Targeting the microtubules in breast cancer beyond taxanes: the epothilones

Microtubule-targeting agents such as the taxanes are highly active against breast cancer and have become a cornerstone in the treatment of patients with early and advanced breast cancer. The natural epothilones and their analogs are a novel class of microtubule-stabilizing agents that bind tubulin and result in apoptotic cell death. Among this family of compounds, patupilone, ixabepilone, BMS-310705, ZK-EPO, and KOS-862 are in clinical development. Extensive preclinical studies have shown that epothilones are working through partially nonoverlapping mechanisms of action with taxanes. In the clinic, epothilones have been found in a series of phase I and phase II studies to be active even in patients who had recently progressed to taxanes. The toxicity profile of these agents consists mostly of sensory neuropathy, sometimes reversible. Neoadjuvant studies with epothilones have been conducted and a number of phase III studies in advanced breast cancer are either under way or have been recently completed. The results of these studies are eagerly awaited and it is anticipated that epothilones may become an important treatment option in patients with breast cancer.     

Epothilones: a novel class of microtubule-stabilizing drugs for the treatment of cancer

Microtubule-targeted anticancer drugs are effective in treating various cancers but are limited in use due to development of resistance and unacceptable toxicities. The epothilones are a novel class of microtubule-stabilizing anticancer drugs and may have a role in treating taxane-resistant cancers. Revised and updated data from several clinical studies for ixabepilone were recently published and subsequently resulted in ixabepilone becoming the first epothilone approved as monotherapy or in combination for treatment of locally advanced or metastatic breast cancer. BMS-310705, patupilone, KOS-862, KOS-1584 and ZK-EPO are epothilones that have been developed. Although peripheral sensory neuropathy and neutropenia are the dose-limiting toxicities for ixabepilone, these dose-limiting toxicities are ixabepilone specific. This review will discuss the current preclinical, clinical pharmacokinetic and pharmacodynamic, efficacy and toxicity data of the epothilones.     

Pharmacodynamics of tubulin and tubulin-binding agents: extending their potential beyond taxanes

Chemotherapeutic agents that disrupt the assembly or disassembly of microtubules, including paclitaxel and docetaxel, are among the most commonly prescribed anticancer therapies. However, the utility of taxane-based therapy is limited principally by problems with formulation, slow administration, cumulative neurotoxicity, and resistance in part through induction of P-glycoprotein. The broad-spectrum anticancer activity of taxane therapy has encouraged investigators to identify a class of structurally novel microtubulin-stabilizing agents that could produce comparable outcomes with fewer problems. Preclinical studies indicate that epothilones have a broad spectrum activity in paclitaxel-resistant breast cancer models. Several epothilone analogues have displayed promising antitumor activity in initial clinical trials. Ixabepilone, an epothilone derivative in the later stages of clinical development, has exhibited antitumor activity in breast cancers, with or without previous taxane therapy. The most common adverse events associated with ixabepilone are reversible sensory neuropathy and neutropenia. This review briefly outlines the basic science behind microtubule-targeting agents and examines the preclinical studies of several of these agents in breast cancer models. Also discussed are results from clinical trials of epothilones alone and in combination in patients with breast cancer.     

The epothilones: translating from the laboratory to the clinic.

The epothilones are macrolide compounds that have been shown to stabilize microtubules. The epothilones are strong promoters of tubulin polymerization in vitro and have significant antitumor activity against human cancer cells that are taxane resistant, express the multidrug resistance gene MDR-1 (ABCB1), and have acquired tubulin mutations. Several epothilones have been evaluated in clinical trials in a variety of tumor types. Ixabepilone (aza-epothilone B) has significant antitumor activity in breast cancer resistant to an anthracycline and a taxane, and has been approved by the U.S. Food and Drug Administration for the treatment of patients with metastatic or locally advanced breast cancer. There have been sustained efforts to develop pharmacodynamic markers to monitor the pharmacologic effect of the epothilones on tumors and normal tissues. The development of predictive markers for epothilone chemotherapy is highly desired to provide more tailored therapy for patients with cancer.     

Therapeutic efficacy of prenylation inhibitors in the treatment of myeloid leukemia.

