO THE ROLE OF ASXL1 IN HUMAN MYELOID CELL DIFFERENTIATION. MICE XENOGRAFTED WITH MUTATION-CORRECTED KBM5 CELLS SHOWED SIGNIFICANTLY LONGER SURVIVAL THAN UNCORRECTED XENOGRAFTS. THESE RESULTS SHOW THAT THE SOLE CORRECTION OF A DRIVER MUTATION IN LEUKEMIA CELLS INCREASES SURVIVAL IN VIVO IN MICE. THIS STUDY PROVIDES PROOF-OF-CONCEPT FOR DRIVER GENE MUTATION CORRECTION VIA CRISPR/CAS9 TECHNOLOGY IN HUMAN LEUKEMIA CELLS AND PRESENTS A STRATEGY TO ILLUMINATE THE IMPACT OF ONCOGENIC MUTATIONS ON CELLULAR FUNCTION AND SURVIVAL. 2015 14 851 23 CHIP-SEQ ANALYSIS OF HUMAN CHRONIC MYELOID LEUKEMIA CELLS. MANY TRANSCRIPTION FACTORS, CHROMATIN-ASSOCIATED PROTEINS AND REGULATORY DNA ELEMENTS ARE GENETICALLY AND/OR EPIGENETICALLY ALTERED IN CANCER, INCLUDING CHRONIC MYELOID LEUKEMIA (CML). THIS LEADS TO DEREGULATION OF TRANSCRIPTION THAT IS OFTEN CAUSALLY LINKED TO THE TUMORIGENIC STATE. CHROMATIN-IMMUNOPRECIPITATION COUPLED WITH MASSIVELY PARALLEL DNA SEQUENCING (CHIP-SEQ) IS THE KEY TECHNOLOGY TO STUDY TRANSCRIPTION AS IT ALLOWS IN VIVO WHOLE-GENOME MAPPING OF EPIGENETIC MODIFICATIONS AND INTERACTIONS OF PROTEINS WITH DNA OR CHROMATIN. HOWEVER, NUMEROUS DNA/CHROMATIN-BINDING PROTEINS, INCLUDING EZH2, REMAIN DIFFICULT TO "CHIP," THUS YIELDING GENOME-WIDE BINDING MAPS OF ONLY SUBOPTIMAL QUALITY. HERE, WE DESCRIBE A CHIP-SEQ PROTOCOL OPTIMIZED FOR HIGH-QUALITY PROTEIN-GENOME BINDING MAPS THAT HAVE PROVEN ESPECIALLY USEFUL FOR STUDYING DIFFICULT TO 'CHIP' TRANSCRIPTION REGULATORY FACTORS IN CHRONIC MYELOID LEUKEMIA (CML) AND RELATED MALIGNANCIES. 2016 15 3918 31 LINKING ABERRANT CHROMATIN FEATURES IN CHRONIC LYMPHOCYTIC LEUKEMIA TO TRANSCRIPTION FACTOR NETWORKS. IN CHRONIC LYMPHOCYTIC LEUKEMIA (CLL), A DIVERSE SET OF GENETIC MUTATIONS IS EMBEDDED IN A DEREGULATED EPIGENETIC LANDSCAPE THAT DRIVES CANCEROGENESIS. TO ELUCIDATE THE ROLE OF ABERRANT CHROMATIN FEATURES, WE MAPPED DNA METHYLATION, SEVEN HISTONE MODIFICATIONS, NUCLEOSOME POSITIONS, CHROMATIN ACCESSIBILITY, BINDING OF EBF1 AND CTCF, AS WELL AS THE TRANSCRIPTOME OF B CELLS FROM CLL PATIENTS AND HEALTHY DONORS. A GLOBALLY INCREASED HISTONE DEACETYLASE ACTIVITY WAS DETECTED AND HALF OF THE GENOME COMPRISED TRANSCRIPTIONALLY DOWNREGULATED PARTIALLY DNA METHYLATED DOMAINS DEMARCATED BY CTCF CLL SAMPLES DISPLAYED A H3K4ME3 REDISTRIBUTION AND NUCLEOSOME GAIN AT PROMOTERS AS WELL AS CHANGES OF ENHANCER ACTIVITY AND ENHANCER LINKAGE TO TARGET GENES. A DNA BINDING MOTIF ANALYSIS IDENTIFIED TRANSCRIPTION FACTORS THAT GAINED OR LOST BINDING IN CLL AT SITES WITH ABERRANT CHROMATIN FEATURES. THESE FINDINGS WERE INTEGRATED INTO A GENE REGULATORY ENHANCER CONTAINING NETWORK ENRICHED FOR B-CELL RECEPTOR SIGNALING PATHWAY COMPONENTS. OUR STUDY PREDICTS NOVEL MOLECULAR LINKS TO TARGETS OF CLL THERAPIES AND PROVIDES A VALUABLE RESOURCE FOR FURTHER STUDIES ON THE EPIGENETIC CONTRIBUTION TO THE DISEASE. 