Pierre Bischoff

A Ruthenium-Containing Organometallic Compound Reduces Tumor Growth through Induction of the Endoplasmic Reticulum Stress Gene CHOP

Cisplatin-derived anticancer therapy has been used for three decades despite its side effects. Other types of organometallic complexes, namely, some ruthenium-derived compounds (RDC), which would display cytotoxicity through different modes of action, might represent alternative therapeutic agents. We have studied both in vitro and in vivo the biological properties of RDC11, one of the most active compounds of a new class of RDCs that contain a covalent bond between the ruthenium atom and a carbon. We showed that RDC11 inhibited the growth of various tumors implanted in mice more efficiently than cisplatin. Importantly, in striking contrast with cisplatin, RDC11 did not cause severe side effects on the liver, kidneys, or the neuronal sensory system. We analyzed the mode of action of RDC11 and showed that RDC11 interacted poorly with DNA and induced only limited DNA damages compared with cisplatin, suggesting alternative transduction pathways. Indeed, we found that target genes of the endoplasmic reticulum stress pathway, such as Bip, XBP1, PDI, and CHOP, were activated in RDC11-treated cells. Induction of the transcription factor CHOP, a crucial mediator of endoplasmic reticulum stress apoptosis, was also confirmed in tumors treated with RDC11. Activation of CHOP led to the expression of several of its target genes, including proapoptotic genes. In addition, the silencing of CHOP by RNA interference significantly reduced the cytotoxicity of RDC11. Altogether, our results led us to conclude that RDC11 acts by an atypical pathway involving CHOP and endoplasmic reticulum stress, and thus might provide an interesting alternative for anticancer therapy.

Signal transduction pathways of taxanes-induced apoptosis.

Docetaxel (Taxotere) is a member of the taxane class of anticancer agents to reach clinical use. This semisynthetic analog of paclitaxel (Taxol) is one of the newer potent anti-neoplastic agents now undergoing extensive laboratory and clinical investigations. Several studies indicate that antimicrotubule agents are potent promoters of apoptosis in cancer cells. Cytotoxic mechanisms of antimitotic taxoids are not yet fully understood, but it has been demonstrated that docetaxel increases tubulin polymerisation, promotes microtubule assembly and also inhibits tubulin depolymerisation. Disruption of microtubules results also in the induction of tumor suppressor gene p53 and inhibitor of cyclin-dependent kinases and activation/inactivation of several protein kinases. As a consequence cells are arrested in the G2-M phase of the cell cycle, after which they may either undergo cell death by apoptosis or necrosis or overcome the G2-M stop and continue in the division cycle (often toward a post-mitotic cell death) depending on the tumor cell type. Nevertheless, how docetaxel induces apoptotic cell death or caspases activation is not yet defined. One may assume that taxanes are able to induce the phosphorylation of Bcl-X(L)/Bcl-2 members and thus inactivate their anti-apoptotic capacities. The down-regulation of Bcl-2 and/or the upregulation of p53 and p21/WAF-1 are certainly one of the important modes of apoptosis induction by taxanes. The aim of this framework is to summarize the effects of microtubuline targeting agents on apoptotic signal transduction and new molecular pathways. Finally, we will also discuss the potential therapeutic interest in the association of docetaxel and ionizing radiation.

Radiation countermeasure agents: an update

Importance of the field: Ionizing radiation (IR) can produce deleterious effects in living tissues, leading to significant morbidity and a potentially fatal illness affecting various organs dose-dependently. As people may be exposed to IR during cancer radiotherapy or as a result of a radiological/nuclear incident or act of terrorism, the danger of irradiation represents a serious public health problem. At present, however, this problem remains largely impervious to medical management. There is, therefore, a pressing need to develop safe and effective radiation countermeasure (RC) agents to prevent, mitigate or treat the harmful consequences of IR exposure. Areas covered in this review: Recent advances in the search for RC agents as reflected by the relevant patent literature of the past five years along with peer-reviewed publications are surveyed. What the reader will gain: A total of 43 patents, describing ∼ 38 chemically diverse compounds with RC potential are analyzed. These include antioxidants capable of scavenging IR-induced free radicals, modulators of cell death signaling or cell cycle progression, cytokines or growth factors promoting tissue repair and inhibitors of inflammatory cytokines. Take home message: Several of these RC candidates appear promising, including at least two that are undergoing evaluation for fast-track clinical development.

