Project description:The vast majority of all breast cancers are driven by oestrogen receptor alpha (ERα) activation, and endocrine therapy represents the mainstay treatment for these patients. However, resistance is common and tumours progress despite years of systemic endocrine suppression. Periodic fasting enhances the efficacy of standard endocrine drugs and delay acquired resistance to them, although the underlying mechanisms remain unclear. Here, we show that fasting, in combination with endocrine therapy, induces extensive epigenetic reprogramming in hormone receptor-positive (HR+) breast cancer xenografts, with large-scale activation of glucocorticoid receptor (GR) and progesterone receptor (PR) signalling, and impairment of activator protein-1 (AP-1) family activity. GR-driven gene programs were selectively activated after fasting, and GR knockout perturbed the beneficial effects of fasting in combination with tamoxifen, in vivo. Exogenous administration of GR-ligands fully recapitulated the observed fasting-enhanced anti-oestrogen action, resulting in tumour regression. Finally, elevated progesterone and cortisol levels were detected in the blood of breast cancer patients after fasting, thus providing clinical validation of our animal findings. Our results indicate GR activation to play a pivotal role in fasting’s ability to enhance endocrine drug activity against hormone-receptor positive breast cancer and suggest that corticosteroid administration should be evaluated as an adjuvant to endocrine therapy in this condition.

Project description:Oestrogen receptor alpha (ER, gene symbol ESR1) is the most important prognostic and treatment-predictive biomarker in breast cancer. Drugs targeting oestrogen and the ER for endocrine therapy of breast cancer include aromatase inhibitors, the selective ER modulator tamoxifen and the selective ER degrader fulvestrant. Tumours can develop resistance to endocrine therapy through several mechanisms, which is often linked to altered expression of the ER. To investigate the role of promoter methylation in regulation of ER expression, we used bisulfite sequencing to measure methylation at CpG sites in alternative ER promoter regions for six cell line models of fulvestrant resistance. Both CpG methylation and expression of alternative first exons changed dynamically with striking differences between cell lines that had stable or unstable resistance upon fulvestrant withdrawal. Methylation at some CpG sites was strongly negatively correlated with expression of specific first exons. In a breast tumour cohort, higher relative expression of upstream alternative first exons was associated with worse prognosis in post-menopausal women with ER-positive tumours who received endocrine therapy.

Project description:Around two thirds of breast tumors are characterized by the expression of estrogen receptor α and are therapeutically treated by blocking estrogen signaling. First line endocrine therapeutics are Tamoxifen which displaces estrogen form its receptor preventing receptor activation and aromatase inhibitors which prevent the formation of estrogen and thereby hormone-deprive the tumors. Therapy resistance remains a major clinical problem, especially for patients with late-stage diagnoses. Tumor heterogeneity may promote therapy resistance either through the selection of pre-existing rare clones or by providing a repertoire of cells that may develop resistance over time. In order to study endocrine therapy resistance on a clonal level, we have developed barcoded (allowing the tracking of single cells) endocrine therapy sensitive and resistant breast cancer cell lines. From these complex cell pools, multiple single cells characterized by a specific barcode were isolated and grown out. We then subjected the clones to phosphoproteomics measurement by Mass spectrometry. Based on their phosphorylation pattern, the kinase activity profiles of endocrine therapy resistant clones were determined to identify differentially activated kinases with implications in therapy resistance.

Project description:Up to 80% of endometrial and breast cancers express the oestrogen receptor ERa. Unlike breast cancer, anti-oestrogen therapy has had limited success in endometrial cancer, raising the possibility that oestrogen has different effects in the two cancer types. We investigated the role of oestrogen in endometrial and breast cancers using cell lines and found that oestrogen-responsive genes were predominantly unique between the two cancer types.

Project description:<p>The genomic evolution of breast cancers exposed to systemic therapy and its effects on clinical outcome have not been broadly characterized. We integrated the genomic sequencing of 1918 breast cancers, including 1501 hormone receptor-positive tumors, with detailed clinical information and treatment outcomes. Functional mutations in ERBB2 and loss-of-function mutations in NF1 were more than twice as common in post-endocrine therapy tumors compared to treatment-naive tumors. Additional alterations in the MAPK pathway (EGFR, KRAS among others) and in estrogen receptor transcriptional regulators (MYC, CTCF, FOXA1 and TBX3) were also more common compared to hormonal therapy-naive tumors.</p> <p>To determine whether candidate genomic lesions in the MAPK pathway and estrogen receptor transcriptional regulators were present prior to therapy or whether such lesions arose under the selective pressure of therapy, we performed whole-exome sequencing in select patients who had adequate samples acquired prior to and after progression on endocrine therapy. In total, 95 specimens corresponding to 30 treatment-naive primary tumors, 35 post-treatment tumors, and 30 normal samples were sequenced from 30 patients with endocrine-resistant metastatic breast cancer.</p>

Project description:Combined menopausal hormone therapy is associated with increased breast cancer risk in postmenopausal women. In our previous studies, progesterone receptor membrane component 1 (PGRMC1) was shown to play a role in progestins’ mode of action, resulting in enhanced proliferation of breast cancer cells. Here we describe a potential mechanism by which PGRMC1 contributes to breast cancer progression via interaction with prohibitins, inhibiting their function as transcription factor repressors, thereby facilitating estrogen receptor alpha (ERα) transcriptional activity and enhancing oncogenic signaling upon treatment with certain progestins, such as norethisterone and dydrogesterone.