2019 16 390 34 AN INTEGRATIVE MODEL OF PATHWAY CONVERGENCE IN GENETICALLY HETEROGENEOUS BLAST CRISIS CHRONIC MYELOID LEUKEMIA. TARGETED THERAPIES AGAINST THE BCR-ABL1 KINASE HAVE REVOLUTIONIZED TREATMENT OF CHRONIC PHASE (CP) CHRONIC MYELOID LEUKEMIA (CML). IN CONTRAST, MANAGEMENT OF BLAST CRISIS (BC) CML REMAINS CHALLENGING BECAUSE BC CELLS ACQUIRE COMPLEX MOLECULAR ALTERATIONS THAT CONFER STEMNESS FEATURES TO PROGENITOR POPULATIONS AND RESISTANCE TO BCR-ABL1 TYROSINE KINASE INHIBITORS. COMPREHENSIVE MODELS OF BC TRANSFORMATION HAVE PROVED ELUSIVE BECAUSE OF THE RARITY AND GENETIC HETEROGENEITY OF BC, BUT ARE IMPORTANT FOR DEVELOPING BIOMARKERS PREDICTING BC PROGRESSION AND EFFECTIVE THERAPIES. TO BETTER UNDERSTAND BC, WE PERFORMED AN INTEGRATED MULTIOMICS ANALYSIS OF 74 CP AND BC SAMPLES USING WHOLE-GENOME AND EXOME SEQUENCING, TRANSCRIPTOME AND METHYLOME PROFILING, AND CHROMATIN IMMUNOPRECIPITATION FOLLOWED BY HIGH-THROUGHPUT SEQUENCING. EMPLOYING PATHWAY-BASED ANALYSIS, WE FOUND THE BC GENOME WAS SIGNIFICANTLY ENRICHED FOR MUTATIONS AFFECTING COMPONENTS OF THE POLYCOMB REPRESSIVE COMPLEX (PRC) PATHWAY. WHILE TRANSCRIPTOMICALLY, BC PROGENITORS WERE ENRICHED AND DEPLETED FOR PRC1- AND PRC2-RELATED GENE SETS RESPECTIVELY. BY INTEGRATING OUR DATA SETS, WE DETERMINED THAT BC PROGENITORS UNDERGO PRC-DRIVEN EPIGENETIC REPROGRAMMING TOWARD A CONVERGENT TRANSCRIPTOMIC STATE. SPECIFICALLY, PRC2 DIRECTS BC DNA HYPERMETHYLATION, WHICH IN TURN SILENCES KEY GENES INVOLVED IN MYELOID DIFFERENTIATION AND TUMOR SUPPRESSOR FUNCTION VIA SO-CALLED EPIGENETIC SWITCHING, WHEREAS PRC1 REPRESSES AN OVERLAPPING AND DISTINCT SET OF GENES, INCLUDING NOVEL BC TUMOR SUPPRESSORS. ON THE BASIS OF THESE OBSERVATIONS, WE DEVELOPED AN INTEGRATED MODEL OF BC THAT FACILITATED THE IDENTIFICATION OF COMBINATORIAL THERAPIES CAPABLE OF REVERSING BC REPROGRAMMING (DECITABINE+PRC1 INHIBITORS), NOVEL PRC-SILENCED TUMOR SUPPRESSOR GENES (NR4A2), AND GENE EXPRESSION SIGNATURES PREDICTIVE OF DISEASE PROGRESSION AND DRUG RESISTANCE IN CP. 2020 17 4728 28 NOTCH SIGNALING PROMOTES DISEASE INITIATION AND PROGRESSION IN MURINE CHRONIC LYMPHOCYTIC LEUKEMIA. NOTCH1 GAIN-OF-FUNCTION MUTATIONS ARE RECURRENT IN B-CELL CHRONIC LYMPHOCYTIC LEUKEMIA (B-CLL), WHERE THEY ARE ASSOCIATED WITH ACCELERATED DISEASE PROGRESSION AND REFRACTORINESS TO CHEMOTHERAPY. THE SPECIFIC ROLE OF NOTCH1 IN THE DEVELOPMENT AND PROGRESSION OF THIS MALIGNANCY IS UNCLEAR. HERE, WE ASSESS THE IMPACT OF LOSS OF NOTCH SIGNALING AND PATHWAY HYPERACTIVATION IN AN IN VIVO MOUSE MODEL OF CLL (IGH.TEMU) THAT FAITHFULLY REPLICATES MANY FEATURES OF THE HUMAN PATHOLOGY. ABLATION OF CANONICAL NOTCH SIGNALING USING CONDITIONAL GENE INACTIVATION OF