Defining the cutoff value of MGMT gene promoter methylation and its predictive capacity in glioblastoma.

Despite advances in the treatment of glioblastoma (GBM), median survival is 12-15 months. O6-methylguanine-DNA methyltransferase (MGMT) gene promoter methylation status is acknowledged as a predictive marker for temozolomide (TMZ) treatment. When MGMT promoter values fall into a "methylated" range, a better response to chemotherapy is expected. However, a cutoff that discriminates between "methylated" and "unmethylated" status has yet to be defined. We aimed to identify the best cutoff value and to find out whether variability in methylation profiles influences the predictive capacity of MGMT promoter methylation. Data from 105 GBM patients treated between 2008 and 2013 were analyzed. MGMT promoter methylation status was determined by analyzing 10 CpG islands by pyrosequencing. Patients were treated with radiotherapy followed by TMZ. MGMT promoter methylation status was classified into unmethylated 0-9 %, methylated 10-29 % and methylated 30-100 %. Statistical analysis showed that an assumed methylation cutoff of 9 % led to an overestimation of responders. All patients in the 10-29 % methylation group relapsed before the 18-month evaluation. Patients with a methylation status ≥30 % showed a median overall survival of 25.2 months compared to 15.2 months in all other patients, confirming this value as the best methylation cutoff. Despite wide variability among individual profiles, single CpG island analysis did not reveal any correlation between single CpG island methylation values and relapse or death. Specific CpG island methylation status did not influence the predictive value of MGMT. The predictive role of MGMT promoter methylation was maintained only with a cutoff value ≥30 %.

Organosulfur derivatives of the HDAC inhibitor valproic acid sensitize human lung cancer cell lines to apoptosis and to cisplatin cytotoxicity.

Lung cancer is the leading cause of cancer mortality worldwide and despite efforts made to improve clinical results, continuing poor survival rates indicate that novel therapeutic approaches are needed. Valproic acid (VPA), a short-chain branched fatty acid used mainly for the treatment of epilepsy and bipolar disorder, has been shown to inhibit class I histone deacetylases (HDAC-I), a group of enzymes involved in chromatin remodeling and which are thought to play a role in tumor development. Although evidence of VPA's therapeutic efficacy has also been observed in patients with solid tumors, the very high concentration required to induce antitumor activity limits its clinical usefulness. We used a panel of NSCLC cell lines to evaluate the activity and mechanisms of action of organosulfur valproic acid derivatives, a promising new class of compounds designed to improve the safety and efficacy of the valproic acid molecule and created by coupling it with a hydrogen sulfide (H(2) S)-releasing moiety. Our results highlighted the increased cytotoxic activity of the novel organosulfur derivatives, ACS33 and ACS2, with respect to VPA, starting from low concentrations. In particular, ACS2 exhibited important pro-apoptotic activity triggered by the mitochondrial pathway and also showed anti-invasion potential. Furthermore, our in vitro results identified a highly effective combination schedule of ACS2 and cisplatin capable of inducing a synergistic interaction even when the two drugs were used at low concentrations, which could prove a valid alternative to traditional chemotherapeutic regimens used for advanced lung cancer. Further studies are needed to confirm these preliminary findings.

Low-dose taxotere enhances the ability of sorafenib to induce apoptosis in gastric cancer models.

Despite the low efficacy of conventional antitumour drugs, chemotherapy remains an essential tool in controlling advanced gastric and oesophageal cancers. We aimed to provide a biological rationale based on the sorafenib-taxotere interaction for the clinical treatment of gastric cancer. In vitro experiments were performed on four human gastric cancer cell lines (GK2, AKG, KKP and NCI-N87). Cytotoxicity was evaluated by sulforhodamine B (SRB) assay, cell cycle perturbations, apoptosis and mitotic catastrophe were assessed by flow cytometric and microscopic analyses, and protein expression was studied by Western blot. In the in vivo experiments, nude mice xenografted with the most resistant line were treated with sorafenib and docetaxel singly or in association. Sorafenib inhibited cell growth (IG(50) values ranged from 3.4 to 8.1 µM) and caused down-regulation of MAP-K/ERK phosphorylation and of mcl-1 and p-bad expression after a 48-hr exposure. Apoptosis induction was associated with caspase-3 and -9 activation and mitochondrial membrane depolarization. The drug combination enhanced apoptosis (up to 80%) and produced a synergistic interaction when low doses of the taxane preceded administration of the antityrosine kinase. This synergism was probably due to the induction of an anomalous multidiploid G0-G1 peak and to consequent mitotic catastrophe, which increased sensitivity to sorafenib. Consistent with in vitro results, the docetaxel-sorafenib sequence exhibited high therapeutic efficacy in NCI-N87 mouse xenografts producing tumour weight inhibition (> 65%), tumour growth delay (up to 25 days) and increased mouse survival (30%). Our findings suggest the potential clinical usefulness of treatment with sorafenib and docetaxel for advanced gastric cancer.

