Helen L. Neville-Webbe

Sequence‐ and schedule‐dependent enhancement of zoledronic acid induced apoptosis by doxorubicin in breast and prostate cancer cells

We investigated whether the combination of zoledronic acid and doxorubicin induced apoptosis of breast and prostate cancer cell lines, and if synergistic interaction was present. We investigated whether the levels of cell death altered depending on the sequence in which the drugs were administered and the possible mechanism of action responsible for the increased cell death following combined treatments. Breast and prostate cancer cells were treated with zoledronic acid alone, doxorubicin alone, or drugs in sequence (doxorubicin before, after, or with zoledronic acid), and the levels of apoptotic death were determined by evaluation of nuclear morphology. We found that clinically relevant concentrations of doxorubicin and zoledronic acid induced sequence‐ and schedule‐dependent apoptosis of breast and prostate cancer cells. For maximal apoptosis, cells had to be pretreated for 24 hr with doxorubicin before immediate treatment with zoledronic acid for 1 hr. This observation is a characteristic feature of cell cycle phase‐specific synergistic effect. Replacing zoledronic acid with the nonnitrogen‐containing bisphosphonate clodronate did not induce increased apoptosis. Induction of apoptosis was mainly via inhibition of the mevalonate (MVA) pathway, as addition of the MVA pathway intermediary geranylgeraniol inhibited the induction of apoptosis by doxorubicin followed by zoledronic acid. In conclusion, combined treatment of breast and prostate cancer cell lines with clinically relevant doses of doxorubicin and zoledronic acid induces apoptosis in a synergistic fashion. These findings may have relevance for the clinical setting, particularly breast cancer patients receiving these drugs in the adjuvant setting.

Osteoprotegerin (OPG) produced by bone marrow stromal cells protects breast cancer cells from TRAIL-induced apoptosis

Advanced breast cancer is often associated with metastatic bone disease, causing a number of serious complications for the patients such as hypercalceamia, pain, nerve compression and fractures. The formation of bone metastases depends on complex interactions between tumour cells and the cells of the bone microenvironment, but the precise molecular mechanisms involved in the development of tumour-induced bone disease have not been identified. We have investigated the ability of bone marrow stromal cells (BMSC) isolated from breast cancer patients to generate osteoprotegerin (OPG), a molecule involved both in bone turnover and cell survival. The potential survival effects of OPG are mediated through binding to a member of the TNF super family, TNF-related Apoptosis Inducing Ligand (TRAIL), preventing association between TRAIL and its death-inducing receptors present on a number of tumour cell types. In the present report we show that bone marrow stromal cells isolated from breast cancer patients produce OPG when grown in culture. The levels of OPG present in BMSC conditioned medium is sufficient to protect breast cancer cells from undergoing TRAIL induced apoptosis. Our data suggest that bone-derived OPG may increase survival of breast cancer cells that reach the bone microenvironment as part of the metastatic process.

The anti-tumour activity of bisphosphonates

Bisphosphonates are stable analogues of pyrophosphate (PPi), an endogenous regulator of bone mineralisation. A number of placebo-controlled trials have demonstrated their positive impact on skeletal-related events (SRE) that occur as a consequence of metastatic or myelomatous bone disease. Based upon their chemical structure bisphosphonates can be classified into nitrogen-containing bisphosphonates, (N-bisphosphonates) (for example zoledronate and pamidronate) and non-nitrogen containing (for example, clodronate and etidronate), which more closely resemble PPi. Clinical trials investigating bisphosphonates in the preventative setting have shown bisphosphonates to not only delay occurrence of bone metastases in certain cancers, but in one trial, occurrence of non-osseous lesions was delayed, and survival was prolonged. Other trials however have shown the opposite. Likewise, in animal models of cancer and metastases, conflicting results have been obtained. In vitro work has concentrated on bisphosphonates direct action upon tumour cells and has found a variety of anti-tumour effects such as apoptosis induction, inhibition of cell growth, inhibition of invasive behaviour and inhibition of angiogenic factors. Furthermore it would appear that bisphosphonates have the potential to enhance anti-tumour activity of known cytotoxic drugs. Ongoing research aims to assess this further, in addition to determining more precisely the role of adjuvant bisphosphonates in cancers such as breast and prostate cancer.

