Project description:Recently, the H3K4 demethylase, KDM5B, was shown to be amplified and overexpressed in luminal breast cancer, suggesting it might constitute a potential cancer therapy target. Here, we characterize, in breast cancer cells, the molecular effects of a recently developed small-molecule inhibitor of the KDM5 family of proteins, either alone, or in combination with the DNA demethylating agent 5-aza-2’ deoxycytidine (DAC). To determine the effects of these compounds on global gene expression, we used the Agilend Whole Human Genome 4x44k v2 Microarray. We found that alone, the KDM5 inhibitor (KDM5i) increased expression of a small number of genes, but when combined with DAC, the drug enhanced the effects of the latter for increasing expression of hundreds of DAC responsive genes.

Project description:Recently, the H3K4 demethylase, KDM5B, was shown to be amplified and overexpressed in luminal breast cancer, suggesting it might constitute a potential cancer therapy target. Here, we characterize, in breast cancer cells, the molecular effects of a recently developed small-molecule inhibitor of the KDM5 family of proteins, either alone, or in combination with the DNA demethylating agent 5-aza-2’ deoxycytidine (DAC). Alone, the KDM5 inhibitor (KDM5i) increased expression of a small number of genes, but when combined with DAC, the drug enhanced the effects of the latter for increasing expression of hundreds of DAC responsive genes. To determine if this combinatorial action was the result of enhanced DNA demethylation, we profiled genome-wide DNA methylation in cells treated with KDM5i, DAC, or both. Methylation levels at approximately 450,000 unique CpG loci were detected using the Infinium Illumina HumanMethylation 450 array. We found that KDM5i did not significantly affect DNA methylation either alone, or in combination with DAC.

Project description:The KDM5B histone H3 lysine 4 (H3K4) demethylase has been implicated in therapy resistance in multiple cancer types including breast cancer, but the underlying mechanism is poorly defined. Here we show that inhibition of KDM5B activity increases sensitivity to anti-estrogens by modulating estrogen-receptor (ER) signaling. Conversely, acquired resistance to KDM5 inhibitors leads to gain of ER chromatin binding and estrogen-independent growth. Sequencing of barcoded cell populations and mathematical modeling demonstrate selection for pre-existent genetically distinct endocrine-resistant cells, while resistance to KDM5 inhibitors is a switch to an acquired epigenetic state. Rare resistant cells can already be detected by single cell RNA-seq prior to treatment. Inhibition of KDM5B in luminal ER+ cells increases H3K4me3 broad domains at promoters and decreases cellular transcriptional heterogeneity. Higher transcriptome heterogeneity is associated with higher KDM5B levels and poor prognosis in ER+ luminal breast tumors.

Project description:The KDM5B histone H3 lysine 4 (H3K4) demethylase has been implicated in therapy resistance in multiple cancer types including breast cancer, but the underlying mechanism is poorly defined. Here we show that inhibition of KDM5B activity increases sensitivity to anti-estrogens by modulating estrogen-receptor (ER) signaling. Conversely, acquired resistance to KDM5 inhibitors leads to gain of ER chromatin binding and estrogen-independent growth. Sequencing of barcoded cell populations and mathematical modeling demonstrate selection for pre-existent genetically distinct endocrine-resistant cells, while resistance to KDM5 inhibitors is a switch to an acquired epigenetic state. Rare resistant cells can already be detected by single cell RNA-seq prior to treatment. Inhibition of KDM5B in luminal ER+ cells increases H3K4me3 broad domains at promoters and decreases cellular transcriptional heterogeneity. Higher transcriptome heterogeneity is associated with higher KDM5B levels and poor prognosis in ER+ luminal breast tumors.

Project description:The KDM5B histone H3 lysine 4 (H3K4) demethylase has been implicated in therapy resistance in multiple cancer types including breast cancer, but the underlying mechanism is poorly defined. Here we show that inhibition of KDM5B activity increases sensitivity to anti-estrogens by modulating estrogen-receptor (ER) signaling. Conversely, acquired resistance to KDM5 inhibitors leads to gain of ER chromatin binding and estrogen-independent growth. Sequencing of barcoded cell populations and mathematical modeling demonstrate selection for pre-existent genetically distinct endocrine-resistant cells, while resistance to KDM5 inhibitors is a switch to an acquired epigenetic state. Rare resistant cells can already be detected by single cell RNA-seq prior to treatment. Inhibition of KDM5B in luminal ER+ cells increases H3K4me3 broad domains at promoters and decreases cellular transcriptional heterogeneity. Higher transcriptome heterogeneity is associated with higher KDM5B levels and poor prognosis in ER+ luminal breast tumors.

