Effect of the proteasome inhibitor ALLnL on cisplatin sensitivity in human ovarian tumor cells.

Small molecules suppressing proteasome function inhibit the post-translational ubiquitination of selected proteins. Ubiquitin H2A is an example of an abundant chromatin-associated protein that is known to be ubiquitinated, which is important for several proteins involved in the repair of DNA damage. We therefore studied the effect of the proteasome inhibitor, N-acetyl leucyl-leucyl norlucinal (ALLnL), on cisplatin sensitivity in three human ovarian tumor cell lines. The proteasome inhibitor ALLnL was administered for 4 h before cells were subsequently exposed to cisplatin for 1 h. Our results showed that ALLnL, at its respective IC20 concentration, increased cellular sensitivity to cisplatin in an additive manner in human ovarian cancer A2780, A2780/CP70, and OVCAR3 cells. We also demonstrated that ALLnL caused a 50% increase in total cellular accumulation of cisplatin, and reduced the rate of cisplatin efflux by about 50%. In addition, DNA damage levels were increased after ALLnL treatment. By contrast, DNA repair was inhibited 2 to 3-fold in ALLnL-pretreated cells, as compared to the controls. Furthermore, our study showed that ALLnL deubiquitinated nucleosomal histone H2A in these cells in a concentration-dependent fashion, as assessed by Western blot analysis. These data suggest that sublethal levels of exposure to agents that inhibit proteasome function may alter the subcellular pharmacology of platinum in human ovarian carcinoma cells.

The bacterial polysaccharide tecogalan blocks growth of breast cancer cells in vivo.

The growth of supportive tissue during the progression of solid tumors is an absolute requirement for the nourishment of the tumor. The blockade of this proliferative response of normal tissues to the growing tumor should hence inhibit tumor progression. We have shown earlier, that the heparinoid pentosan polysulfate (PPS) can block tumor growth and neoangiogenesis induced by Kaposi's FGF as well as by other heparin-binding growth factors (HBGFs). We now report on the effects of a bacterial polysaccharide, tecogalan, on tumor xenografts of human breast cancer cells. Tecogalan inhibited FGF-dependent SW-13 cells in vitro very similarly to PPS. Growth factor-independent MDA-MB 231 cells were used in animal studies to assess the in vivo potential of tecogalan. Subcutaneous growth of tumors was inhibited by once weekly i.v. administration of tecogalan. PPS single weekly administration showed a similar effect. No gross side effects were observed. Based on our previous studies with these models, we conclude, that tecogalan acts by blocking HBGFs released from tumor cells. Interestingly, single weekly dosing of either PPS or tecogalan appears to be strikingly more efficacious than spreading the dose over several administrations. These findings with a novel compound, tecogalan, and a novel treatment regimen, PPS, suggests a different approach to planning of therapies with these types of drugs.

Lactacystin enhances cisplatin sensitivity in resistant human ovarian cancer cell lines via inhibition of DNA repair and ERCC-1 expression.

Cisplatin is among the most effective chemotherapeutic agents in the treatment of human ovarian cancer. The cytotoxicity of cisplatin results primarily from its ability to bind covalently to DNA and prevent DNA replication and transcription. The ubiquitin-proteasome pathway plays important roles in a broad array of basic cellular processes. Lactacystin is a selective inhibitor of the proteasome that can inhibit the ubiquitin pathway. However, the effect of lactacystin on DNA repair and the antitumor activity of cisplatin in ovarian cancer have not been evaluated. We report in this work that lactacystin, at concentrations that do not appear harmful, increased cisplatin toxicity in three resistant human ovarian carcinoma cell lines. In addition, lactacystin significantly enhanced DNA platination and decreased DNA repair of cisplatin-DNA adducts in these cell lines, as measured by atomic absorption spectrometry. Furthermore, Northem blot analysis and in vitro nuclear transcript elongation assay demonstrated that lactacystin dramatically reduced the steady-state mRNA expression and the rate of transcription of the DNA repair gene ERCC-1 in these cells. These observations indicate that proteasome inhibition has impact on nucleotide excision repair in several ways: i/ the normal ERCC-1 message upregulation is suppressed; ii/ cisplatin-DNA adduct repair is inhibited, and iii/ DNA platination, as well as cisplatin cytotoxicity, is enhanced.