Radiosensitising agents for the radiotherapy of cancer: advances in traditional and hypoxia targeted radiosensitisers

Background: Radiotherapy is utilised for the treatment of ∼ 50% of patients with solid tumours, but its efficacy is limited by normal tissue toxicity and by the intrinsic or acquired radioresistance of many tumours. The combination of radiotherapy with chemotherapeutic agents that preferentially sensitise tumour cells to its cytotoxic effects has thus long been considered as a strategy to enhance cancer therapy. However, current chemoradiotherapy protocols remain highly unsatisfactory. Therefore, continuing efforts are being conducted to identify improved radiosensitising agents. Objective: To survey the patent literature and associated peer-reviewed publications of the past 4 years pertaining to the development of novel radiosensitising agents, with a focus on anticancer drugs traditionally used as radiosensitisers and on agents targeting radioresistant hypoxic tumour cells. Methods: Patents were searched with a set of relevant keywords using several search engines (ep.espacenet.com/, www.freepatentsonline.com/, patft.uspto.gov/). A Medline search on the same topics was performed in parallel. Results/conclusion: A total of 37 patents/applications were retrieved. Of these, 14 concern the use of conventional anticancer cytotoxic drugs for tumour radiosensitisation. The other patents mostly disclose novel hypoxic radiosensitisers, bioreductive drugs and inhibitors of hypoxia-inducible factor-1. Whether these advances will translate into clinically valuable radiosensitisers is, however, unclear.

Caspase 8-mediated cleavage of the pro-apoptotic BCL-2 family member BID in p53-dependent apoptosis

The objective of this study was to characterize the apoptotic pathways activated by fast neutrons in the human lymphoblastoid cell line TK6 and in its p53 -/- derivative. Our results demonstrate that while p53 is not required for neutron-induced apoptosis, as previously shown, it does affect the kinetics of apoptosis and the molecular pathways leading to the activation of effector caspases. Indeed, rapid p53-dependent apoptosis was associated with the activation of caspase 9, 8, 3, and 7 and the cleavage of BID by caspase 8. In contrast, the slow-occurring p53-independent apoptotic process, mediated by caspase 7, took place without BID cleavage and loss of transmembrane mitochondrial potential. Altogether, our findings highlight an essential role for caspase 8-mediated BID cleavage, in the course of p53-dependent apoptosis triggered by fast neutrons in lymphoid cells. They also demonstrate that this mechanism is not involved in p53-independent apoptosis.

High-LET radiation combined with oxaliplatin induce autophagy in U-87 glioblastoma cells

Modern protocols of concomitant chemo/radiotherapy provide a very effective strategy to treat certain types of tumors. High-linear energy transfer (LET) radiations, on the other hand, have an increased efficacy against cancer with low radiosensibility and critical localization. We previously reported that oxaliplatin, a third generation platinum drug, was able to reinforce the cytotoxicity of an irradiation by fast neutrons towards human glioblastoma U-87 cells in culture. We show here that such a combination has the capacity to enhance the number of double strand breaks in DNA and to induce autophagy in these cells. Xenografts experiments were further performed in nude mice subcutaneously transplanted with U-87 cells. When injected shortly before a single irradiation by fast neutrons, oxaliplatin causes a marked reduction of tumor growth compared with the irradiation alone. Overall, our data indicate the unique cytotoxic mechanism of a combined high-LET irradiation and oxaliplatin treatment modality and suggest its potential application in anticancer therapy.

Radiosensitising agents for the radiotherapy of cancer: novel molecularly targeted approaches.

Background: The efficacy of radiotherapy (RT) for cancer treatment is limited by normal tissue toxicity and by the intrinsic or acquired radioresistance of many tumours. Therefore, continuing efforts are conducted to identify radiosensitising agents that preferentially sensitise tumour cells to the cytotoxic action of RT. Recent progresses in molecular oncology have uncovered an array of novel targets, which may be exploited for RT enhancement. Objective: To survey the patent literature of the past 4 years pertaining to the development of molecularly targeted agents as potential tumour radiosensitisers. Methods: Patents were searched with a set of relevant keywords using several search engines. A Medline search on the same topics was performed in parallel. Results/conclusion: A total of 48 patents/applications were selected. These concerned agents target molecular components of pathways involved in DNA damage repair, cell growth and survival signalling, apoptosis modulation and tumour angiogenesis. Current trials of some of these agents may reveal their value as clinical radiosensitisers.

