We looked at a disease-associated macrosatellite array D4Z4 and focused on epigenetic factors influencing its chromatin state outside of the disease-context. We used the HCT116 cell line that contains the non-canonical polyadenylation (poly-A) signal required to stabilize somatic transcripts of the human double homeobox gene DUX4, encoded from D4Z4. In HCT116, D4Z4 is packaged into constitutive heterochromatin, characterized by DNA methylation and histone H3 tri-methylation at lysine 9 (H3K9me3), resulting in low basal levels of D4Z4-derived transcripts. However, a double knockout (DKO) of DNA methyltransferase genes, DNMT1 and DNMT3B, but not either alone, results in significant loss of DNA and H3K9 methylation. This is coupled with upregulation of transcript levels from the array, including DUX4 isoforms (DUX4-fl) that are abnormally expressed in somatic muscle in the disease Facioscapulohumeral muscular dystrophy (FSHD) along with DUX4 protein, as indicated indirectly by upregulation of bondafide targets of DUX4 in DKO but not HCT116 cells. Results from treatment with a chemical inhibitor of histone methylation in HCT116 suggest that in the absence of DNA hypomethylation, H3K9me3 loss alone is sufficient to facilitate DUX4-fl transcription. Additionally, characterization of a cell line from a patient with Immunodeficiency, Centromeric instability and Facial anomalies syndrome 1 (ICF1) possessing a non-canonical poly-A signal and DNA hypomethylation at D4Z4 showed DUX4 target gene upregulation in the patient when compared to controls in spite of retention of H3K9me3. Taken together, these data suggest that both DNA methylation and H3K9me3 are determinants of D4Z4 silencing. Moreover, we show that in addition to testis, there is appreciable expression of spliced and polyadenylated D4Z4 derived transcripts that contain the complete DUX4 open reading frame (ORF) along with DUX4 target gene expression in the thymus, suggesting that DUX4 may provide normal function in this somatic tissue.
Epithelial-mesenchymal transition (EMT) programs operate within carcinoma cells in which they generate phenotypes associated with malignant progression. In their various manifestations, EMT programs enable epithelial cells to enter into a series of intermediate states arrayed along the E-M phenotypic spectrum. At present, we lack a coherent understanding of how carcinoma cells control their entrance into and continued residence in these various states, and which of these states favor the process of metastasis. Here, we characterize a layer of EMT-regulating machinery that governs E-M plasticity (EMP). This machinery consists of two chromatin-modifying complexes, PRC2 and KMT2D-COMPASS, that operate as critical regulators to maintain a stable epithelial state. Interestingly, loss of these two complexes unlocks two distinct EMT trajectories. Dysfunction of PRC2, but not KMT2D-COMPASS, yields a quasi-mesenchymal state that is associated with highly metastatic capabilities and poor survival of breast cancer patients, suggesting great caution should be applied when PRC2 inhibitors are evaluated clinically in certain patient cohorts. These observations identify epigenetic factors that regulate E-M plasticity, determine specific intermediate EMT states and, as a direct consequence, govern the metastatic ability of carcinoma cells.
Genome-wide DNA replication timing (RT) profiles reflect the global 3D chromosome architecture of cells. They also provide a comprehensive and unique megabase-scale picture of the cellular epigenetic state. Thus normal differentiation involves reproducible changes in RT and transformation generally perturbs these, although the potential effects of altered RT on the properties of transformed cells remain largely unknown. A major challenge to interrogating these issues in human acute lymphoid leukemia (ALL) is the low proliferative activity of most of the cells, which may be further reduced in cryopreserved samples and difficult to overcome in vitro. In contrast, the ability of many human ALL cell populations to expand when transplanted in highly immunodeficient mice is well documented. To examine the stability of DNA RT profiles of serially passaged xenografts of primary human B- and T-ALL cells, we first devised a method that circumvents the need for BrdU incorporation to distinguish early versus late S-phase cells. Using this and more standard protocols, we found consistent strong retention in xenografts of the original patient-specific RT features, for all 8 primary human ALL cases surveyed (7 B-ALLs and one T-ALL). Moreover, in a case where genomic analyses indicated changing subclonal dynamics in serial passages, the RT profiles tracked concordantly. These results show that DNA RT is a relatively stable feature of human ALLs propagated in immunodeficient mice. In addition, they suggest the power of this approach for future interrogation of the origin and consequences of altered DNA RT in these diseases.
Facioscapulohumeral muscular dystrophy (FSHD) is a debilitating muscle disease that currently does not have an effective cure or therapy. The abnormal reactivation of DUX4, an embryonic gene that is epigenetically silenced in somatic tissues, is causal to FSHD. Disease-specific reactivation of DUX4 has two common characteristics, the presence of a non-canonical polyadenylation sequence within exon 3 of DUX4 that stabilizes pathogenic transcripts, and the loss of repressive chromatin modifications at D4Z4, the macrosatellite repeat which encodes DUX4. We used CRISPR/Cas9 to silence DUX4 using two independent approaches. We deleted the DUX4 pathogenic polyadenylation signal, which resulted in downregulation of pathogenic DUX4-fl transcripts. In another approach, we transcriptionally repressed DUX4 by seeding heterochromatin using the dCas9-KRAB platform within exon 3. These feasibility of targeting DUX4 experiments were initially tested in a non-myogenic carcinoma cell line that we have previously characterized. Subsequently, in an immortalized patient myoblast cell line, we demonstrated that targeting DUX4 by either approach led to substantial downregulation of not only pathogenic DUX4 transcripts, but also a subset of its target genes that are known biomarkers of FSHD. These findings offer proof-of-concept of the effect of silencing the polyadenylation sequence on pathogenic DUX4 expression.
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