Project description:Global changes in DNA methylation are observed in several developmental and disease contexts, and single-cell analyses are beginning to reveal the heterogeneous regulation of these processes. However, these studies are limited by the poor alignment rates and high sequencing demands associated with single-cell analysis of DNA methylation. We present single-cell transposable element methylation sequencing (scTEM-seq) for cost-effective estimation of global DNA methylation levels. By targeting high-copy LINE-1 and SINE Alu elements, we achieve amplicon bisulphite sequencing with thousands of annotated loci covered in each scTEM-seq library. Parallel transcriptome analysis of the same single cell is also performed to link global DNA methylation heterogeneity with transcriptional consequences. We apply scTEM-seq to KG1a acute myeloid leukaemia (AML) cells, and primary cells from an AML patient. Treatment of KG1a cells with the hypomethylating agent, decitabine, induces global DNA methylation heterogeneity associated with altered expression of viral response pathways. We also compare global levels of DNA methylation to expression of transposable elements and find a predominance of negative correlations in both the KG1a and patient cells. Finally, we observe co-ordinated upregulation of many transposable elements in a sub-set of decitabine treated KG1a cells. These observations suggest that viral mimicry processes important for epigenetic therapy and tumour immunogenicity are variably active in AML cells. By linking global DNA methylation heterogeneity with transcriptional consequences, scTEM-seq will refine our understanding of epigenetic regulation in cancer and beyond.

Project description:Global changes in DNA methylation are observed in several developmental and disease contexts, and single-cell analyses are beginning to reveal the heterogeneous regulation of these processes. However, these studies are limited by the poor alignment rates and high sequencing demands associated with single-cell analysis of DNA methylation. We present single-cell transposable element methylation sequencing (scTEM-seq) for cost-effective estimation of global DNA methylation levels. By targeting high-copy LINE-1 and SINE Alu elements, we achieve amplicon bisulphite sequencing with thousands of annotated loci covered in each scTEM-seq library. Parallel transcriptome analysis of the same single cell is also performed to link global DNA methylation heterogeneity with transcriptional consequences. We apply scTEM-seq to KG1a acute myeloid leukaemia (AML) cells, and primary cells from an AML patient. Treatment of KG1a cells with the hypomethylating agent, decitabine, induces global DNA methylation heterogeneity associated with altered expression of viral response pathways. We also compare global levels of DNA methylation to expression of transposable elements and find a predominance of negative correlations in both the KG1a and patient cells. Finally, we observe co-ordinated upregulation of many transposable elements in a sub-set of decitabine treated KG1a cells. These observations suggest that viral mimicry processes important for epigenetic therapy and tumour immunogenicity are variably active in AML cells. By linking global DNA methylation heterogeneity with transcriptional consequences, scTEM-seq will refine our understanding of epigenetic regulation in cancer and beyond.

Project description:Global changes in DNA methylation are observed in several developmental and disease contexts, and single-cell analyses are beginning to reveal the heterogeneous regulation of these processes. However, these studies are limited by the poor alignment rates and high sequencing demands associated with single-cell analysis of DNA methylation. We present single-cell transposable element methylation sequencing (scTEM-seq) for cost-effective estimation of global DNA methylation levels. By targeting high-copy LINE-1 and SINE Alu elements, we achieve amplicon bisulphite sequencing with thousands of annotated loci covered in each scTEM-seq library. Parallel transcriptome analysis of the same single cell is also performed to link global DNA methylation heterogeneity with transcriptional consequences. We apply scTEM-seq to KG1a acute myeloid leukaemia (AML) cells, and primary cells from an AML patient. Treatment of KG1a cells with the hypomethylating agent, decitabine, induces global DNA methylation heterogeneity associated with altered expression of viral response pathways. We also compare global levels of DNA methylation to expression of transposable elements and find a predominance of negative correlations in both the KG1a and patient cells. Finally, we observe co-ordinated upregulation of many transposable elements in a sub-set of decitabine treated KG1a cells. These observations suggest that viral mimicry processes important for epigenetic therapy and tumour immunogenicity are variably active in AML cells. By linking global DNA methylation heterogeneity with transcriptional consequences, scTEM-seq will refine our understanding of epigenetic regulation in cancer and beyond.