Prevention of cisplatin-DNA adduct repair and potentiation of cisplatin-induced apoptosis in ovarian carcinoma cells by proteasome inhibitors.

Histones H2A and H2B are known to be reversibly post-translationally modified by ubiquitination. We previously observed in cultured tumor cells that proteasome inhibition stabilizes polyubiquitinated proteins, depletes unconjugated ubiquitin, and thereby promotes the deubiquitination of nucleosomal histones in chromatin. Provocative indirect evidence suggests that histone ubiquitination/deubiquitination cycles alter chromatin structure, which may limit accessibility of DNA repair proteins to damaged sites. In the present study, we focused on the relationship between the ubiquitination status of histone H2A, the structure of chromatin, and the efficiency of nucleotide excision repair (NER) of cisplatin-DNA adducts in human ovarian carcinoma cells exposed to the antitumor drug cisplatin. Pretreating cells with the proteasome inhibitor lactacystin (LC) or N-acetyl-leucyl-leucyl-norleucinal (ALLnL) induced deubiquitination of ubiquitinated histone H2A (uH2A) and concomitantly promoted chromatin condensation, increased the extent of cisplatin-DNA adducts, and diminished NER-dependent repair of cisplatin-DNA lesions, compared with control cells treated with cisplatin alone. Both proteasome inhibitors also prevented the increase in ERCC-1 mRNA expression that occurs in cells exposed to cisplatin. Cells treated with the combination of ALLnL and cisplatin underwent apoptosis, as indicated by caspase-dependent poly(ADP-ribose) polymerase (PARP) cleavage, more quickly than cells treated with either agent alone. Additionally, the combination of ALLnL and cisplatin potently increased p53 levels in cell lysates and stimulated the binding of p53 to chromatin. Together, these observations suggest that proteasome inhibition may be exploited therapeutically for its potential to sensitize ovarian tumor cells to cisplatin.

Association between the level of ERCC-1 expression and the repair of cisplatin-induced DNA damage in human ovarian cancer cells.

Nucleotide excision repair (NER) is responsible for the repair of platinum-DNA lesions. ERCC-1 is a critical gene within the NER pathway, and cells without a functional ERCC-1 do not repair cisplatin-caused DNA damage. The present study was therefore designed to evaluate the relationship between the expression of ERCC-1 and the repair of cisplatin-induced DNA adducts in human ovarian cancer cells in vitro. One hour exposure of MCAS cells to cisplatin yielded an approximately two-fold increment in the levels of ERCC-1 mRNA and ERCC-1 protein, as determined, respectively, by Northern and Western blottings. In addition, nuclear run-on assay showed that ERCC-1 gene transcription rate was increased to about the same extent as steady-state ERCC-1 mRNA and protein, in response to cisplatin treatment. However, the levels of ERCC-1 mRNA, ERCC-1 protein, and ERCC-1 transcript in MCAS cells are two-fold lower than those in A2780/CP70 cells, as previously reported. Furthermore, the repair of cisplatin-DNA adducts in MCAS cells, as measured by atomic absorption spectrometry, is also nearly two-fold less than that in A2780/CP70 cells, indicating a strong association between the level of ERCC-1 expression and the activity of excision repair in these two human ovarian tumor cell lines. These results suggest that ERCC-1 may be a useful marker to monitor the repair of platinum-DNA damage in tumor cells, and further highlight that potential pharmacological approaches which specifically inhibit ERCC-1 expression may increase cellular sensitivity to cisplatin.

Inhibition of breast cancer in nude mouse model by anti-angiogenesis.

