Nicolas Guilbaud

Triptolide is an inhibitor of RNA polymerase I and II–dependent transcription leading predominantly to down-regulation of short-lived mRNA

Triptolide, a natural product extracted from the Chinese plant Tripterygium wilfordii, possesses antitumor properties. Despite numerous reports showing the proapoptotic capacity and the inhibition of NF-κB–mediated transcription by triptolide, the identity of its cellular target is still unknown. To clarify its mechanism of action, we further investigated the effect of triptolide on RNA synthesis in the human non–small cell lung cancer cell line A549. Triptolide inhibited both total RNA and mRNA de novo synthesis, with the primary action being on the latter pool. We used 44K human pan-genomic DNA microarrays and identified the genes primarily affected by a short treatment with triptolide. Among the modulated genes, up to 98% are down-regulated, encompassing a large array of oncogenes including transcription factors and cell cycle regulators. We next observed that triptolide induced a rapid depletion of RPB1, the RNA polymerase II main subunit that is considered a hallmark of a transcription elongation blockage. However, we also show that triptolide does not directly interact with the RNA polymerase II complex nor does it damage DNA. We thus conclude that triptolide is an original pharmacologic inhibitor of RNA polymerase activity, affecting indirectly the transcription machinery, leading to a rapid depletion of short-lived mRNA, including transcription factors, cell cycle regulators such as CDC25A, and the oncogenes MYC and Src. Overall, the data shed light on the effect of triptolide on transcription, along with its novel potential applications in cancers, including acute myeloid leukemia, which is in part driven by the aforementioned oncogenic factors. [Mol Cancer Ther 2009;8(10):2780–90]

Melanoma Chemotherapy Leads to the Selection of ABCB5-Expressing Cells

Metastatic melanoma is the most aggressive skin cancer. Recently, phenotypically distinct subpopulations of tumor cells were identified. Among them, ABCB5-expressing cells were proposed to display an enhanced tumorigenicity with stem cell-like properties. In addition, ABCB5+ cells are thought to participate to chemoresistance through a potential efflux function of ABCB5. Nevertheless, the fate of these cells upon drugs that are used in melanoma chemotherapy remains to be clarified. Here we explored the effect of anti-melanoma treatments on the ABCB5-expressing cells. Using a melanoma xenograft model (WM266-4), we observed in vivo that ABCB5-expressing cells are enriched after a temozolomide treatment that induces a significant tumor regression. These results were further confirmed in a preliminary study conducted on clinical samples from patients that received dacarbazine. In vitro, we showed that ABCB5-expressing cells selectively survive when exposed to dacarbazine, the reference treatment of metastatic melanoma, but also to vemurafenib, a new inhibitor of the mutated kinase V600E BRAF and other various chemotherapeutic drugs. Our results show that anti-melanoma chemotherapy might participate to the chemoresistance acquisition by selecting tumor cell subpopulations expressing ABCB5. This is of particular importance in understanding the relapses observed after anti-melanoma treatments and reinforces the interest of ABCB5 and ABCB5-expressing cells as potential therapeutic targets in melanoma.

Preclinical activity of F14512, designed to target tumors expressing an active polyamine transport system

SummaryWe have exploited the polyamine transport system (PTS) to deliver selectively a spermine-drug conjugate, F14512 to cancer cells. This study was aimed to define F14512 anticancer efficacy against tumor models and to investigate whether fluorophor-labeled polyamine probes could be used to identify tumors expressing a highly active PTS and that might be sensitive to F14512 treatments. Eighteen tumor models were used to assess F14512 antitumor activity. Cellular uptake of spermine-based fluorescent probes was measured by flow cytometry in cells sampled from tumor xenografts by needle biopsy. The accumulation of the fluorescent probe within B16 tumors in vivo was assessed using infrared fluorescence imaging. This study has provided evidence of a major antitumor activity for F14512. Significant responses were obtained in 67% of the tumor models evaluated, with a high level of activity recorded in 33% of the responsive models. Complete tumor regressions were observed after i.v., i.p. or oral administrations of F14512 and its antitumor activity was demonstrated over a range of 2–5 dose levels, providing evidence of its good tolerance. The level of cellular fluorescence emitted by the fluorescent probes was higher in cells sampled from tumors sensitive to F14512 treatments than from F14512-refractory tumors. We suggest that these probes could be used to identify tumors expressing a highly active PTS and guide the selection of patients that might be treated with F14512. These results emphasize the preclinical interest of this novel molecule and support its further clinical development.