Activity of different anthracycline formulations in hormone-refractory prostate cancer cell lines: role of Golgi apparatus.

The efficacy of therapy for hormone-refractory prostate cancer (HRPC) is still unsatisfactory and new agents and therapeutic modalities are needed. The aims of the present work were to examine the in vitro activity and mechanisms of action of doxorubicin (DX), pegylated liposomal DX (PLDX), and non-pegylated liposomal DX (NPLDX) in DU145 and taxane-resistant DU145-R HRPC cell lines. Drug activity and incorporation, apoptosis, and expression of cell death-related markers were evaluated by SRB test, cytofluorimetric assays, and Western blot, respectively. Among the different DX formulations, NPLDX showed the highest cytotoxic activity in both cell lines, with more than 50% of apoptotic cells at only 1/10 of the plasma peak concentration after 72 h exposure. Anthracyclines, in particular NPLDX, were highly concentrated in the Golgi apparatus. Moreover, a significant increase was observed in the expression of CD95 receptor, GD3 ganglioside and, caspase-2 and -8 active forms in both cell lines followed by caspase-3 activation and mitochondrial membrane depolarization. The Golgi apparatus, probably acting as a stress sensor, intensified the conventional apoptotic mechanism induced by anthracyclines. Our data support the hypothesis that organelle-dependent initiation of cell death other than that induced by mitochondria and nucleus is a research area worthy of pursuing and suggest that the Golgi apparatus could be an ideal target for anti-cancer therapy. Of note, the activity of NLPDX in taxane-resistant DU145-R cells warrants further evaluation as second-line treatment of advanced HRPC after taxane failure.

Docetaxel-ST1481 sequence exerts a potent cytotoxic activity on hormone-resistant prostate cancer cells by reducing drug resistance-related gene expression.

BACKGROUND: The efficacy of current therapy for hormone-refractory prostate cancer is still unsatisfactory and new agents and therapeutic modalities are needed. The aims of the present work were to examine the in vitro activity and mechanisms of action of different antitumor drug combinations in hormone-resistant prostate cancer (HRPC) cell lines. METHODS: The activity of docetaxel (Doc), cisplatin (Cis), oxaliplatin (Oxa), SN-38 and ST1481, singly or in combination, was assessed in different HRPC cell lines (PC3, parental DU145 and taxane-resistant DU145-R) by SRB test. Apoptosis was evaluated by TUNEL and ANN-V assays. Extrusion pump activity was studied by Hoechst 33342 assay, while gene expression related to drug efflux mechanisms and DNA damage repair was analyzed by RT-PCR. RESULTS: Doc induced a high cytocidal effect in the HRPC cells, whereas Cis, Oxa, SN-38 and ST1481 exerted prevalently cytostatic activity. Doc followed by ST1481 proved to be the most effective drug sequence among those investigated, producing an important synergistic effect (R.I. from 2.0 to 5.2) in all the tested cell lines. Moreover, this sequence induced a significant downregulation of xenobiotic extrusion pump and DNA damage repair gene expression. ST1481 synergistically increased the cytocidal effect of Doc, probably through a downregulation of extrusion pump activity and DNA damage repair-related genes. CONCLUSIONS: Our results show that the Doc --> ST1481 sequence effectively reduces the cancer cell population and restores Doc activity in taxane-resistant HRPC, indicating its potential usefulness as first- or second-line treatment of hormone-refractory prostate cancer.

Influence of Intratumor Heterogeneity on the Predictivity of MGMT Gene Promoter Methylation Status in Glioblastoma.