RBP-J IN IMMATURE HEMATOPOIETIC OR B-CELL PROGENITORS DELAYED CLL INDUCTION AND REDUCED INCIDENCE OF MICE DEVELOPING DISEASE. IN CONTRAST, FORCED EXPRESSION OF A DOMINANT ACTIVE FORM OF NOTCH RESULTED IN MORE ANIMALS DEVELOPING CLL WITH EARLY DISEASE ONSET. COMPARATIVE ANALYSIS OF GENE EXPRESSION AND EPIGENETIC FEATURES OF NOTCH GAIN-OF-FUNCTION AND CONTROL CLL CELLS REVEALED DIRECT AND INDIRECT REGULATION OF CELL CYCLE-ASSOCIATED GENES, WHICH LED TO INCREASED PROLIFERATION OF NOTCH GAIN-OF-FUNCTION CLL CELLS IN VIVO. THESE RESULTS DEMONSTRATE THAT NOTCH SIGNALING FACILITATES DISEASE INITIATION AND PROMOTES CLL CELL PROLIFERATION AND DISEASE PROGRESSION. 2021 18 2025 29 EPIGENETIC CHANGES DURING DISEASE PROGRESSION IN A MURINE MODEL OF HUMAN CHRONIC LYMPHOCYTIC LEUKEMIA. EPIGENETIC ALTERATIONS, INCLUDING GAIN OR LOSS OF DNA METHYLATION, ARE A HALLMARK OF NEARLY EVERY MALIGNANCY. CHANGES IN DNA METHYLATION CAN IMPACT EXPRESSION OF CANCER-RELATED GENES INCLUDING APOPTOSIS REGULATORS AND TUMOR SUPPRESSORS. BECAUSE SUCH EPIGENETIC CHANGES ARE REVERSIBLE, THEY ARE BEING AGGRESSIVELY INVESTIGATED AS POTENTIAL THERAPEUTIC TARGETS. HERE WE USE THE EMU-TCL1 TRANSGENIC MOUSE MODEL OF CHRONIC LYMPHOCYTIC LEUKEMIA (CLL) TO DETERMINE THE TIMING AND PATTERNS OF ABERRANT DNA METHYLATION, AND TO INVESTIGATE THE MECHANISMS THAT LEAD TO ABERRANT DNA METHYLATION. WE SHOW THAT CLL CELLS FROM EMU-TCL1 MICE AT VARIOUS STAGES RECAPITULATE EPIGENETIC ALTERATIONS SEEN IN HUMAN CLL. ABERRANT METHYLATION OF PROMOTER SEQUENCES IS OBSERVED AS EARLY AS 3 MONTHS OF AGE IN THESE ANIMALS, WELL BEFORE DISEASE ONSET. ABNORMALLY METHYLATED PROMOTER REGIONS INCLUDE BINDING SITES FOR THE TRANSCRIPTION FACTOR FOXD3. WE SHOW THAT LOSS OF FOXD3 EXPRESSION DUE TO AN NF-KAPPAB P50/P50:HDAC1 REPRESSOR COMPLEX OCCURS IN TCL1-POSITIVE B CELLS BEFORE METHYLATION. THEREFORE, SPECIFIC TRANSCRIPTIONAL REPRESSION IS AN EARLY EVENT LEADING TO EPIGENETIC SILENCING OF TARGET GENES IN MURINE AND HUMAN CLL. THESE RESULTS PROVIDE STRONG RATIONALE FOR THE DEVELOPMENT OF STRATEGIES TO TARGET NF-KAPPAB COMPONENTS IN CLL AND POTENTIALLY OTHER B-CELL MALIGNANCIES. 2009 19 1976 23 EPIGENETIC ALTERATIONS IN A MURINE MODEL FOR CHRONIC LYMPHOCYTIC LEUKEMIA. EARLY STAGES IN THE DEVELOPMENT OF CHRONIC LYMPHOCYTIC LEUKEMIA (CLL) HAVE NOT BEEN EXPLORED MAINLY DUE TO THE INABILITY TO STUDY NORMAL B-CELLS EN ROUTE TO TRANSFORMATION. IN ORDER TO DETERMINE SUCH EARLY EVENTS OF LEUKEMOGENESIS, WE HAVE USED A WELL ESTABLISHED MOUSE MODEL FOR CLL. OVER-EXPRESSION OF HUMAN TCL1, A KNOWN CLL ONCOGENE IN MURINE B-CELLS LEADS TO THE DEVELOPMENT OF MATURE CD19+/CD5+/IGM+ CLONAL LEUKEMIA WITH A DISEASE PHENOTYPE SIMILAR TO THAT SEEN IN HUMAN CLL. HEREIN, WE REVIEW OUR RECENT STUDY USING THIS TCL1-DRIVEN MOUSE MODEL FOR