Nives Carenini

Design, synthesis and anticancer activities of stilbene-coumarin hybrid compounds: Identification of novel proapoptotic agents.

The naturally occurring coumarins and resveratrol, attract great attention due to their wide range of biological properties, including anticancer, antileukemic, antibacterial and anti-inflammatory activities; moreover, their cancer chemopreventive property have been recently emphasized. A novel class of hybrid compounds, obtained by introducing a substituted trans-vinylbenzene moiety on a coumarin backbone, was synthesized and evaluated for the antitumor profile. A number of derivatives showed a good antiproliferative activity, in some cases higher to that of the reference compound resveratrol. The most promising compounds in this series were 14 and 17, endowed with excellent antiproliferative and proapoptotic activities. The present study suggests that the 7-methoxycoumarin nucleus, together with the 3,5-disubstitution pattern of the trans-vinylbenzene moiety, are likely promising structural features to obtain excellent antitumor compounds endowed with a apoptosis-inducing capability.

In vitro and in vivo interaction between cisplatin and topotecan in ovarian carcinoma systems

Abstract Topotecan, a camptothecin analogue, is a␣specific inhibitor of topoisomerase I approved for use in the treatment of patients with refractory ovarian carcinoma. The drugs mechanism of action suggests a potential efficacy of drug combinations incorporating DNA-damaging agents. In an attempt better to define a␣rational basis for drug combination we examined the effect of topotecan on the cytotoxicity and antitumor activity of cisplatin in an ovarian carcinoma system growing in vitro and in vivo as a tumor xenograft. The in vitro cell system included a cisplatin-sensitive cell line, IGROV-1, and a cisplatin-resistant subline, IGROV-1/Pt0.5, which is characterized by p53 mutation and loss of normal function of the wild-type gene of the parental cell line. This cell system was chosen since the cell sensitivity to DNA-damaging agents appears to be dependent on p53 gene status. Cytotoxicity was assessed by the growth inhibition assay using different schedules: (a) a 1-h period of cisplatin exposure followed by a 24-h topotecan treatment and (b) a 1-h period of simultaneous exposure to cisplatin and topotecan. In the case of the sequential schedule, an additive interaction was observed in IGROV-1 and IGROV-1/Pt0.5 cells. When the simultaneous schedule was used, a synergistic interaction, more evident for the cisplatin-sensitive cells, was found. On the basis of these observations at a cellular level, the effect of concomitant administration of the two drugs (i.e., the most favorable schedule) was studied in the IGROV-1 tumor xenograft, which is moderately responsive to cisplatin and topotecan. Suboptimal doses of each drug (with a low dose of topotecan, 5.1 mg/kg) achieved an antitumor effect comparable with or superior to that of the optimal dose of a single treatment (tumor weight inhibition, 60%), thus indicating a␣pharmacological advantage of the combination over the single treatment. However, an increase in the topotecan dose (7.1 mg/kg) was associated with an evident increase in the toxicity of the combination, thereby suggesting that the drug interaction was not tumor-specific. Although the molecular basis of the drug interaction is not clear, it is likely that inhibition of topoisomerase I affects the ability of cells to repair cisplatin adducts. Such findings may have pharmacological implications since they suggest the potential clinical interest of topoisomerase I inhibitors in combination with cisplatin.

Activation of ATM and Chk2 kinases in relation to the amount of DNA strand breaks

The diverse checkpoint responses to DNA damage may reflect differential sensitivities by molecular components of the damage-signalling network to the type and amount of lesions. Here, we determined the kinetics of activation of the checkpoint kinases ATM and Chk2 (the latter substrate of ATM) in relation to the initial yield of genomic DNA single-strand (SSBs) and double-strand breaks (DSBs). We show that doses of γ-radiation (IR) as low as 0.25 Gy, which generate vast numbers of SSBs but only a few DSBs per cell (<8), promptly activate ATM kinase and induce the phosphorylation of the ATM substrates p53–Ser15, Nbs1–Ser343 and Chk2–Thr68. The full activation of Chk2 kinase, however, is triggered by treatments inflicting >19 DSBs per cell (e.g. 1 Gy), which cause Chk2 autophosphorylation on Thr387, Chk2-dependent accumulation of p21waf1 and checkpoint arrest in the S phase. Our results indicate that, in contrast to ATM, Chk2 activity is triggered by a greater number of DSBs, implying that, below a certain threshold level of lesions (<19 DSBs), DNA repair can occur through ATM, without enforcing Chk2-dependent checkpoints.