Project description:*** This submission includes RNA data, with DNA files available under a different accession number*** Purpose: Endocrine therapy resistance remains the greatest challenge for treating hormone receptor positive breast cancer patients. We aim to identify molecular mechanisms underlying endocrine therapy resistance through in-depth genomic analysis of patient samples. Experimental Design: We collected tumors from 35 estrogen receptor positive breast cancer patients receiving endocrine therapy, of which 3 patients had intrinsic resistance and 19 patients developed acquired resistance. For each patient, multiple tumor specimens were collected during the course of treatment. We performed DNA whole exome sequencing and RNA sequencing on all tumor samples. DNA mutations, copy number alterations and RNA gene expression data were analyzed through supervised analyses comparing paired sensitive and resistant tumor samples to identify molecular features related to endocrine therapy resistance. Results: We identified mutations enriched in resistant tumors including ESR1 and GATA3. ESR1 D538G variant confers endocrine therapy resistance while E380Q variant confers hypersensitivity. We demonstrate that resistant tumors had distinct gene expression profiles and elevated signaling pathways including ER, HER2, GATA3, AKT, RAS and p63 signaling. Integrated analysis for individual patient highlighted the heterogeneity of endocrine therapy resistance mechanisms. Conclusions: Our results suggest that mechanisms underlying endocrine therapy resistance are highly heterogeneous with diverse changes in genomic and transcriptomic levels.

Project description:Breast cancer is a heterogeneous disease encompassing a number of phenotypically diverse tumours. Expression levels of the estrogen, progesterone and HER2/neu receptors which characterise clinically distinct breast tumors have been shown to change during disease progression and in response to systemic therapies. Mi(cro)RNAs play critical roles in diverse biological processes and are aberrantly expressed in several human neoplasms including breast cancer, where they function as regulators of tumour behaviour and progression. The aims of this study were to identify miRNA signatures that accurately predict the oestrogen receptor (ER), progesterone receptor (PR) and HER2/neu receptor status of breast cancer patients to provide insight into the regulation of breast cancer phenotypes and progression.

Project description:Oestrogen receptor-α (ER) is the principal transcription factor in the majority of breast cancers, driving expression of genes that control cell growth and endocrine response. Understanding the mechanisms of ER action is crucial for improving response to endocrine treatments. Recent studies show that cytosine deaminase (CD) activity is an important source of cancer mutations. In particular, APOBEC3B (A3B) promotes mutagenesis in breast cancer cells1. Our analysis of breast cancer expression datasets showed that A3B expression predicts for poor survival in ER-positive, but not in ER-negative patients, indicative of a link with ER activity. Chromatin immunoprecipitation coupled to deep sequencing (ChIP-seq) used to map global A3B binding sites showed a remarkable oestrogen-stimulated recruitment of A3B to ER binding sites. Functionally, A3B was critical for ER transcriptional activity and regulated breast cancer cell proliferation. We show that A3B regulates ER transcription by promoting cytosine deamination and activation of DNA strand break repair at ER binding regions. We propose that cytosine deamination and DNA strand break generation by A3B facilitates gene expression by aiding chromatin remodeling at ER target genes. Our findings also suggest a mechanism by which subversion of transcription factor mediated recruitment of cytosine deaminases promotes cancer mutations. Hormone-depleted MCF-7 breast cancer cell line was treated with estrogen (100 nM), H2O2 (10 mM) or vehicle for 45 minutes. H2AX ChIP-seq was performed using Illumina methodology.

Project description:Male breast cancer (MBC) is rare and poorly characterized. Like the female counterpart, most MBCs are hormonally driven, but resistance to hormonal treatment is common. The pan-hormonal action of steroid hormonal receptors including Estrogen Receptor alpha (ERα), Androgen Receptor (AR), Progesterone Receptor (PR) and Glucocorticoid Receptor (GR) in this understudied tumor type remains wholly unexamined. This pioneering study reveals genomic cross-talk of steroid hormone receptor action and interplay in human tumors, here in the context of MBC, in relation to patient outcome. Using chromatin immunoprecipitation coupled with massively-parallel sequencing (ChIP-seq), we characterized human MBCs for epigenetic make-up of hormonal regulation in human tumors, revealing genome-wide chromatin binding landscapes of ERα, AR, PR and GR, along with pioneer factor FOXA1 and enhancer-enriched histone mark H3K4me1. These data were integrated with transcriptomics analyses to reveal gender-selective and genomic location-specific hormone receptor action, that are associated with survival in MBC patients.