Project description:Hormone receptor (HR)-positive, HER2-positive breast cancers are resistant to endocrine and anti-HER2 therapies due to crosstalk between estrogen receptor (ER) and HER2. However, how anti-HER2 agents activate ER as a mechanism of resistance remains unknown. Using single-cell RNA sequencing, we identified Bromodomain Containing Protein 8 (BRD8) as a major mediator of ER activation in response to neratinib, a HER2 tyrosine kinase inhibitor. BRD8 expression was rapidly induced by various anti-HER2 agents (neratinib, lapatinib and trastuzumab) and its expression positively correlates with ER. BRD8 regulates both ER-dependent and -independent growth promoting pathways. Moreover, BRD8 ablation re-sensitizes fulvestrant- or neratinib-resistant HR+/HER2+ cells to neratinib, suggesting that combinatorial targeting of BRD8 and HER2 attenuates signal crosstalk and possibly overcomes treatment resistance to dual anti-ER/HER2 blockade therapy. This work identifies BRD8 as not only a central hub for ER signaling activation upon anti-HER2 treatment, but also a druggable vulnerability for treating HR+/HER2+ breast cancer.

Project description:Hormone receptor (HR)-positive, HER2-positive breast cancers often develop resistance to endocrine and anti-HER2 therapies due to the heterogeneous expression of estrogen receptor (ER) and HER2 and the crosstalk of these growth-promoting pathways. However, how anti-HER2 agents activate ER and other growth-promoting pathways remains unknown. Single-cell RNA sequencing of BT474 breast cancer cells identified Bromodomain Containing Protein 8 (BRD8), an acetyl-lysine reader protein in the histone acetylase EP400 complex, as a pivotal mediator to activate ER in response to neratinib treatment. BRD8 expression was rapidly induced by various anti-HER2 agents (neratinib, lapatinib, and trastuzumab), and its depletion disrupted the crosstalk between ER and HER2 signaling pathways and rendered HR+/HER2+ cells and tumor organoids more sensitive to anti-HER2 agents. BRD8, ER, and ER target genes are co-induced by neratinib in single-nucleus (sn) RNA sequencing of a patient-derived xenograft (PDX). Concomitantly, SnATAC-seq reveals that the activated genes share open chromatin regions enriched in transcription factors (TF) binding motifs of ER, forkhead box (FOX), and ETS family. Since EP400 enhances H2AZ deposition and acetylation on chromatin, we performed H2AZ and H2AZac ChIP-sequencing in the presence or absence of BRD8 and neratinib treatment. Upon neratinib treatment, BRD8 activates ER, FOX, and ETS target genes through modulating H2AZac deposition and chromatin decompaction. This finding coincides with RNA-sequencing, where BRD8 promotes cell growth in an ER-dependent and independent manner. In line with these findings, patients who responded poorly to the anti-HER2 therapies exhibited higher BRD8 gene signatures. Furthermore, BRD8 knockdown ablates the ER and HER2 signaling crosstalk and re-sensitizes neratinib-resistant HR+/HER2+ cells to neratinib. Together, this work not only explains why ER signaling is activated upon anti-HER2 therapies but also identifies BRD8 as a druggable vulnerability in HR+/HER2+ breast cancer.

Project description:Hormone receptor (HR)-positive, HER2-positive breast cancers often develop resistance to endocrine and anti-HER2 therapies due to the heterogeneous expression of estrogen receptor (ER) and HER2 and the crosstalk of these growth-promoting pathways. However, how anti-HER2 agents activate ER and other growth-promoting pathways remains unknown. Single-cell RNA sequencing of BT474 breast cancer cells identified Bromodomain Containing Protein 8 (BRD8), an acetyl-lysine reader protein in the histone acetylase EP400 complex, as a pivotal mediator to activate ER in response to neratinib treatment. Since EP400 enhances H2AZ deposition and acetylation on chromatin, we performed H2AZ and H2AZac ChIP-sequencing in the presence or absence of BRD8 and neratinib treatment. This will help us address how BRD8 regulates ER as well as other growth factors.

Project description:Estrogen receptor positive (ER+) breast cancers that develop resistance to therapies that target the ER are the most common cause of breast cancer death. Beyond mutations in ER, which occur in 25-30% of patients treated with aromatase inhibitors (AIs), our understanding of clinical mechanisms of resistance to ER-directed therapies remains incomplete. We identified activating HER2 mutations in metastatic biopsies from eight patients with ER+ metastatic breast cancer who had developed resistance to ER-directed agents, including AIs, tamoxifen, and fulvestrant. Examination of treatment-naïve primary tumors in five patients revealed no evidence of pre-existing mutations in four of five patients, suggesting that these mutations were acquired under the selective pressure of ER-directed therapy. These mutations were mutually exclusive with ER mutations, suggesting a distinct mechanism of acquired resistance to ER-directed therapies. In vitro analysis confirmed that these mutations conferred estrogen independence. In addition, and in contrast to ER mutations, these mutations resulted in resistance to tamoxifen, fulvestrant, and the CDK4/6 inhibitor palbociclib. Resistance was overcome by combining ER-directed therapy with the irreversible HER2 kinase inhibitor neratinib, highlighting an effective treatment strategy in these patients.