Ovarian cancer cisplatin-resistant cell lines: Multiple changes including collateral sensitivity to Taxol

BACKGROUND Alteration in apoptosis pathways (in particular mutations of p53 gene) may result in resistance of ovarian carcinoma to cisplatin. However, cisplatin resistance is likely to be multifactorial. An understanding of the molecular alterations associated with the development of resistance may be of considerable relevance in an attempt to optimize the therapeutic approach. STUDY DESIGN Two cisplatin-resistant sublines (IGROV-1/Pt0.5 and IGROV-1/Pt1), both characterized by mutant p53 (Cancer Res 1996; 56: 556-62), but with different degree of resistance were studied in terms of pattern of cross-resistance, susceptibility to drug-induced apoptosis, expression of gluthathione-dependent system, cellular pharmacokinetics, drug-induced DNA damage. The resistance index (ratio between the IC50 of resistant and sensitive cells) after a 96-hour drug exposure was 10 for IGROV-1/Pt0.5 and 14 for IGROV-1/Pt1 cells. RESULTS Resistant cells were cross-resistant to DNA-damaging agents and, interestingly, they had a collateral sensitivity to Taxol. The cellular response to Taxol paralleled the drug ability to induce apoptosis. The intracellular glutathione level was significantly increased in IGROV-1/Pt cells compared to the sensitive counterpart. In contrast, glutathione S-transferase level was consistently reduced in both sublines. gamma-Glutamyl transpeptidase activity, which was lower in resistant than in sensitive cells, was not directly correlated with glutathione level, thus suggesting a complex regulation of cellular glutathione content. In the resistant cells with the highest glutathione content, a reduced level of cisplatin-induced cross-link was found. Analysis of DNA platination revealed a slight decrease of DNA-bound platinum only in IGROV-1/Pt1 cells. Again, this reduction is consistent with a protective role for glutathione. The expression of metallothionein IIa was increased in both resistant variants. CONCLUSIONS Multiple changes are involved in acquired resistance of ovarian carcinoma cells including reduced susceptibility to apoptosis as consequence of inactivation of p53 and expression of defence mechanisms. The relative contribution is related to the degree of drug resistance. In particular, the glutathione-dependent system could have a role only in the development of a high degree of resistance. Finally, the finding that Taxol was very effective in inducing apoptosis in resistant sublines with p53 mutation supports the expression of an intact p53-independent pathway of apoptosis and suggests the pharmacological interest of Taxol in the treatment of p53-mutated tumors.

Increased levels and defective glycosylation of MRPs in ovarian carcinoma cells resistant to oxaliplatin

Pt compounds still represent the mainstay of the treatment of ovarian carcinoma. The aim of the present study was to investigate the molecular bases of resistance to Pt drugs using an oxaliplatin-resistant ovarian carcinoma cell model IGROV-1/OHP. These cells exhibited high levels of resistance to oxaliplatin, cross-resistance to cisplatin and topotecan and displayed a marked accumulation defect of Pt drugs. This feature was associated with increased expression and altered N-linked glycosylation of ATP binding cassette transporters MRP1 and MRP4. Pre-treatment with tunicamycin, which inhibits the biosynthesis of N-linked oligosaccharides, decreased the accumulation of Pt in sensitive cells exposed to oxaliplatin or cisplatin and increased the electrophoretic mobility of MRP1 and MRP4, reproducing the association between decreased glycosylation of MRP1 and MRP4 and decreased Pt accumulation observed in the resistant IGROV-1/OHP cells. The observed N-glycosylation defect of oxaliplatin-resistant cells was linked to reduced levels of N-acetylglucosamine-1-phosphotransferase (GNPTG) and mannosyl (alpha-1,6-)-glycoprotein beta-1,6-N-acetyl-glucosaminyltransferase (MGAT5). This feature, observed in IGROV-1/OHP cells, was associated with decreased retention of Pt drugs. In addition, the overexpression of fully glycosylated MRP1 or MRP4 in tumor cell line of ovarian origin was associated with resistance to oxaliplatin and cisplatin. Our findings, showing that development of resistance to oxaliplatin results in up-regulation of MRPs, support that patients with oxaliplatin-refractory ovarian carcinomas may benefit from non-Pt-based regimens which do not contain MRP1 and MRP4 substrates.