CLL AND CORRESPONDING HUMAN CLL SAMPLES IN A CROSS-SPECIES EPIGENOMICS APPROACH TO ADDRESS THE TIMING AND RELEVANCE OF EPIGENETIC EVENTS OCCURRING DURING LEUKEMOGENESIS. WE DEMONSTRATED THAT THE MOUSE MODEL RECAPITULATES THE EPIGENETIC EVENTS THAT HAVE BEEN REPORTED FOR HUMAN CLL, AFFIRMING THE POWER AND VALIDITY OF THIS MOUSE MODEL TO STUDY EARLY EPIGENETIC EVENTS IN CANCER PROGRESSION. EPIGENETIC ALTERATIONS ARE DETECTED AS EARLY AS THREE MONTHS AFTER BIRTH, FAR BEFORE DISEASE MANIFESTS AT ABOUT 11 MONTHS OF AGE. THESE MICE UNDERGO NFKAPPAB REPRESSOR COMPLEX MEDIATED INACTIVATION OF THE TRANSCRIPTION FACTOR FOXD3, WHOSE TARGETS BECOME ABERRANTLY METHYLATED AND SILENCED IN MOUSE AND HUMAN CLL. OVERALL, OUR DATA SUGGEST THE ACCUMULATED EPIGENETIC ALTERATIONS DURING CLL PATHOGENESIS AS A CONSEQUENCE OF GENE SILENCING THROUGH TCL1 AND NFKAPPAB REPRESSOR COMPLEX, SUGGESTING THE RELEVANCE FOR NFKAPPAB AS A THERAPEUTIC TARGET IN CLL. 2009 20 1542 38 DNA METHYLATION IN HAEMATOLOGICAL MALIGNANCIES: THE ROLE OF DECITABINE. NORMAL CELL DEVELOPMENT AND FUNCTION IS DEPENDENT UPON CONTROLLED GENE EXPRESSION. DNA METHYLATION IS AN EPIGENETIC MODIFICATION THAT CAN PLAY AN IMPORTANT ROLE IN THE CONTROL OF GENE EXPRESSION. DNA METHYLATION AT CYTOSINE RESIDUES IN GENE PROMOTER CPG SEQUENCES IS KNOWN TO INHIBIT GENE TRANSCRIPTION. INAPPROPRIATE INHIBITION OF THE TRANSCRIPTION OF TUMOUR SUPPRESSOR GENES, GENES THAT INHIBIT ANGIOGENESIS AND METASTASIS AND GENES INVOLVED IN DNA REPAIR BY UNCONTROLLED METHYLATION, CAN LEAD TO UNREGULATED GROWTH AND PROLIFERATION OF A CELL AND CARCINOGENESIS. PROMOTER HYPERMETHYLATION AFFECTING THE P16 GENE, RESULTING IN GENE SILENCING, HAS BEEN SHOWN TO OCCUR IN MANY HUMAN SOLID TUMOURS AND A 'HYPERMETHYLATION PROFILE' IN SOME LEUKAEMIAS HAS BEEN DEFINED. THE MOLECULAR MECHANISMS BY WHICH ABERRANT DNA METHYLATION TAKES PLACE DURING CARCINOGENESIS ARE STILL NOT CLEAR. HOWEVER, THE LARGE NUMBER OF TARGET GENES (INVOLVED IN TUMORIGENESIS) THAT ARE SILENCED BY ABERRANT METHYLATION SUGGESTS THAT INHIBITION OF THIS PROCESS MAY HAVE POTENTIAL AS CANCER THERAPY. DECITABINE (NSC-127716, DACOGEN; SUPERGEN) IS A POTENT AND SPECIFIC HYPOMETHYLATING AGENT AND AN INHIBITOR OF THE DNA METHYLTRANSFERASE ACTIVITY THAT MEDIATES DNA METHYLATION. DECITABINE HAS BEEN SHOWN TO HAVE A BROAD RANGE OF ANTINEOPLASTIC ACTIVITY IN PRECLINICAL STUDIES. THIS AGENT HAS EXHIBITED SIGNIFICANT ACTIVITY IN THE TREATMENT OF PATIENTS WITH MYELODYSPLASTIC SYNDROME, CHRONIC MYELOID LEUKAEMIA AND ACUTE MYELOID LEUKAEMIA, ALTHOUGH CLINICAL PHASE I AND II STUDIES WITH SOLID TUMOURS HAVE NOT BEEN VERY PROMISING. PHASE II AND III STUDIES ARE CURRENTLY ONGOING TO EVALUATE DECITABINE, BOTH ALONE AND IN COMBINATION, IN VARIOUS STAGES OF THESE HAEMATOLOGICAL MALIGNANCIES. 2003