Project description:Bone is the primary site of breast cancer metastasis and complications associated with bone metastases can lead to a significantly decreased quality of life in these patients. Thus, it is essential to gain a better understanding of the molecular mechanisms that underlie the emergence and growth of breast cancer skeletal metastases. Methods: To search for novel molecular mediators that influence breast cancer bone metastasis, we generated gene expression profiles from laser capture micro-dissected trephine biopsies of both breast cancer bone metastases and primary breast tumors that metastasized to bone. Bioinformatics analysis identified genes that are differentially expressed in breast cancer bone metastases compared to primary mammary tumors. Results: ABCC5, an ATP-dependent transporter, was found to be overexpressed in breast cancer osseous metastases relative to primary mammary tumors. In addition, ABCC5 was significantly up-regulated in human and mouse breast cancer cell lines with high bone-metastatic potential. Stable knockdown of ABCC5 significant reduced bone metastatic burden and osteolytic bone destruction in mice. The decrease in osteolysis was further associated with diminished osteoclast numbers. Conclusions: Our data, for the first time, suggests that ABCC5 functions as a mediator of breast cancer skeletal metastasis. ABCC5 expression in breast cancer cells is important for the efficient bone resorption mediated by osteoclasts. Hence, ABCC5 may be a potential therapeutic target for breast cancer bone metastasis. primary breast tumors vs. bone trephine biopsies

Project description:Bone is the primary site of breast cancer metastasis and complications associated with bone metastases can lead to a significantly decreased quality of life in these patients. Thus, it is essential to gain a better understanding of the molecular mechanisms that underlie the emergence and growth of breast cancer skeletal metastases. Methods: To search for novel molecular mediators that influence breast cancer bone metastasis, we generated gene expression profiles from laser capture micro-dissected trephine biopsies of both breast cancer bone metastases and primary breast tumors that metastasized to bone. Bioinformatics analysis identified genes that are differentially expressed in breast cancer bone metastases compared to primary mammary tumors. Results: ABCC5, an ATP-dependent transporter, was found to be overexpressed in breast cancer osseous metastases relative to primary mammary tumors. In addition, ABCC5 was significantly up-regulated in human and mouse breast cancer cell lines with high bone-metastatic potential. Stable knockdown of ABCC5 significant reduced bone metastatic burden and osteolytic bone destruction in mice. The decrease in osteolysis was further associated with diminished osteoclast numbers. Conclusions: Our data, for the first time, suggests that ABCC5 functions as a mediator of breast cancer skeletal metastasis. ABCC5 expression in breast cancer cells is important for the efficient bone resorption mediated by osteoclasts. Hence, ABCC5 may be a potential therapeutic target for breast cancer bone metastasis.

Project description:Metastases of breast cancer is a prevalent problem with over 25% of patients suffering with metastatic disease. Of the patients that present with metastatic disease, the majority are estrogen receptor positive (ER+) and have skeletal metastases. These skeletal metastases can cause several issues including pathological fractures, chronic pain, and hypercalcemia. Currently, there are not any cures for metastatic breast cancer in bone and only therapies to mediate the osteolysis caused by breast cancer. The bone microenvironment presents various physical forces that can act on the tumor cell that has been studied in ER- cells, however, the physical forces on ER+ tumor cells have not been widely evaluated. In this study, we explored the transcriptional changes that occur at different matrix rigidities associated with the bone microenvironment (bone marrow: 0.5 kPa to 32 kPa; cortical and trabecular bone – 2 x 107 kPa). We observed that lower stiffnesses contributed to increased gene signatures associated with interleukin signaling. Additionally, we observed that downstream estrogen signaling outputs were modified. These interesting findings give us insights on what may be changing when ER+ tumor cells encounter rigidities associated with the bone microenvironment.

Project description:Neurofibromin/NF1-depletion (NF1low) is associated with endocrine therapy resistance in approximately 20% of ER+/HER2– early-stage breast cancer but specific treatments for NF1low tumors are not established. Proteogenomic analyses on ER+/HER2– breast cancer demonstrated that NF1low tumors exhibit elevated CDK4/6 activity. NF1-silencing in cell lines promoted ER recruitment to CCND1, thus increasing cyclin-D1 levels. Additionally, RAF is demonstrated to directly phosphorylate the CDK4 activation-loop (pT172) thus providing a direct connection between NF1 loss and an increase in CDK4 activity. Consequently, NF1low cancer cells are differentially sensitive to a fulvestrant plus CDK4/6 inhibitor (CDK4/6i) combination, with cell-death induction in vitro, and durable tumor regressions in ER+ NF1low PDX models in vivo. Furthermore, NF1low ER+/HER2– tumors treated neoadjuvantly with 4 weeks of anastrozole exhibited a minimal reduction of a multigene mRNA proliferation score vs NF1high tumors but exhibited marked sensitivity to the subsequent addition of palbociclib. In conclusion, dual ER and downstream RAF activation following NF1-loss drives endocrine therapy resistance and CDK4/6i sensitivity in NF1low ER+ breast cancer. NF1 status should therefore be prioritized for biomarker investigations in adjuvant CDK4/6i trials to determine whether the NF1low status