Synthesis of conjugated spermine derivatives with 7-nitrobenzoxadiazole (NBD), rhodamine and bodipy as new fluorescent probes for the polyamine transport system

The synthesis of a series of conjugated spermine derivatives with benzoxadiazole, phenylxanthene or bodipy fluorophores is described. These fluorescent probes were used to identify the activity of the polyamine transport system (PTS). N(1)-Methylspermine NBD conjugate 5 proved to have the optimal fluorescence characteristics and was used to show a selectivity for PTS-proficient CHO versus PTS-deficient CHO-MG cells. It can therefore be used as a tool for the selection of cells sensitive to cytotoxic compounds vectored through the PTS.

Acronycine derivatives as promising antitumor agents.

Originally isolated from an Australian plant, acronycine is an antitumor alkaloid with poor water solubility and low potency. The modest antitumor activity of this compound was markedly improved by the total synthesis of original analogs resulting in the selection of S23906-1, a diester derivative of 1,2-dihydrobenzo[b]acronycine. S23906-1 is characterized in vitro by a high potency in clonogenic assays and uncommon cell cycle pertubations. In vivo, this compound demonstrated a selectivity for human solid tumors as compared to murine transplantable tumors. The unique pharmacological profile of S23906-1 was particularly defined by a broad antitumor efficacy when administered i.v. or orally on aggressive orthotopic models of human lung, ovarian and colon models with comparable or better activity than clinically used anticancer drugs. The molecular mechanism of action of S23906-1 could involve DNA alkylation, modulation of cyclin E protein levels and inhibition of DNA synthesis leading to apoptosis. Ongoing preclinical toxicological studies will help to define the potential of this novel agent which is already considered as a valuable candidate for clinical studies.

Cytotoxicity and cell death mechanisms induced by the polyamine-vectorized anti-cancer drug F14512 targeting topoisomerase II

The polyamines transport system (PTS) is usually enhanced in cancer cells and can be exploited to deliver anticancer drugs. The spermine-conjugated epipodophyllotoxin derivative F14512 is a topoisomerase II poison that exploits the PTS to target preferentially tumor cells. F14512 has been characterized as a potent anticancer drug candidate and is currently in phase 1 clinical trials. Here we have analyzed the mechanisms of cell death induced by F14512, compared to the parent drug etoposide lacking the polyamine tail. F14512 proved to be >30-fold more cytotoxic than etoposide against A549 non-small cell lung cancer cells and triggers less but unrecoverable DNA damages. The cytotoxic action of F14512 is extremely rapid (within 3 h) and does not lead to a marked accumulation in the S-phase of the cell cycle, unlike etoposide. Interestingly, A549 cells treated with F14512 were less prone to undergo apoptosis (neither caspases-dependent nor caspases-independent pathways) or autophagy but preferentially entered into senescence. Drug-induced senescence was characterized qualitatively and quantitatively by an increased β-galactosidase activity, both by cytochemical staining and by flow cytometry. A morphological analysis by electron microscopy revealed the presence of numerous multi-lamellar and vesicular bodies and large electron-lucent (methuosis-like) vacuoles in F14512-treated cell samples. The mechanism of drug-induced cell death is thus distinct for F14512 compared to etoposide, and this difference may account for their distinct pharmacological profiles and the markedly superior activity of F14512 in vivo. This study suggests that senescence markers should be considered as potential pharmacodynamic biomarkers of F14512 antitumor activity.

In vivo antitumor activity of S 16020-2, a new olivacine derivative.