Osteoprotegerin (OPG) Expression by Breast Cancer Cells in vitro and Breast Tumours in vivo – A Role in Tumour Cell Survival?

SummaryIn addition to its role in bone turnover, osteoprotegerin (OPG) has been reported to bind to and inhibit Tumour necrosis factor-related apoptosis inducing ligand (TRAIL). TRAIL is produced in tumours by invading monocytes, inducing apoptosis in neoplastic cells sensitive to this cytokine. OPG production by tumour cells would therefore be a novel mechanism whereby cancer cells evade host defences and gain a growth advantage. In this study we show that OPG produced by breast cancer cells enhances tumour cell survival by inhibiting TRAIL-induced apoptosis. OPG expression by breast cancer cells (MDA-MB 436/231) grown in vitro was examined using PCR and ELISA, and the sensitivity of these cells to TRAIL was determined. The effects of OPG on TRAIL induced apoptosis was investigated by exposing MDA-MB 436 cells to TRAIL, in the presence or absence of OPG, followed by assessment of nuclear morphology. We found that the levels of OPG produced were sufficient to inhibit TRAIL-induced apoptosis, suggesting that OPG may play a role in tumour cell survival. We also examined the expression pattern of OPG in a selection of breast tumours (n=400) by immunohistochemistry, and related OPG expression to the clinico-pathological data for each tumour. OPG expression was found to be negatively correlated with increasing tumour grade. To our knowledge these results are the first to demonstrate that OPG can act as an endocrine survival factor for breast cancer cells, as well as reporting the expression patterns of OPG in a large cohort of human breast tumours.

Osteoprotegerin (OPG)--a potential new role in the regulation of endothelial cell phenotype and tumour angiogenesis?

The progression of cancer depends on the establishment of a tumour blood supply, and therefore tumour angiogenesis has been identified as a major target for new anticancer agents. Recent reports have suggested that osteoprotegerin (OPG) is involved in the control of endothelial cell survival through the inhibition of the activity of tumour necrosis factor‐ (TNF) related apoptosis‐inducing ligand (TRAIL). The role of OPG in human tumour development and angiogenesis is currently unknown. In the present study we demonstrate the ability of OPG to support endothelial cell survival, as well as the formation of cord‐like structures in vitro using a matrigel tubule formation assay. Investigation of various human cancers demonstrated endothelial OPG expression in 59% of malignant tumours (n = 512), but in contrast, OPG was absent in endothelial cells associated with benign tumours and normal tissues (n = 178). In a series of 400 breast tumours, endothelial OPG expression was associated with high tumour grade and certain histological types. Our data show a clear separation in endothelial OPG expression between malignant tumours and nonmalignant tissues, supporting a potential biological role for this molecule in the development and/or maintenance of the tumour vasculature. This is the first study to report the proangiogenic effects of OPG in vitro, as well as correlating expression of OPG by tumour endothelial cells with clinicopathological data in human tumours.

Mechanisms of the Synergistic Interaction between the Bisphosphonate Zoledronic Acid and the Chemotherapy Agent Paclitaxel in Breast Cancer Cells in vitro

Breast cancer patients often receive both paclitaxel and zoledronic acid as part of their treatment, and these drugs are reported to have synergistic effects on the induction of apoptosis of breast cancer cells in vitro. We have found that the synergistic interaction is drug sequence dependent, with maximal levels of apoptosis achieved when cells are treated with paclitaxel followed by zoledronic acid, as opposed to the reverse sequence or simultaneous treatment. The synergistic interaction persists at clinically relevant concentrations and incubation periods. We report that the sequential treatment is associated with cell cycle changes and depends on breast cancer cell characteristics, with hormone independence, mutated p53 status and presence of BRCA1 gene being associated with higher levels of apoptosis. Finally, we have found that the synergistic induction of apoptosis is via zoledronic acid-mediated inhibition of the mevalonate pathway.