Glioblastoma is the most aggressive tumor of the central nervous system. Prognosis is poor, even in the presence of a methylated state of MGMT gene promoter, which represents the biomarker with the highest prognostic/predictive value for the standard treatment of patients. Among patients with a methylated MGMT status, we identified an intermediate range of methylation above the standard 9% cut-off (gray zone) in which the predictive strength of the marker was lost. In an effort to improve the evaluation of the biomarker in clinical decision-making, we are carrying out a retrospective study, performing an in-depth analysis of samples used for diagnosis to understand how molecular heterogeneity, a hallmark of glioblastoma, impacts the evaluation of MGMT gene promoter methylation. Preliminary data from samples belonging to the "gray zone" tend to confirm the hypothesis of a mismatch between methylation values used for clinical decision-making and those included in our in-depth analysis. Confirmation of these data would help to better define the predictive power of MGMT promoter methylation status and greatly facilitate clinical decision-making.

Role of efflux pump activity in lapatinib/caelyx combination in breast cancer cell lines.

The aim of this study was to investigate, at preclinical level, efflux pump modulation induced by lapatinib, a small-molecule dual inhibitor of the epidermal growth factor receptor (EGFR), in HER2-negative or HER2-positive breast cancer cell lines (SkBr3 and BRC230). We also evaluated the cytotoxic activity and modulation of biomolecular cellular pathways regulated by caelyx and lapatinib, used singly or in combination, at concentrations corresponding to peak plasma level in the two cell lines. Lapatinib was active in the HER2-overexpressing cell line, SkBr3, but not in BRC230 cell line, which does not express HER2. Conversely, caelyx exerted a cytotoxic effect on both the cell lines. Simultaneous exposure to lapatinib and caelyx in SkBr3 cell line produced an additive cytotoxic effect with dephosphorylation of HER2 and EGFR, an upregulation of p21, and an induction of apoptosis through dephosphorylation of BAD and caspase cleavage. In BRC230, simultaneous treatment induced a synergistic effect that was because of, at least in part, an upregulation of p21. Lapatinib also blocked efflux pumps, such as the breast cancer resistance protein I by increasing the length of time in which caelyx was present in tumor cell cytoplasm, which led to caspase cleavage, BAD dephosphorylation, and apoptosis. Our data indicate that lapatinib used in combination with caelyx is active in HER2-expressing cells, probably because of lapatinib-induced dephosphorylation of the HER2-EGFR pathway, and also in non-HER2-expressing cells, possibly because lapatinib blocks efflux pump activity, increasing the length of time of intracellular exposure to caelyx and thereby increasing its cytotoxic effect.

Mitotic catastrophe and apoptosis induced by docetaxel in hormone-refractory prostate cancer cells.

Studies performed in different experimental and clinical settings have shown that Docetaxel (Doc) is effective in a wide range of tumors and that it exerts its activity through multiple mechanisms of action. However, the sequence of events induced by Doc which leads to cell death is still not fully understood. Moreover, it is not completely clear how Doc induces mitotic catastrophe and whether this process is an end event or followed by apoptosis or necrosis. We investigated the mechanisms by which Doc triggers cell death in hormone-refractory prostate cancer cells by analyzing cell cycle perturbations, apoptosis-related marker expression, and morphologic cell alterations. Doc induced a transient increase in G2/M phase followed by the appearance of G0/1 hypo- and hyperdiploid cells and increased p21 expression. Time- and concentration-dependent apoptosis was induced in up to 70% of cells, in concomitance with Bcl-2 phosphorylation, which was followed by caspase-2 and -3 activation. In conclusion, Doc would seem to trigger apoptosis in hormone-refractory prostate cancer cells via mitotic catastrophe through two forms of mitotic exit, in concomitance with increased p21 expression and caspase-2 activation.

Zoledronic acid increases docetaxel cytotoxicity through pMEK and Mcl-1 inhibition in a hormone-sensitive prostate carcinoma cell line.