Farnesyltransferase inhibitors (FTIs) represent a new class of anticancer agents that specifically target post-translational farnesylation of various proteins that mediate several cellular processes such as signal transduction, growth, differentiation, angiogenesis and apoptosis. These compounds were originally designed to block oncogenic RAS-induced tumor growth by impeding RAS localization to the membrane, but it is now evident that FTIs also affect processing of several other proteins. The need for novel therapies in myeloid leukemia is underscored by the high rate of treatment failure due to high incidences of relapse- and treatment-related toxicities. As RAS deregulation is important in the pathogenesis of myeloid leukemias, targeting of RAS signaling may provide a new therapeutic strategy. Several FTIs (eg BMS-214662, L-778,123, R-115777 and SCH66336) have entered phase I and phase II clinical trials in myeloid leukemias. This review discusses recent clinical results, potential combination therapies, mechanisms of resistance and the clinical challenges of toxicities associated with prenylation inhibitors.     

Epothilones: clinical update and future directions

Epothilones are cytotoxic compounds that function in a similar fashion to paclitaxel and show promise for the treatment of a variety of cancers by inducing microtubule bundling and apoptotic cell death. However, their mechanism of microtubule binding is different from that of paclitaxel, which makes epothilones an attractive drug class for patients with taxane-resistant malignancies. As taxane resistance remains a significant barrier in the treatment of a variety of cancers, it is important to understand epothilones and their indications. Several epothilone compounds, including ixabepilone (BMS-247550, aza-epothilone B, Ixempra), patupilone (EPO906, epothilone B), KOS-862 (desoxyepothilone B, epothilone D), BMS-310705, ZK-EPO (ZK-219477), nd KOS-1584, have been testedf or the treatment of a variety of solid tumor types. Recently, ixabepilone became the first epothilone to be approved by the US Food and Drug Administration, for the treatment of metastatic or locally advanced breast cancer as monotherapy or in combination with capecitabine (Xeloda) after other treatments have failed. This article reviews recent findings from clinical trials of epothilones and discusses future directions for the use of these agents in cancer therapy, with a focus on the two most-studied epothilones to date: ixabepilone and patupilone.     

The epothilones: new therapeutic agents for castration-resistant prostate cancer

The management of castration-resistant prostate cancer (CRPC) presents a clinical challenge because of limitations in efficacy and durability with currently available therapeutics. The epothilones represent a novel class of anticancer therapy that stabilizes microtubules, causing cell death and tumor regression in preclinical models. The structure of the tubulin-binding site for epothilones is distinct from that of the taxanes. Moreover, preclinical studies suggest nonoverlapping mechanisms of resistance between epothilones and taxanes. In early-phase studies in patients with CRPC, treatment with ixabepilone, a semisynthetic analog of epothilone B, induced objective responses and prostate-specific antigen declines in men previously progressing on docetaxel-based regimens. Clinical activity has been observed in nonrandomized trials for patients with CRPC using ixabepilone in the first- and second-line settings as a single agent and in combination with estramustine. Patupilone and sagopilone were also shown to have promising efficacy in phase II clinical trials of patients with CRPC. All three epothilones appear to be well tolerated, with modest rates of neutropenia and peripheral neuropathy. The lack of crossresistance between epothilones and taxanes may allow sequencing of these agents. Evaluating epothilones in phase III comparative trials would provide much-needed insight into their potential place in the management of patients with CRPC.     

新型抗肿瘤药埃坡霉素的临床研究进展

埃坡霉素（epothilones）是一类非紫杉烷类促微管蛋白聚合剂,其作用机制与紫杉醇相似,但结构完全不同,临床前研究结果显示其细胞毒活性较紫杉醇强,对紫杉类耐药的细胞株和小鼠肿瘤移植模型显示出较强的抗肿瘤活性。近来合成或半合成了很多埃坡霉素类似物,目前已进入临床抗肿瘤治疗研究的埃坡霉素类似物主要有ixabepilone、patupilone、BMS-310705、ZK—EPO、KOS-862及KOS-1584。现有的临床研究结果提示部分接受过紫杉类药物治疗的晚期乳腺癌、卵巢癌、膀胱癌或非小细胞肺癌患者埃坡霉素治疗有效。本文就埃坡霉素的化学结构,作用机制、药理活性及毒副作用等临床研究的进展进行了回顾和综述。     

Efficacy and safety of ixabepilone, a novel epothilone analogue

The epothilones and their analogues are a new class of anticancer agents derived from the fermentation of myxobacterium Sorangium cellulosum. These compounds have some similarities to taxanes in targeting and stabilizing microtubules, but they also have important differences. Among the epothilone family, ixabepilone has emerged to be a semisynthetic epothilone analogue of interest. Ixabepilone has demonstrated consistent preclinical activity and seems active against various taxane-sensible and taxane-resistant cell lines, including those with overexpression of multidrug resistance and with mutations in the beta-tubulin gene. The interest of this ixabepilone has been confirmed clinically. Phase II clinical studies have demonstrated high activity in patients with taxane-resistant metastatic breast cancer and in patients with other chemotherapy-resistant tumor types.     