Project description:Neurofibromin/NF1-depletion (NF1low) is associated with endocrine therapy resistance in approximately 20% of ER+/HER2– early-stage breast cancer but specific treatments for NF1low tumors are not established. Proteogenomic analyses on ER+/HER2– breast cancer demonstrated that NF1low tumors exhibit elevated CDK4/6 activity. NF1-silencing in cell lines promoted ER recruitment to CCND1, thus increasing cyclin-D1 levels. Additionally, RAF is demonstrated to directly phosphorylate the CDK4 activation-loop (pT172) thus providing a direct connection between NF1 loss and an increase in CDK4 activity. Consequently, NF1low cancer cells are differentially sensitive to a fulvestrant plus CDK4/6 inhibitor (CDK4/6i) combination, with cell-death induction in vitro, and durable tumor regressions in ER+ NF1low PDX models in vivo. Furthermore, NF1low ER+/HER2– tumors treated neoadjuvantly with 4 weeks of anastrozole exhibited a minimal reduction of a multigene mRNA proliferation score vs NF1high tumors but exhibited marked sensitivity to the subsequent addition of palbociclib. In conclusion, dual ER and downstream RAF activation following NF1-loss drives endocrine therapy resistance and CDK4/6i sensitivity in NF1low ER+ breast cancer. NF1 status should therefore be prioritized for biomarker investigations in adjuvant CDK4/6i trials to determine whether the NF1low status identifies a particularly sensitive subset where CDK4/6i therapy is critical.

Project description:Lymph node involvement is a major prognostic variable in breast cancer. Whether the molecular mechanisms that drive breast cancer cells to colonize lymph nodes are shared with their capacity to form distant metastases is yet to be established. In a transcriptomic survey aimed at identifying molecular factors associated with lymph node involvement of ductal breast cancer, we found that luminal differentiation, assessed by the expression of estrogen receptor (ER) and/or progesterone receptor (PR) and GATA3, was only infrequently lost in node-positive primary tumors and in matched lymph node metastases. The transcription factor GATA3 critically determines luminal lineage specification of mammary epithelium and is widely considered a tumor and metastasis suppressor in breast cancer. Strong expression of GATA3 and ER in a majority of primary node-positive ductal breast cancer was corroborated by quantitative RT-PCR and immunohistochemistry in the initial sample set, and by immunohistochemistry in an additional set from 167 patients diagnosed of node-negative and positive primary infiltrating ductal breast cancer, including 102 samples from loco-regional lymph node metastases matched to their primary tumors, as well as 37 distant metastases. These observations suggest that loss of luminal differentiation is not a major factor driving the ability of breast cancer cells to colonize regional lymph nodes. The transcriptomic study comprises 16 samples from Lymph node metastasis from infiltrating ductal breast carcinoma, 18 samples from Primary node-positive infiltrating ductal,7 samples from Primary node-negative infiltrating ductal and 3 samples from Unaffected lymph node were included. Their RNA was isolated and prepared for hybridization to human Affymetrix GeneChip arrays.

Project description:  Lymph node involvement is a major prognostic variable in breast cancer. Whether the molecular mechanisms that drive breast cancer cells to colonize lymph nodes are shared with their capacity to form distant metastases is yet to be established. In a transcriptomic survey aimed at identifying molecular factors associated with lymph node involvement of ductal breast cancer, we found that luminal differentiation, assessed by the expression of estrogen receptor (ER) and/or progesterone receptor (PR) and GATA3, was only infrequently lost in node-positive primary tumors and in matched lymph node metastases. The transcription factor GATA3 critically determines luminal lineage specification of mammary epithelium and is widely considered a tumor and metastasis suppressor in breast cancer. Strong expression of GATA3 and ER in a majority of primary node-positive ductal breast cancer was corroborated by quantitative RT-PCR and immunohistochemistry in the initial sample set, and by immunohistochemistry in an additional set from 167 patients diagnosed of node-negative and –positive primary infiltrating ductal breast cancer, including 102 samples from loco-regional lymph node metastases matched to their primary tumors, as well as 37 distant metastases. These observations suggest that loss of luminal differentiation is not a major factor driving the ability of breast cancer cells to colonize regional lymph nodes.