BACKGROUND: In prostate cancer, the identification of drug combinations that could reduce the tumor cell population and rapidly eradicate hormone-resistant cells potentially present would be a remarkable breakthrough in the treatment of this disease. METHODS: The study was performed on a hormone-sensitive prostate cancer cell line (LNCaP) grown in normal or hormone-deprived charcoal-stripped (c.s.) medium. Cell viability and apoptosis were assessed by SRB assay and Annexin-V/TUNEL assays, respectively. Activated caspase-3, p21, pMEK and MCL-1 expression levels were detected by western blotting. RESULTS: The simultaneous exposure of zoledronic acid [100 microM] and docetaxel [0.01 microM] for 1 h followed by treatment with zoledronic acid for 72, 96 or 120 h produced a high synergistic interaction (R index = 5.1) with a strong decrease in cell viability. This cytotoxic effect was associated with a high induction of apoptosis in both LNCaP and in c.s. LNCaP cells. The induction of apoptosis was paralleled by a decrease in pMEK and Mcl-1 expression. CONCLUSION: The zoledronic acid-docetaxel combination produced a highly significant synergistic effect on the LNCaP cell line grown in normal or hormone-deprived medium, the principal molecular mechanisms involved being apoptosis and decreased pMEK and Mcl-1 expression. This experimentally derived schedule would seem to prevent the selection and amplification of hormone-resistant cell clones and could thus be potentially used alongside standard androgen deprivation therapy in the management of hormone-sensitive prostate carcinoma.

Short interfering RNA directed against the SLUG gene increases cell death induction in human melanoma cell lines exposed to cisplatin and fotemustine.

BACKGROUND: Melanoma remains largely resistant to currently available chemotherapy, and new strategies have been proposed to flank standardized therapeutic protocols in an effort to improve efficacy. Such an approach requires good knowledge of the mechanisms involved in the resistance and survival of melanoma cells. In this context, the SLUG gene has recently been characterized as a major regulator of melanocytes and melanoma cell survival. METHODS: We tested the hypothesis that an oligonucleotide-based short interfering RNA (siRNA) directed against the SLUG gene increases the susceptibility of melanoma cells to drugs such as cisplatin and fotemustine, which are frequently used to treat this cancer. RESULTS: It was found that SLUG siRNA increased cisplatin-induced cell death and rendered the drug active in vitro at half its plasmatic peak concentration. Such activity was correlated with an upregulation of the pro-apoptotic gene, PUMA. Furthermore, SLUG siRNA increased the capacity of fotemustine to elicit cell death and induced p21WAF1 upregulation, resulting in cell cycle arrest. Interestingly, this pathway did not require functional p53. CONCLUSION: These findings suggest that SLUG siRNA enhances the efficacy of two of the most widely used drugs to treat melanoma.

Sequential events of apoptosis involving docetaxel, a microtubule-interfering agent: a cytometric study.

BACKGROUND: Despite the great advances in the understanding of programmed cell death, little attention has been paid to the sequence of the events that characterise it. In particular, the course of apoptotic events induced by microtubule-interfering agents such as taxanes is poorly understood. In order to increase such knowledge, we studied a number of independent biochemical and cytological modifications using cytometric methods in a bladder cancer cell line treated with the second generation taxane, docetaxel. RESULTS: Within a few hours, drug treatment had induced mitochondrial membrane transition, cell shrinkage and a decrease in granularity. Cell cycle was almost completely blocked in G2/M phase within 24 hours. The hypodiploid peak started to become prominent 48 hours after the treatment. At the same time, the appearance of a DNA ladder demonstrated caspase-dependent chromatin fragmentation. Concurrently, specific cell surface modifications took place, involving at first glycoprotein syalilation and later phospholipid asymmetry. DNA fragmentation was subsequently detected by TUNEL assay. Over time, cell membranes became permeable to propidium iodide. A very similar time-course of apoptotic events was found after treatment of a myelomonocytic cell line with the same drug. CONCLUSION: After discussing some characteristics of the methods employed and their limitations, a succession of apoptotic events over time is suggested, in which the collapse of mitochondrial transmembrane potential (Deltapsim) is the earliest sign of apoptosis.

Cellular basis of antiproliferative and antitumor activity of the novel camptothecin derivative, gimatecan, in bladder carcinoma models.