Abstract The antitumor activity of S 16020-2, a new olivacine derivative, was investigated in vivo and compared with that of Adriamycin and elliptinium acetate in a panel of murine (P388 leukemia, M5076 sarcoma, Lewis lung carcinoma, and B16 melanoma) and human (NCI-H460 non-small-cell lung and MCF7 breast carcinomas) tumor models. S 16020-2 given i.v. was active against P388 leukemia implanted i.p., s.c., or intracerebrally. The therapeutic effect of an intermittent schedule (administration on days 1, 5, 9) was superior to that of single-dose treatment, allowing the i.v. administration of high total doses of S 16020-2 and resulting in the cure of 60% of mice in the i.p. P388 model. In this model, S 16020-2 was more active than elliptinium acetate and showed a better therapeutic index than Adriamycin:≥8 versus 2. A good therapeutic effect of S 16020-2 was also observed in three P388 leukemia sublines displaying the classic multidrug-resistance phenotype, namely, P388/VCR, P388/VCR-20, and P388/MDRC.04, the latter being totally insensitive to vincristine and Adriamycin. However, S 16020-2 was not active against the P388/ADR leukemia, a model highly resistant to adriamycin in vivo. S 16020-2 was both more active than Adriamycin and curative in the M5076 sarcoma and Lewis lung carcinoma implanted s.c. In the B16 melanoma implanted i.p. or s.c., S 160202 was less active than Adriamycin. Against the NCI-H460 human tumor xenograft, S 16020-2 demonstrated activity superior to that of Adriamycin (T/C=20% versus 43% on day 21). Against the MCF7 breast cancer xenograft, S 16020-2 was active, but less so than Adriamycin (T/C=23% versus 9% on day 21), whereas elliptinium acetate was marginally active (T/C=49% on day 24). The hematological toxicity of S 16020-2 given to B6D2F1 mice at pharmacological dose appeared to be less severe than that of Adriamycin, particularly in bone-marrow stem cells. These results demonstrate that S 16020-2 is a highly active antitumor drug in various experimental tumor models and is markedly more efficient than elliptinium acetate. Because of its pharmacological profile, which is globally different from that of Adriamycin, S 16020-2 is considered an interesting candidate for clinical trials.

Novel bicyclic oxazolone derivatives as anti-Angiogenic agents

Novel bicyclic tetrahydropyrano[3,2-d]oxazolones derivatives, analogues of Fumagillin, were synthesised via a stereocontrolled oxidative-rearrangement of furylcarbinols and subsequent treatment with the appropriate isocyanate. These compounds demonstrated potent antiangiogenic activity.

Eriochrome Black T, structurally related to suramin, inhibits angiogenesis and tumor growth in vivo.

The polyanionic species suramin is a potential anti-cancer agent of narrow therapeutic index. Among other pharmacological characteristics, suramin is an inhibitor of angiogenesis. We have targeted its angiostatic properties as part of a program to discover less toxic analogs. From screening a series of commercially available compounds, structurally related to suramin and containing a sulfonic acid substituted naphthylamine moiety, we discovered a new lead, Eriochrome Black T (EBT). EBT is a novel inhibitor of angiogenesis, more potent and less toxic than suramin in the chick chorioallantoic membrane assay. EBT was more active than suramin in inhibiting endothelial cell proliferation in primary culture and in inhibiting proliferation of three tumor cell lines, A431, L1210 and M5076 (IC50 10-100µM). Cell cycle studies on the A431 line showed that both EBT and suramin caused an accumulation of cells in the S phase, EBT being 10-fold more potent. We suggest that this cell cycle perturbation is linked to inhibition of topoisomerase II catalytic activity. EBT was found to be a moderate but significant inhibitor of matrix metalloproteinases (10µM range), more efficient than suramin. In a s.c. M5076 sarcoma model in mice, EBT had similar efficacy to suramin both by the i.p. or s.c. route and was moreover better tolerated. Combined pharmacological results show that EBT compared favorably with suramin in all assays, and that in ovo and in vivo, EBT is an analog of suramin with diminished toxicity.

Antitumor activity of S 16020-2 in two orthotopic models of lung cancer.

S 16020-2, a new olivacine derivative selected on the basis of its cytotoxicity in vitro and antitumor activity in vivo, was evaluated against the human A549 and the murine Lewis lung tumor models implanted s.c. and i.v. Against Lewis lung carcinoma implanted s.c, S 16020-2 was found to be curative, with an activity and therapeutic index (77= 4) similar to that of cyclophosphamide. S 16020-2 administered weekly demonstrated a high therapeutic efficacy against A549 non-small cell lung carcinoma implanted s.c. in nude mice and induced tumor regression at 80mg/kg. When A549 tumor cells were injected i.v. in SCID mice, experimental metastases rapidly developed and the progressive invasion of the lung tissue by tumor preceded the death of animals. In this model, S 16020-2 administered at 40mg/kg i.v. following an early (days 8, 18 and 28) or delayed (days 20, 30 and 40) treatment schedule prolonged the survival of tumor-bearing mice with T/C values of 150 and 145%, respectively. Against the i.v. Lewis lung carcinoma, S 16020-2 was also highly active since when administered at 60 mg/kg on days 5, 9 and 13 it totally inhibited tumor growth and cured up to 89% of mice. When administered on days 11, 15 and 19 to animals with established tumors, S 16020-2 was still active but not curative. In the presented studies, S 16020-2 antitumor activity was superior to that of adriamycin and comparable or superior to cyclophosphamide (used as reference compounds). Our results demonstrate the efficacy of S 16020-2 against these highly agressive and chemoresistant tumor models.