Project description:We investigated the role of breast cancer stem-like cells (CSCs-like), isolated from primary tumor, in promoting bone metastases in a human-in-mice model. Luciferase-transduced CD44+CD24- breast CSCs-like were injected through subcutaneous (SC) and intracardiac (IC) route in nonobese/severe combined immunodeficient (NOD/SCID) mice carrying subcutaneous human bone implants. The implanted bone was viable, active and human neo-vascularization was present. By in vivo luciferase imaging, we monitored tumor growth and detected bone-localized breast CSCs-like, both after SC and IC injection. Bone metastatic lesions were histologically evident, and tumor cells expressed epithelial markers and vimentin. Bone metastatic cells isolated from bone implants showed a CD44-CD24+ phenotype and re-created tumors and bone metastases after injection in secondary mice. A “bone tropism” expression signature was found to distinguish bone-colonizing cells from parental CSCs-like and to persist at subsequent passages also in the absence of surrounding bone tissue. The bone tropism signature displayed significant enrichment in genes discriminating bone metastases of breast cancer from metastases at other organs. Our results demonstrate the ability of breast CSCs-like to promote bone metastasis and provide a CSCs-like bone tropism signature, with potential prognostic value. C10 breast cancer stem-like cells (CSCs-like) were derived as mammospheres from a lobular-infiltrating breast carcinoma (ER+, HER2-). Samples are organized in the following groups: (i) Breast CSCs-like (C10, duplicate); (ii) Luciferase-transduced CSCs-like (C10L, simplicate); (iii) Bone-isolated C10L metastatic cells (C10-bone, duplicate) and subsequently (iv) grown in vitro as spheroids (C10-CSC, simplicate) or (v) re-grown in subcutaneous implants (C10-SC, duplicate).

Project description:The lymphatic system is a common avenue for the spread of breast cancer cells and dissemination through it occurs at least as frequently as hematogenous metastasis. Approximately 75% of primary breast cancers are estrogen receptor (ER) positive and the majority of these maintain receptor expression as lymph node (LN) metastases. However, it is unknown if ER function is equivalent in cancer cells growing in the breast and in the LNs. We have developed a model to assess estrogen responsiveness in ER(+) breast tumors and LN metastases. Fluorescent ER(+) MCF-7 tumors were grown in ovariectomized nude mice supplemented with estradiol. Once axillary LN metastasis arose, estradiol was withdrawn (EWD), for 1 or 4 weeks, or continued, to assess estradiol responsiveness. On EWD, proliferation rates fell similarly in tumors and LN metastases. However, estradiol-dependent ER down-regulation and progesterone receptor induction were deficient in LN metastases, indicating that ER-dependent transcriptional function was altered in the LN. Cancer cells from estradiol-treated and EWD primary tumors and matched LN metastases were isolated by laser capture microdissection. Global gene expression profiling identified transcripts that were regulated by the tissue microenvironment, by hormones, or by both. Interestingly, numerous genes that were estradiol regulated in tumors lost estradiol sensitivity or were regulated in the opposite direction by estradiol in LN metastases. We propose that the LN microenvironment alters estradiol signaling and may contribute to local antiestrogen resistance. Experiment Overall Design: 10 samples, including 3 each of estrogen and estrogen withdrawn axillary lymph nodes and 2 each of estrogen and estrogen withdrawn primary mammary gland tumors.

Project description:Molecular drivers underlying bone metastases in human cancer are not well understood, in part due to constraints in bone tissue sampling. Here, we undertook RNA sequencing of circulating tumor cells (CTCs) obtained from blood samples of women with metastatic estrogen receptor (ER)+ breast cancer, comparing cases with progression in bone versus visceral organs. Among the activated cellular pathways in CTCs from bone-predominant breast cancer is Androgen Receptor (AR) signaling. AR gene expression is evident, as is its constitutively active splicing variant AR-v7. AR expression within CTCs is correlated with the duration of treatment with aromatase inhibitors, suggesting that it may contribute to acquired resistance to anti-estrogen therapy. In an established breast cancer xenograft model, a bone-tropic derivative displays increased AR expression, whose genetic or pharmacologic suppression reduces metastases to bone but not to lungs. Together, these observations identify AR signaling in CTCs from women with bone-predominant ER+ breast cancer, and provide a rationale for testing androgen inhibitors in this subset of patients.