Project description:Global DNA methylation was analyzed in total bone marrow cells of AML/MDS patients undergoing decitabine treatment.

Project description:We employed the AML cell line model U937 to determine the effects of single and dual treatment with the HMA decitabine and the HDACi Pano or VPA on gene expression and DNA methylation. We noted global alterations of gene expression and a massive effect on the methylome.

Project description:We employed the AML cell line model U937 to determine the effects of single and dual treatment with the HMA decitabine and the HDACi Pano or VPA on gene expression and DNA methylation. We noted global alterations of gene expression and a massive effect on the methylome.

Project description:The DNA hypomethylating drug decitabine maintains normal hematopoietic stem and progenitor cell (HSPC) self-renewal but induces terminal differentiation in acute myeloid leukemia (AML) cells. To better understand the basis for this contrasting treatment effect, the baseline expression of key lineage-specifying transcription factor (TF) (eg., CEBPa) and key late differentiation TF (CEBPe), was examined in normal, myelodysplastic (MDS) and AML primary cells and cell lines. To appreciate the role of differentiation in hypomethylation of some CpG by decitabine treatment but not others, promoter CpGs, analyzed by microarray and mass spectrometry, were categorized by the direction of methylation change during normal myeloid differentiation. In MDS/AML cells, high expression of CEBPa, relatively low expression of CEBPe (a gene target of CEBPa), hypermethylation of CEBPe promoter CpG, and the methylation pattern at differentiation sensitive promoter CpGs analyzed by microarray, suggested lineage-commitment and aberrant epigenetic repression of late differentiation genes. DNA hypomethylation in response to decitabine was greatest at CpGs that are hypomethylated during normal myeloid differentiation. In contrast, normal HSPC treated with decitabine retained immature morphology, and methylation significantly decreased at CpG that are hypermethylated during myeloid differentiation. Partial differentiation at baseline, and repression of key late differentiation genes by epigenetic means, likely plays a role in methylation and phenotype responses of AML cells treated with decitabine. Bisulphite converted DNA from the 208 samples were hybridised to the Illumina Cancel Panel 1 GPL9183 methylation assay

Project description:We found previously that the effect of decitabine (DAC) on hematopoietic stem cell viability differed between Mll5 wildtype and null cells. We therefore investigated the role of MLL5 expression levels on outcome of AML patients who were treated with decitabine. High MLL5 expressing AML patients have improved overall survival when treated with decitabine. In transformed murine cells, loss of Mll5 was associated with resistance to low-dose decitabine, less frequent promoter methylation, and reduced demethylation upon decitabine treatment. These data suggest a biological link between MLL5 expression and decitabine response involving regulation of DNA methylation. Leukemia cell model was generated by co-transfer of HOXA9 and MEIS1 into Mll5 wildtype or knockout mouse bone marrow cells. MeDIP was performed in Mll5+/+ HOXA9/MEIS1 and Mll5-/- HOXA9/MEIS1 leukemic cells, untreated or treated with 3-day exposure of 20 nM decitabine, triplicate for each condition. MeDIP-enriched DNA was amplified with the GenomePlex Complete Whole Genome Amplification (WGA) Kit (Sigma-Aldrich). DNA from three MeDIP and WGA of each cell type and treatment was pooled for subsequent microarray analysis. The enriched DNA and corresponding input genomic DNA was labeled, hybridized and scanned on Agilent custom mouse promoter microarrays (Agilent-025976 AP_1M_Custom_CH3, assembly build mm9). The methylation value of individual probes was defined by the signal intensity ratio of MeDIP DNA (Cy3) compared to input DNA (Cy5) . Methylated DNA immunoprecipitation coupled with Agilent mouse promoter CpG arrays (MeDIP-chip)

Project description:We assessed global gene expression changes in nelarabine (NEL)-treated AML cell lines (U937 and KG1A)

Project description:We assessed global gene expression changes in 2'-deoxyguanosine (dG)-treated AML cell lines (U937 and KG1A)