To investigate the cellular/molecular basis of the activity of a novel lipophilic camptothecin, gimatecan (ST1481), against slowly proliferating cells, we performed a comparative study of topotecan and gimatecan in human bladder cancer models (HT1376 and MCR). Gimatecan was significantly more effective than topotecan in inhibiting the growth of HT1376 tumor, thus reflecting antiproliferative potency. In both HT1376 and MCR cells, gimatecan caused a persistent S-phase arrest, indicating an efficient DNA damage checkpoint. This response was consistent with a cytostatic effect, because no evidence of apoptosis was detected. In contrast to gimatecan, topotecan at equitoxic concentrations caused an early and persistent downregulation of topoisomerase I. Modulation of protein level could not be solely ascribed to the proteasome-mediated degradation of the enzyme because the proteasome inhibitor PS341 sensitized MCR but not HT1376 cells to camptothecins, suggesting alternative mechanisms of drug-induced topoisomerase I downregulation. Indeed, the two camptothecins caused a differential inhibition of topoisomerase I transcription, which is more marked in topotecan-treated cells. The HT1376 model was more sensitive to this immediate decrease of mRNA level. Our data document a marked antitumor activity of gimatecan against a bladder carcinoma model. A limited downregulation of topoisomerase I by gimatecan provides additional insights into the cellular basis of drug potency.

Addition of 5-fluorouracil to doxorubicin-paclitaxel sequence increases caspase-dependent apoptosis in breast cancer cell lines.

INTRODUCTION: The aim of the study was to evaluate the activity of a combination of doxorubicin (Dox), paclitaxel (Pacl) and 5-fluorouracil (5-FU), to define the most effective schedule, and to investigate the mechanisms of action in human breast cancer cells. METHODS: The study was performed on MCF-7 and BRC-230 cell lines. The cytotoxic activity was evaluated by sulphorhodamine B assay and the type of drug interaction was assessed by the median effect principle. Cell cycle perturbation and apoptosis were evaluated by flow cytometry, and apoptosis-related marker (p53, bcl-2, bax, p21), caspase and thymidylate synthase (TS) expression were assessed by western blot. RESULTS: 5-FU, used as a single agent, exerted a low cytotoxic activity in both cell lines. The Dox-->Pacl sequence produced a synergistic cytocidal effect and enhanced the efficacy of subsequent exposure to 5-FU in both cell lines. Specifically, the Dox-->Pacl sequence blocked cells in the G2-M phase, and the addition of 5-FU forced the cells to progress through the cell cycle or killed them. Furthermore, Dox-->Pacl pretreatment produced a significant reduction in basal TS expression in both cell lines, probably favoring the increase in 5-FU activity. The sequence Dox-->Pacl-->48-h washout-->5-FU produced a synergistic and highly schedule-dependent interaction (combination index < 1), resulting in an induction of apoptosis in both experimental models regardless of hormonal, p53, bcl-2 or bax status. Apoptosis in MCF-7 cells was induced through caspase-9 activation and anti-apoptosis-inducing factor hyperexpression. In the BRC-230 cell line, the apoptotic process was triggered only by a caspase-dependent mechanism. In particular, at the end of the three-drug treatment, caspase-8 activation triggered downstream executioner caspase-3 and, to a lesser degree, caspase-7. CONCLUSION: In our experimental models, characterized by different biomolecular profiles representing the different biology of human breast cancers, the schedule Dox-->Pacl-->48-h washout-->5-FU was highly active and schedule-dependent and has recently been used to plan a phase I/II clinical protocol.

Nonsteroidal androgen receptor ligands: versatile syntheses and biological data.

We report herein a stereoselective and straightforward methodology for the synthesis of new androgen receptor ligands with (anti)-agonistic activities. Oxygen-nitrogen replacement in bicalutamide-like structures paves the way to the disclosure of a new class of analogues, including cyclized/nitrogen-substituted derivatives, with promising antiandrogen (or anabolic) activity.

Tyrosine kinase inhibitors gefitinib, lapatinib and sorafenib induce rapid functional alterations in breast cancer cells.