Epothilones in development for non--small-cell lung cancer: novel anti-tubulin agents with the potential to overcome taxane resistance

Progress in the treatment of non-small-cell lung cancer (NSCLC) will require the introduction of new agents as well as better use of existing therapies. Targeted therapies are likely to have a profound effect on the treatment of NSCLC after identification of patients who are most likely to benefit. The epothilones are novel anti-tubulin agents derived from Sorangium cellulosum. β III tubulin overexpression has been implicated as a mechanism of anti-tubulin resistance that can be overcome by epothilones. Several epothilones have advanced to clinical trials; ixabepilone (BMS247550, aza-epothilone B, Bristol-Myers Squibb, New York, NY), patupilone (EPO906, Novartis, Basel, Switzerland) and sagopilone (ZK-EPO, ZK-219477, Schering AG, Berlin-Wedding, Germany) are currently in active development. Several of the epothilones, most notably ixabepilone, have demonstrated activity in lung cancer in phase I and II trials, including taxane-resistant patients. Although a phase II study failed to show superior outcome in patients with β III tubulin overexpression, other aspects of the epothilones argue for their continued development.     

Ixabepilone, first in a new class of antineoplastic agents: the natural epothilones and their analogues

Although targeted therapies are becoming increasingly important in oncology, cytotoxic agents are likely to remain a valuable element in the treatment paradigm of cancer. However, resistance to chemotherapy is a major obstacle to the successful treatment of cancer. Therefore, there is a need for novel antineoplastic agents that are able to overcome mechanisms of tumor resistance. Drugs that target microtubules, including paclitaxel and docetaxel, are among the most commonly prescribed anticancer therapies. However, the utility of taxane-based therapies is limited by difficulties with formulation, administration, and resistance induced by P-glycoprotein. The epothilones and their analogues are a novel class of antimicrotubule agents that has demonstrated antitumor activity in the setting of resistance. These antimicrotubule agents are structurally unrelated to the taxanes, with a distinct beta-tubulin-binding mode. Ixabepilone is a rationally designed, semisynthetic analogue of natural epothilone B, which displays reduced susceptibility to a range of common tumor resistance mechanisms. Promising phase II activity and a manageable safety profile with ixabepilone have been seen in a wide range of tumor types, including heavily pretreated/resistant and early-stage breast cancer. Moreover, encouraging phase III results with ixabepilone and capecitabine for patients with breast cancer have recently been presented. Clinical trials are also planned for ixabepilone in combination with targeted agents, such as trastuzumab and bevacizumab. Ixabepilone is likely to be the first available drug in its class, with the potential to bring clinical benefit to patients with a wide range of malignancies.     

Nail disorders in a woman treated with ixabepilone for metastatic breast cancer

Ixabepilone (Ix) (BMS-247550) is a potent member of a new class of microtubule-stabilizing cytotoxic agents known as epothilones. In pre-clinical studies, Ix has shown anticancer activity against several cancer types, including paclitaxel-resistant models, both in vitro and in vivo. The major toxicities associated with Ix are myelosuppression, sensory neuropathy and neutropenia. Other minor side-effects include asthenia/fatigue, stomatitis, anorexia, alopecia, skin reaction, hypersensitivity reactions and a fluid-retention syndrome. Although Ix is functionally correlated to taxanes, no previous evidence exists regarding Ix-related nail disorders. Here, we report a case of a 59-year-old woman treated with Ix at 40 mg/m2 day 1 q 21 days who, after 8 cycles of therapy, developed onycholysis and subungual hemorrhagic bullas in the fingernails.     

Taxol and discodermolide represent a synergistic drug combination in human carcinoma cell lines.