Project description:In a 3D coculture with stroma cells derived from breast cancer patients’ brain metastasis, HER2+ breast cancer cells were protected from HER2-targeted therapies, particularly the EGFR/HER2 small molecule inhibitor neratinib. To get insight into how this protection arises, ATAC-seq on coculture cells with or without neratinib as performed.

Project description:Despite significant advances in HER2-targeted therapies, therapeutic resistance in HER2-positive (HER2+) breast cancer remains a significant clinical problem, especially in the metastatic setting. “Drug tolerant persisters” (DTPs), a sub-population of cancer cells that survive via reversible, non-genetic mechanisms, are implicated in resistance to tyrosine kinase inhibitors (TKIs) in several cancer models, but DTPs for HER2-targeted TKIs (e.g., lapatinib, neratinib, tucatinib) have not been characterized extensively. Here, we report that HER2+ER+ and HER2+ER- breast cancer lines give rise to distinct types of “lapatinib-DTPs,” characterized by different transcriptional programs and sensitivity to lapatinib/anti-estradiol combination. Lapatinib-DTPs from HER2+/ER+ cells rewire the PI3K/AKT/mTORC1 pathway via transcriptional induction of SGK3 to enable AKT-independent mTORC1 activation and survival. Lentiviral barcoding experiments, combined with single cell RNA-sequencing, suggest that HER2+ cells stochastically cycle through a cell state (“pre-DTP”) capable of transition to DTPs. Collectively, our results provide insight into DTP ontogeny and therapeutic vulnerabilities.

Project description:Despite significant advances in HER2-targeted therapies, therapeutic resistance in HER2-positive (HER2+) breast cancer remains a significant clinical problem, especially in the metastatic setting. “Drug tolerant persisters” (DTPs), a sub-population of cancer cells that survive via reversible, non-genetic mechanisms, are implicated in resistance to tyrosine kinase inhibitors (TKIs) in several cancer models, but DTPs for HER2-targeted TKIs (e.g., lapatinib, neratinib, tucatinib) have not been characterized extensively. Here, we report that HER2+ER+ and HER2+ER- breast cancer lines give rise to distinct types of “lapatinib-DTPs,” characterized by different transcriptional programs and sensitivity to lapatinib/anti-estradiol combination. Lapatinib-DTPs from HER2+/ER+ cells rewire the PI3K/AKT/mTORC1 pathway via transcriptional induction of SGK3 to enable AKT-independent mTORC1 activation and survival. Lentiviral barcoding experiments, combined with single cell RNA-sequencing, suggest that HER2+ cells stochastically cycle through a cell state (“pre-DTP”) capable of transition to DTPs. Collectively, our results provide insight into DTP ontogeny and therapeutic vulnerabilities.

Project description:Although BRD8 has been considered to act as a coactivator of the NuA4/TIP60-histone acetyltransferase complex, the role of BRD8 in colorectal cancer cells remains to be elucidated. We explored genomic BRD8-binding sites in human colorectal cancer cells.

Project description:In a 3D coculture with stroma cells derived from breast cancer patients’ brain metastasis, HER2+ breast cancer cells were protected from HER2-targeted therapies, particularly the EGFR/HER2 small molecule inhibitor neratinib. To get insight into how this protection arises, a Synthetic Notch (SynNotch) reporter model allowed to study the effect of direct contact between stroma and cancer cells.

Project description:Mechanisms regulating gene expression in the airway epithelium underlie its response to the environment.  A network of transcription factors (TFs) and architectural proteins, modulate chromatin accessibility and recruit activating or repressive signals. Bromodomain-containing proteins function as TFs or by engaging methyltransferase or acetyltransferase activity to induce chromatin modifications.  Here we investigate the role of Bromodomain Containing 8 (BRD8) in coordinating lung epithelial function. Sites of BRD8 occupancy genome-wide were mapped in human lung epithelial cell lines (Calu-3 and 16HBE14o-). CCCTC-Binding Factor (CTCF) was identified as a predicted co-factor of BRD8, based upon motif over-representation under BRD8 ChIP-seq peaks. Following siRNA-mediated depletion of BRD8, differentially expressed genes with peaks of BRD8 occupancy within 20 kb were subject to gene ontology process enrichment analysis. BRD8 targets are enriched for genes involved in the innate immune response and depletion of BRD8 increased the secretion of the antimicrobial peptide beta-defensin 1 and multiple chemokines.