Decreased Drug Accumulation and Increased Tolerance to DNA Damage in Tumor Cells with a Low Level of Cisplatin Resistance

In an attempt to examine the cellular changes associated with cisplatin resistance, we selected a cisplatin-resistant (A43 1/Pt) human cervix squamous cell carcinoma cell line following continuous in vitro drug exposure. The resistant subline was characterized by a 2.5-fold degree of resistance. In particular, we investigated the expression of cellular defence systems and other cellular factors probably involved in dealing with cisplatin-induced DNA damage. Resistant cells exhibited decreased platinum accumulation and reduced levels of DNA-bound platinum and interstrand cross-link frequency after short-term drug exposure. Analysis of the effect of cisplatin on cell cycle progression revealed a cisplatin-induced G2M arrest in sensitive and resistant cells. Interestingly, a slowdown in S-phase transit was found in A431/Pt cells. A comparison of the ability of sensitive and resistant cells to repair drug-induced DNA damage suggested that resistant cells were able to tolerate higher levels of cisplatin-induced DNA damage than their parental counterparts. Analysis of the expression of proteins involved in DNA mismatch repair showed a decreased level of MSH2 in resistant cells. Since MSH2 seems to be involved in recognition of drug-induced DNA damage, this change may account for the increased tolerance to DNA damage observed in the resistant subline. In conclusion, the involvement of accumulation defects and the increased tolerance to cisplatin-induced DNA damage in these cisplatin-resistant cells support the notion that multiple changes contribute to confer a low level of cisplatin resistance.

Synthesis and Biological Evaluation (in Vitro and in Vivo) of Cyclic Arginine–Glycine–Aspartate (RGD) Peptidomimetic–Paclitaxel Conjugates Targeting Integrin αVβ3

A small library of integrin ligand-paclitaxel conjugates 10-13 was synthesized with the aim of using the tumor-homing cyclo[DKP-RGD] peptidomimetics for site-directed delivery of the cytotoxic drug. All the paclitaxel-RGD constructs 10-13 inhibited biotinylated vitronectin binding to the purified αVβ3 integrin receptor at low nanomolar concentration and showed in vitro cytotoxic activity against a panel of human tumor cell lines similar to that of paclitaxel. Among the cell lines, the cisplatin-resistant IGROV-1/Pt1 cells expressed high levels of integrin αVβ3, making them attractive to be tested in in vivo models. cyclo[DKP-f3-RGD]-PTX 11 displayed sufficient stability in physiological solution and in both human and murine plasma to be a good candidate for in vivo testing. In tumor-targeting experiments against the IGROV-1/Pt1 human ovarian carcinoma xenotransplanted in nude mice, compound 11 exhibited a superior activity compared with paclitaxel, despite the lower (about half) molar dosage used.

Development of resistance to a trinuclear platinum complex in ovarian carcinoma cells