Recently, three natural products have been identified, the epothilones, eleutherobin, and discodermolide, whose mechanism of action is similar to that of Taxol in that they stabilize microtubules and block cells in the mitotic phase of the cell cycle. In this report, we have compared and contrasted the effects of these new agents in Taxol-sensitive and -resistant cell lines. We also have taken advantage of a human lung carcinoma cell line, A549-T12, that was isolated as a Taxol-resistant cell line and found to require low concentrations of Taxol (2-6 nM) for normal cell division. This study then examined the ability of these new compounds to substitute for Taxol in sustaining the growth of A549-T12 cells. Immunofluorescence and flow cytometry have both indicated that the epothilones and eleutherobin, but not discodermolide, can substitute for Taxol in this Taxol-dependent cell line. In A549-T12 cells, the presence of Taxol significantly amplified the cytotoxicity of discodermolide, and this phenomenon was not observed in combinations of Taxol with either the epothilones or eleutherobin. Median effect analysis using the combination index method revealed a schedule-independent synergistic interaction between Taxol and discodermolide in four human carcinoma cell lines, an effect that was not observed between Taxol and epothilone B. Flow cytometry revealed that concurrent exposure of A549 cells to Taxol and discodermolide at doses that do not induce mitotic arrest caused an increase in the hypodiploid population, thereby indicating that a possible mechanism for the observed synergy is the potentiation of apoptosis. Our results suggest that Taxol and discodermolide may constitute a promising chemotherapeutic combination.     

Epothilones in breast cancer: current status and future directions

Taxanes have become fundamental in the treatment of early and advanced breast cancer. However, tumors vary in their sensitivity to these agents; resistance can be acquired or de novo resistance can occur. Epothilones and associated analogs are novel microtubule-stabilizing agents that induce apoptosis and promote cell death. There is now a growing body of clinical data describing the efficacy of epothilones in breast cancer patients who have progressed on taxanes and anthracyclines. This culminated with US FDA approval in October 2007 of ixabepilone (Ixempra, Brystol Myers Squibb, NJ, USA) either as single agent or in combination with capecitabine for the treatment of breast cancer, which has progressed after prior therapies. The results of ongoing and future randomized clinical trials will further define how epothilones, in particular ixabepilone, will be integrated into the management of early and metastatic breast cancer. In parallel, the search for biomarkers predictive of sensitivity to epothilones continues in an attempt to tailor these therapies to patients with greater accuracy.     

Efficacy and safety of ixabepilone (BMS-247550), a novel epothilone B analogue

The epothilones are a new class of non-taxane tubulin polymerization agents obtained by natural fermentation of the myxobacteria Sorangium cellulosum. The cytotoxic activities of the epothilones, like those of the taxanes, have been linked to stabilization of microtubules, but they also have important differences. Among the epothilone family, ixabepilone (BMS247550) is a semisynthetic derivative of the natural product epothilone B. Ixabepilone was evaluated in vivo in a panel of human and rodent tumour models, the majority of which were chosen because of their known, well-characterized resistance to paclitaxel, and seems able to overcome the over-expression of multidrug resistance and to be unaffected by mutations in the beta tubulin gene. The interest of ixabepilone was clinically confirmed in clinical studies of phase II which demonstrated a strong activity at the patients with metastatic breast cancer resistant to taxanes and in patients suffering of other types of chemoresistant tumors.     

Epothilones in breast cancer: current status and future directions

Taxanes have become fundamental in the treatment of early and advanced breast cancer. However, tumors vary in their sensitivity to these agents; resistance can be acquired or de novo resistance can occur. Epothilones and associated analogs are novel microtubule-stabilizing agents that induce apoptosis and promote cell death. There is now a growing body of clinical data describing the efficacy of epothilones in breast cancer patients who have progressed on taxanes and anthracyclines. This culminated with US FDA approval in October 2007 of ixabepilone (Ixempra?, Brystol Myers Squibb, NJ, USA) either as single agent or in combination with capecitabine for the treatment of breast cancer, which has progressed after prior therapies. The results of ongoing and future randomized clinical trials will further define how epothilones, in particular ixabepilone, will be integrated into the management of early and metastatic breast cancer. In parallel, the search for biomarkers predictive of sensitivity to epothilones continues in an attempt to tailor these therapies to patients with greater accuracy.     

Chromosome segregation machinery and cancer

Loss or gain of chromosomes is associated with many cancer cells. This property, called chromosome instability, might arise from a lesion in the chromosome segregation machinery. Essential for chromosome segregation are the proper connection of microtubules to kinetochores, and the synchronous segregation of sister chromatids in anaphase. Accuracy of these processes is ensured by two sophisticated machineries called the correction mechanism and the spindle assembly checkpoint. Here we outline the current understanding of the underlying mechanisms, and highlight recent challenging experiments to address how chromosome segregation failure might relate to tumorigenesis. Understanding these mechanisms may lead to the discovery of new and improved anticancer therapies. ( Cancer Sci 2009; 100: 1158–1165)     

Alkenyl group is responsible for the disruption of microtubule network formation in human colon cancer cell line HT-29 cells