Disrupting the mTOR Signaling Network as a Potential Strategy for the Enhancement of Cancer Radiotherapy

Radiotherapy (RT) allows for tumor control through the cytotoxic action of ionizing radiation (IR). Although modern technologies permit precise IR delivery to the tumor mass while minimizing exposure of surrounding healthy tissues, the efficacy of RT remains limited by the intrinsic or acquired radioresistance of many tumors. There is thus an ongoing search for agents that augment the sensitivity of tumor cells to IR cytotoxicity, with recent interest in targeting components of signaling pathways involved in tumor growth and radioresistance. Here, we review the evidence suggesting that disabling one of these components, the mechanistic target of rapamycin (mTOR) kinase, may enhance RT efficacy. This molecule constitutes the catalytic subunit of the mTORC1 and mTORC2 protein complexes, which regulate cell growth and other processes implicated in tumorigenesis. Much work has focused on mTORC1 because it is selectively blocked by the microbial product rapamycin and its analogs (collectively designated rapamycins) that are approved for cancer treatment, and is frequently hyperactivated in malignant cells. In several, but not all human cancer cell lines, rapamycins increased IR cytotoxicity in vitro, apparently through multiple mechanisms, including the promotion of autophagic cell death. Rapamycins also potentiated fractionated RT in tumor xenograft models, in part by suppressing tumor angiogenesis. Synthetic kinase inhibitors that simultaneously target PI3K and both mTOR complexes also enhanced RT in vitro and in vivo, but with greater efficiency than rapamycins. These encouraging data have led to early clinical trials of rapamycins and catalytic mTOR inhibitors combined with RT in various cancers.

The mTOR inhibitor RAD001 augments radiation-induced growth inhibition in a hepatocellular carcinoma cell line by increasing autophagy

Treatment of hepatocellular carcinoma (HCC) is a major concern for physicians as its response to chemotherapy and radiotherapy remains generally poor, due, in part, to intrinsic resistance to either form of treatment. We previously reported that an irradiation with fast neutrons, which are high-linear energy transfer (LET) particles, massively induced autophagic cell death in the human HCC SK-Hep1 cell line. In the present study, we tested the capacity of the mammalian target of rapamycin (mTOR) inhibitor RAD001 to augment the cytotoxicity of low and high-LET radiation in these cells. As mTOR is a key component in a series of pathways involved in tumor growth and development, it represents a potential molecular target for cancer treatment. Results indicate that RAD001, at clinically relevant nanomolar concentrations, enhances the efficacy of both high- and low-LET radiation in SK-Hep1 cells, and that the induction of autophagy may account for this effect. However, fast neutrons were found to be more efficient at reducing tumor cell growth than low-LET radiation.

Non-erythropoietic tissue-protective peptides derived from erythropoietin: WO2009094172

Erythropoietin (EPO) is a cytokine with erythropoietic and tissue protective activities. Its action as a tissue protective agent requires, however, high dosage that results in limiting side effects associated with abnormally augmented erythropoiesis. Elimination of the erythropoietic activity of EPO while preserving its tissue protective properties was nevertheless achieved in carbamoylated EPO (CEPO), whose therapeutic activity and apparent safety were documented in experimental models of nervous, heart, kidney and other tissue damage, justifying ongoing clinical trials. Here, we review patent application WO2009094172 by Araim Pharmaceuticals, which describes novel EPO-derived peptides having tissue protective but no erythropoietic activity. The preferred peptide, UEQLERALNSS, which mimics the external 3D structure of the helix B of EPO, was shown to exhibit the same spectrum of tissue protective activity as CEPO in several in vivo models. In addition, it could reduce radiation-induced mortality when administered 24 h after irradiation in mice, suggesting its possible utility in emergency situations after mass irradiation casualties. Owing to their low manufacturing cost, high stability and low immunogenicity, such peptides might well offer a superior alternative to CEPO for therapeutic tissue protection in human pathologies and are likely to provide valuable probes to study the molecular mechanisms of EPO-mediated cytoprotection.