BBR3464 is a trinuclear platinum complex that exhibits a potent cytotoxicity and efficacy against cisplatin‐resistant tumors. To better understand the determinants of cellular resistance to BBR3464, we selected a resistant ovarian carcinoma cell line after exposure to the complex. The resistant cells (A2780/BBR3464) exhibited a high level of resistance to the selecting agent, but a marginal cross‐resistance to cisplatin. Although cellular accumulation of BBR3464 was similar in parental and in resistant cells, DNA platination was decreased in A2780/BBR3464 cells, suggesting a reduced drug accessibility to DNA. This behavior reflected a partial drug inactivation at cytoplasmic level, as a consequence of increased levels of nucleophilic molecules including metallothioneins and human neurofilament low, but not glutathione. A2780/BBR3464 cells also exhibited a reduced susceptibility to apoptosis, which was consistent with reduced expression of Bax, and an alteration of DNA mismatch repair system, as reflected by lack of expression of MLH1 and PMS2, which could impair the recognition/repair of DNA lesions. Whereas both platinum drugs induced G2/M arrest in the parental cells, BBR3464, but not cisplatin, caused a late G1 arrest of resistant cells. Cisplatin induced an appreciable increase of p21WAF1 levels in both models, in contrast to BBR3464 that produced a substantial upregulation of p21WAF1 only in parental cells. An inverse relationship with p21WAF1 modulation was found for CHK1 in parental cells treated with both agents and in resistant cells treated with cisplatin. This pattern of response is consistent with a regulatory loop involving p53 and p21WAF1 at G2 checkpoint. In contrast, no modulation of CHK1 was found in A2780/BBR3464 treated with the triplatinum compound. These findings, indicating a different activation of regulatory pathways at DNA damage checkpoints in response to cisplatin and BBR3464, support an altered ability of resistant cells to recognize or tolerate sublethal lesions induced by BBR3464.

The cell-specific anti-proliferative effect of reduced glutathione is mediated by γ-glutamyl transpeptidase-dependent extracellular pro-oxidant reactions

We have shown earlier that extracellular GSH can exert a cell‐specific growth‐inhibitory effect on human tumor cells. In the present study, 2 human ovarian carcinoma cell lines (A2780 and IGROV‐1) were used to investigate the biochemical basis of the GSH growth‐inhibitory effect. Whereas cells were resistant, A2780 cells were sensitive to a 1 hr exposure to GSH, as assessed by the growth inhibition assay. Analysis of relevant GSH‐dependent enzymes indicated that A2780 cells had low level of GSH S‐transferase, glutathione reductase and γ‐glytamyl transpeptidase (γ‐GT) activities in comparison with those of IGROV‐1 cells, and GSH peroxidase activity was undetectable in A2780 cells. The GSH effect was reversed by catalase and by dithiothreitol, indicating the occurrence of oxidative phenomena resulting in the impairment of critical cellular thiols. Indeed treatment of cells with H2O2 also resulted in growth inhibition, which was more marked in A2780 cells. The γ‐glutamyl acceptor glycylglycine, a co‐substrate for γ‐GT, potentiated the growth‐inhibitory effect of GSH, which in contrast was decreased by the γ‐GT inhibitors, serine‐borate complex and acivicin, suggesting that the production of reactive forms of oxygen (probably H2O2) was mediated by cysteinyl‐glycine after GSH hydrolysis. The results support that the growth‐inhibitory effect of low GSH concentration is the result of oxidative damage related to extracellular GSH metabolism. Int. J. Cancer 71:246–250, 1997.

Design, Synthesis, and Biological Evaluation of Novel cRGD–Paclitaxel Conjugates for Integrin-Assisted Drug Delivery

The efficacy of taxane-based antitumor therapy is limited by several drawbacks which result in a poor therapeutic index. Thus, the development of approaches that favor selective delivery of taxane drugs (e.g., paclitaxel, PTX) to the disease area represents a truly challenging goal. On the basis of the strategic role of integrins in tumor cell survival and tumor progression, as well as on integrin expression in tumors, novel molecular conjugates were prepared where PTX is covalently attached to either cyclic AbaRGD (Azabicycloalkane-RGD) or AmproRGD (Aminoproline-RGD) integrin-recognizing matrices via structurally diverse connections. Receptor-binding assays indicated satisfactory-to-excellent α(V)β(3) binding capabilities for most conjugates, while in vitro growth inhibition assays on a panel of human tumor cell lines revealed outstanding cell sensitivity values. Among the nine conjugate ensemble, derivative 21, bearing a robust triazole ring connected to ethylene glycol units by an amide function and showing excellent cell sensitivity properties, was selected for in vivo studies in an ovarian carcinoma model xenografted in immunodeficient mice. Remarkable antitumor activity was attained, superior to that of PTX itself, which was associated with a marked induction of aberrant mitoses, consistent with the mechanism of action of spindle poisons. Overall, the novel cRGD-PTX conjugates disclosed here represent promising candidates for further advancement in the domain of targeted antitumor therapy.