Alterations in tyrosine kinase expression or functionality have been linked to tumor growth, and detailed analysis of tyrosine kinase pathways has led to the development of novel anticancer drugs based on their inhibition. The aim of the present work was to examine the cytotoxicity and cellular alterations correlated with multidrug resistance mechanisms induced by three tyrosine kinase inhibitors, lapatinib, sorafenib and gefitinib. The study was performed on three breast cancer cell lines (BRC-230, MCF-7 and SkBr3). Drug-induced growth inhibition was detected by Sulforhodamine B analysis. Apoptosis, cytosolic calcium alteration, extrusion pump activity and mitochondrial membrane depolarization were assessed by flow cytometry. Drug efflux-related gene expression was analyzed by RT-PCR and drug target protein expression was evaluated by Western Blot. Lapatinib and gefitinib induced a cytotoxic effect and mitochondrial membrane depolarization in BRC-230 and SkBr3 cells, while sorafenib induced apoptosis and a high and rapid dissipation of mitochondrial potential in all cell lines. Moreover, all three drugs produced a rapid cytosolic calcium mobilization from endoplasmic reticulum stores in the investigated cell lines and a strong decrease in multidrug transporter activity in BRC-230 and MCF-7 cells. Mitochondrial membrane depolarization and inhibition of multidrug transporter activity induced by tyrosine kinase inhibitors were independent of cytosolic calcium mobilization. These data suggest that the investigated drugs possess mechanisms of action that are independent of drug target expression, opening up further possibilities for the development of new therapeutic strategies.

Iressa strengthens the cytotoxic effect of docetaxel in NSCLC models that harbor specific molecular characteristics.

Non-small cell lung cancer (NSCLC) is the most lethal malignant tumor and is also considered one of the most chemoresistant cancers. Despite the benefits obtained from platinum-based therapy, the majority of patients treated will progress and die. In the continuing quest for personalized therapy based on the biomolecular characteristics of each single patient, clinical practice now seems to be oriented towards combining conventional drugs with molecular-targeted agents. In the present study, we evaluated the antitumor activity of docetaxel, one of the most widely used drugs for second-line treatment, and Iressa, an EGFR-targeting tyrosine kinase inhibitor, administered singly or in sequence. The study was performed on three human NSCLC cell lines (ChaGo-K1, CAEP and RAL) that exhibit different expression of proliferation and apoptosis-related markers, and do not harbor EGFR mutations. The efficacy of docetaxel and Iressa differed in the three cell lines and an important synergistic interaction was observed with the sequence 1-h docetaxel --> 72-h Iressa during which Iressa doubled the fraction of docetaxel-induced apoptotic cells, amplifying a caspase-dependent apoptosis and inhibiting docetaxel-induced p21 hyperexpression. Moreover, the important role of MAPK-dependent modulation of this molecular marker was shown using a specific inhibitor. The results from the present preclinical study demonstrate the cytotoxic activity of Iressa and its ability to increase taxane activity in a model that does not harbor EGFR-specific mutations, thus highlighting the importance of focusing on alternative molecular targets of Iressa activity.

Molecular characterization of cytotoxic and resistance mechanisms induced by NCX 4040, a novel NO-NSAID, in pancreatic cancer cell lines.

Although non steroidal antiinflammatory drugs (NSAIDs) have been shown to be effective as chemopreventive agents, important side-effects limit their clinical use. A promising novel class of drugs, nitric oxide-donating NSAIDs (NO-NSAIDs), has been found to be more active than classical NSAIDs. This study explored the effect of the NO-donating aspirin derivative, NCX 4040, on three human pancreatic adenocarcinoma cell lines (Capan-2, MIA PaCa-2 and T3M4). NCX 4040 activity was compared with that of NCX 4016 (an NO(2)-positional isomer of NCX 4040), SNAP (a standard NO-releasing molecule), NCX 4042 (denitrated analog of NCX 4040), and aspirin. NCX 4040 showed a striking cytocidal activity in all cell lines, already inducing significant percentages of apoptotic cells at 10 muM in Capan-2 cell lines. This study focused on the biological mechanisms of sensitivity and resistance to NCX 4040, highlighting that the cytotoxic action of this drug may be due to the hyperexpression of Bax, its translocation to the mitochondria, the release of Cytochrome C, and the activation of caspases-9 and -3, overall in a p53-independent manner. Moreover, the use of a specific COX-2 inhibitor (NS 398) in the experimental models showed that COX-2 hyperexpression could partially explain the resistance mechanisms to NCX 4040.