Project description:The KDM5B histone H3 lysine 4 (H3K4) demethylase has been implicated in therapy resistance in multiple cancer types including breast cancer, but the underlying mechanism is poorly defined. Here we show that inhibition of KDM5B activity increases sensitivity to anti-estrogens by modulating estrogen-receptor (ER) signaling. Conversely, acquired resistance to KDM5 inhibitors leads to gain of ER chromatin binding and estrogen-independent growth. Sequencing of barcoded cell populations and mathematical modeling demonstrate selection for pre-existent genetically distinct endocrine-resistant cells, while resistance to KDM5 inhibitors is a switch to an acquired epigenetic state. Rare resistant cells can already be detected by single cell RNA-seq prior to treatment. Inhibition of KDM5B in luminal ER+ cells increases H3K4me3 broad domains at promoters and decreases cellular transcriptional heterogeneity. Higher transcriptome heterogeneity is associated with higher KDM5B levels and poor prognosis in ER+ luminal breast tumors.

Project description:The KDM5B histone H3 lysine 4 (H3K4) demethylase has been implicated in therapy resistance in multiple cancer types including breast cancer, but the underlying mechanism is poorly defined. Here we show that inhibition of KDM5B activity increases sensitivity to anti-estrogens by modulating estrogen-receptor (ER) signaling. Conversely, acquired resistance to KDM5 inhibitors leads to gain of ER chromatin binding and estrogen-independent growth. Sequencing of barcoded cell populations and mathematical modeling demonstrate selection for pre-existent genetically distinct endocrine-resistant cells, while resistance to KDM5 inhibitors is a switch to an acquired epigenetic state. Rare resistant cells can already be detected by single cell RNA-seq prior to treatment. Inhibition of KDM5B in luminal ER+ cells increases H3K4me3 broad domains at promoters and decreases cellular transcriptional heterogeneity. Higher transcriptome heterogeneity is associated with higher KDM5B levels and poor prognosis in ER+ luminal breast tumors.

Project description:The KDM5B histone H3 lysine 4 (H3K4) demethylase has been implicated in therapy resistance in multiple cancer types including breast cancer, but the underlying mechanism is poorly defined. Here we show that inhibition of KDM5B activity increases sensitivity to anti-estrogens by modulating estrogen-receptor (ER) signaling. Conversely, acquired resistance to KDM5 inhibitors leads to gain of ER chromatin binding and estrogen-independent growth. Sequencing of barcoded cell populations and mathematical modeling demonstrate selection for pre-existent genetically distinct endocrine-resistant cells, while resistance to KDM5 inhibitors is a switch to an acquired epigenetic state. Rare resistant cells can already be detected by single cell RNA-seq prior to treatment. Inhibition of KDM5B in luminal ER+ cells increases H3K4me3 broad domains at promoters and decreases cellular transcriptional heterogeneity. Higher transcriptome heterogeneity is associated with higher KDM5B levels and poor prognosis in ER+ luminal breast tumors.

Project description:Alterations in the histone methylation profiles are observed in various types of cancer and targeting of this epigenetic process has therapeutic potential. Here we provide proof-of-principle that pharmacological targeting of KDM5 histone-demethylases is a new strategy for the personalized treatment of HER2-positive breast cancer. This analysis demonstrates that cells characterized by HER2-positivity are particularly sensitive to KDM5 inhibition. The results are confirmed in an appropriate in vivo model with a close structural analogue (KDM5-inh1A). In selected HER2-positive breast cancer cells, we demonstrate synergistic interactions between KDM5-inh1 and HER2-targeting agents (trastuzumab and lapatinib). In addition, HER2-positive cell lines showing innate/acquired resistance to trastuzumab show sensitivity to KDM5-inh1. The levels of KDM5A/B/C proteins, which are selectively targeted by the agent, have no significant association with KDM5-inh1 responsiveness across our panel of breast cancer cell lines, suggesting the existence of other determinants of sensitivity. Using RNA-sequencing data of the breast cancer cell lines, we generate a gene-expression model, consisting of fifteen genes, which is a robust predictor of KDM5-inh1 sensitivity. In a test set of breast cancers, this model correctly predicts sensitivity to the compound in a large fraction of HER2+ tumors. In conclusion, KDM5 inhibition has potential in the treatment of HER2+ breast cancer and our gene-expression model can be developed into a diagnostic tool to select patients who may benefit from treatments based on KDM5-inhibitors.

Project description:To determine which genes affected by loss of KDM5 in adults were direct targets, we carried out KDM5 ChIP-seq analyses. To valide this data, we utilized a previously generated fly strain in which the sole source of KDM5 is from a transgene expressing an HA tagged form of KDM5 expressed under the control of its endogenous promoter. Comparing genome-wide gene expression and KDM5 binding analyses in Drosophila adults, we demonstrate the primary function of KDM5 in adults is to activate gene expression KDM5. To investigate the link between KDM5 and H3K4me3, we carried out anti-H3K4me3 ChIP-seq from wildtype adults . Genome-wide, KDM5 and H3K4me3 peaks showed a similar distribution, with both peaking at the transcription start site (TSS) showed a striking overlap with the presence of H3K4me3. Examination of KDM5 binding and histone H3K4me3 modifications in drosophila adults