Potential Anticancer Properties of Bisphosphonates

Bisphosphonates inhibit osteoclast-mediated bone resorption, which is increased when cancer cells invade bone, and are used in the treatment of metastatic bone disease to reduce the risk of skeletal-related events. In addition, preclinical studies have shown that bisphosphonates, especially potent nitrogen-containing bisphosphonates, have direct anticancer actions. Anticancer activity includes induction of apoptosis, and inhibition of invasion, in addition to synergistic activity with chemotherapy agents, antiangiogenic properties, and modulating effects on the immune system. In terms of potential clinical anticancer activity, early data suggest that zoledronic acid may have a role to play in preventing metastatic disease. The definitive answer is not known as yet; however, with more than 20,000 patients with breast, prostate, or lung cancer currently participating in adjuvant bisphosphonate randomized trials, results should be available in the next few years. This will establish whether bisphosphonates given early in the course of cancer will be able to prevent formation of metastases, in or out of the bone environment. This review will focus on emerging evidence of the anticancer activities of bisphosphonates and possible underlying mechanisms of action.

Combined effects of the bisphosphonate, zoledronic acid and the aromatase inhibitor letrozole on breast cancer cells in vitro: evidence of synergistic interaction

Background:Aromatase inhibitors are widely used in the treatment of oestrogen receptor-positive post-menopausal breast cancer. These patients may also be receiving the bisphosphonate, zoledronic acid (ZA) to prevent bone loss or reduce skeletal morbidity in the setting of advanced disease. The potential biological interaction of these two drugs in breast cancer has not been assessed.Methods:Aromatase-expressing breast cancer cells were treated with letrozole and ZA either simultaneously or in sequence, and the resulting apoptosis was assessed by staining with Hoechst 33342 and propidium iodide and examined using a fluorescent inverted Leica DMIRB microscope and a UV filter.Results:We found that letrozole and ZA induce levels of apoptosis in breast cancer cells in vitro that are significantly greater compared with treatment with each drug alone. However, this potentially, synergistic relationship is drug-sequence dependent, occurring only when cells are treated with letrozole, followed by ZA. The converse sequence, or administering drugs simultaneously, induces levels of apoptosis no greater than each drug alone.Conclusion:Owing to the enhanced anti-tumour efficacy of sequential drug administration, our findings may indicate that, for post-menopausal women who require treatment with letrozole, ZA should also be considered.

Targeting RANK/RANKL in the Treatment of Solid Tumours and Myeloma

Cancers which damage the human skeleton include multiple myeloma, where the primary tumour colonises bone directly, or breast and prostate cancer, where malignant cells travel from the primary tumour to form clonal outgrowths within the bone. Owing to the interaction of tumour cells with those normally found in the bone microenvironment, such as osteoclasts and osteoblasts, these cancers affect the closely linked processes of bone formation and resorption. As a result, these twin processes contribute to the clinical manifestations of cancer metastasis, including bone pain and pathological fractures. A critical component of physiologically normal bone remodelling, the RANK/RANKL/OPG pathway, has been implicated in the formation of osteolytic, and possibly osteoblastic, lesions, which characterise the bone disease associated with these malignancies. In these cancers that affect the skeleton in this way the abnormally regulated RANK/RANKL system appears to be the final effector pathway. As a result, there has been much research focused upon targeting these molecules using OPG constructs, peptidomimetics, soluble receptor constructs and antibodies to RANKL, in pre-clinical studies. The success of these studies has paved the way for a clinical programme, the success of which is likely to lead to a new therapeutic approach to treating cancers that develop in the skeleton.

Prevention and Treatment of Skeletal Complications

Management of early breast cancer has become increasingly successful, leading to current 10-year survival rates of around 80-85%. Approximately 75% of breast cancers are hormone-receptor-positive, and these patients are usually managed in the adjuvant setting with targeted hormonal agents, and if indicated, cytotoxic chemotherapy. These treatments are not without side effects, and of particular relevance to the older woman is their impact on skeletal health.