Alk(en)yl trisulfides (R-SSS-R') are organosulfur compounds produced by crushed garlic and other Allium vegetables. We found that these compounds exhibit potent anticancer effects through the reaction with microtubules, causing cell cycle arrest. Nine alk(en)yl trisulfides including dimethyl trisulfide, diethyl trisulfide, dipropyl trisulfide (DPTS), dibutyl trisulfide, dipentyl trisulfide, diallyl trisulfide (DATS), dibutenyl trisulfide, dipentenyl trisulfide and allyl methyl trisulfide were synthesized and added to cultures of HT-29 human colon cancer cells at a concentration of 10 muM. The trisulfides with alkenyl groups such as DATS, but not those with alkyl groups, induced rapid microtubule disassembly at 30-60 min as well as cell cycle arrest during the mitotic phase approximately at 4 h after the treatment. Both DATS-induced microtubule disassembly and the cell cycle arrest were cancelled by the simultaneous treatment of the cancer cells with 2 mM L-cysteine, glutathione (GSH) or N-acetyl-L-cysteine. Reciprocally, L-buthionine-(S,R)-sulfoximine (500 muM), an inhibitor of GSH synthesis, enhanced the power of DATS in inducing the cell cycle arrest. These results indicate that alk(en)yl trisulfide react with sulfhydryl groups in cysteine residues of cellular proteins such as microtubule proteins. Thus, the present study provides evidence that trisulfides with alkenyl groups have potent anticancer activities, at least in part, directed toward microtubules. These findings suggest that alkenyl trisulfides and their structurally related compounds may provide novel and effective anticancer agents.     

Apoptotic and cytostatic farnesyltransferase inhibitors have distinct pharmacology and efficacy profiles in tumor models

BMS-214662 and BMS-225975 are tetrahydrobenzodiazepine-based farnesyltransferase inhibitors (FTIs) that have nearly identical structures and very similar pharmacological profiles associated with farnesyltransferase (FT) inhibition. Despite their similar activity against FT in vitro and in cells, these compounds differ dramatically in their apoptotic potency and tumor-regressing activity in vivo. BMS-214662 is the most potent apoptotic FTI known and exhibits curative responses in mice bearing a variety of staged human tumor xenografts such as HCT-116 human colon tumor. By contrast, BMS-225975 does not cause tumor regression and at best causes partial tumor growth inhibition in staged HCT-116 human colon tumor xenografts. Lack of tumor regression activity in BMS-225975 was attributable to its relatively weak apoptotic potency, not to poor cell permeability or pharmacokinetics. Both compounds were equally effective in inhibiting Ras processing and causing accumulation of a variety of nonfarnesylated substrates of FT in HCT-116 cells. Because BMS-225975 has poor apoptotic activity compared with BMS-214662 but inhibits FT to the same extent as BMS-214662, it is very unlikely that FT inhibition alone can account for the apoptotic potency of BMS-214662. Clearly distinct patterns of sensitivities in a cell line panel were obtained for the apoptotic FTI BMS-214662 and the cytostatic FTI BMS-225975. Activation of the c-Jun-NH(2)-terminal kinase pathway was readily observed with BMS-214662 but not with BMS-225975. We developed a highly sensitive San-1 murine xenograft tumor model that is particularly useful for evaluating the in vivo activity of cytostatic FTIs such as BMS-225975.     

Targeting the insulin-like growth factor axis as a cancer therapy

The insulin-like growth factor (IGF) axis has been implicated in malignant transformation and in tumor cell biology. Human population studies have demonstrated that high levels of circulating IGF-I are associated with an increased risk of certain malignancies. Many model systems show that IGFs stimulate tumor cell proliferation, survival and metastasis. In a new era of anticancer treatments aimed at tumor-specific targets, efforts are in progress for the development of novel anti-IGF therapies. Disrupting type I IGF-receptor (IGF-IR) function in vitro and in vivo results in tumor growth inhibition in several model systems. Antireceptor therapies in particular have provided encouraging results leading to the approval of the first Phase I human clinical trial targeting IGF-IR. Additional methods to decrease levels of circulating IGF-I and II have also been developed. In principle, a benefit of targeted therapies could be their relative lack of toxicity compared with conventional chemotherapy. Anti-IGF-IR therapies, however, raise theoretical concerns for the development of serious side effects, including diabetes. As targeted therapies against the IGF axis continue to be developed, efforts will need to be made to minimize the side effects that result from blocking normal ligand and receptor-induced functions.