The mechanism by which DL-alpha-difluoromethylornithine (DFMO) inhibits angiogenesis is generally thought to involve the inhibition of the rate-limiting enzyme, ornithine decarboxylase (ODC), leading to polyamine depletion in cells and the ultimate cytostatic effect on proliferating endothelial cells. Another mechanism for inhibiting tumor growth involves pentosan polysulfate (PPS) which binds heparin-binding growth factors, known to be crucial for tumor angiogenesis. To quantitate the combined anti-angiogenic effect of DFMO and PPS on tumors, blood vessels were stained using monoclonal antibodies against the platelet endothelial cell adhesion molecule (PECAM). When compared to untreated mice, DFMO/PPS-treated mice exhibited significantly lower (6-fold) blood vessel counts. Furthermore, mice receiving the combination drug treatment had prolonged life compared to untreated tumor-bearing mice, but less than normal tumor-free mice. The prolonged life span of drug treated tumor-bearing mice also correlated with reduced tumor burden in these mice. The use of single drug treatment results in rapid tumor growth and eventual death of tumor-bearing mice. We have demonstrated that there was significant difference in survival time which correlated to less tumor burden in treated groups of mice as compared to the controls. Inhibition of tumor angiogenesis by the drug combinations suggest that these compounds are anti-angiogenic agents for potential use in clinical trial.

Phase I trial of orally administered pentosan polysulfate in patients with advanced cancer.

Tumor angiogenesis is critically important to tumor growth and metastasis. We have shown that pentosan polysulfate (PPS) is an effective inhibitor of heparin-binding growth factors in vitro and can effectively inhibit the establishment and growth of tumors in nude mice. Following completion of our Phase I trial of s.c. administered PPS, we performed a Phase I trial of p.o. administered PPS in patients with advanced cancer to determine the maximum tolerated dose (MTD) and toxicity profile and to search for any evidence for biological activity in vivo. Patients diagnosed with advanced, incurable malignancies who met standard Phase I criteria and who did not have a history of bleeding complications were enrolled, in cohorts of three, to receive PPS p.o. t.i.d., at planned doses of 180, 270, 400, 600, and 800 mg/m2. Patients were monitored at least every 2 weeks with physical exams and weekly with hematological, chemistry, stool hemoccult, and coagulation blood studies, and serum and urine samples for PPS and basic fibroblastic growth factor (bFGF) levels were also taken. The PPS dose was escalated in an attempt to reach the MTD. Eight additional patients were enrolled at the highest dose to further characterize the toxicity profile and biological in vivo effects of PPS. A total of 21 patients were enrolled in the three cohorts of doses 180 (n = 4), 270 (n = 3), and 400 (n = 14) mg/m2. The most severe toxicities seen were grade 3 proctitis and grade 4 diarrhea; however, 20 of the 21 patients had evidence of grade 1 or 2 gastrointestinal (GI) bleeding. These toxicities became evident at a much earlier time point as the dose was increased, but their severities were similar at all dose levels. There were no objective responses, although three patients had prolonged stabilization of previously progressing disease. Pharmacokinetic analysis suggested marked accumulation of PPS upon chronic administration. Serum and urine bFGF levels failed to show a consistent, interpretable pattern; however the data suggested an inverse relationship between PPS and bFGF levels in vivo. A MTD could not be determined using the daily t.i.d. dosing schedule due to the development of grade 3/4 GI toxicity (proctitis) at all dose levels studied. PPS, administered p.o. at doses of 400 mg/m2 t.i.d., did not cause significant systemic toxicity, but most patients developed moderate-to-severe GI toxicity within 1-2 months. The cause of the GI toxicity was unclear, but it was readily reversible upon cessation of the agent. The suggestion of an inverse relationship between PPS and bFGF supports further study of PPS as an antiangiogenic agent. The tested doses and schedule cannot be recommended for further study. Subsequent murine experiments showed PPS to be more effective as an anticancer agent when it is given intermittently. We propose a study of PPS given on a weekly schedule in further clinical trials.

In vivo evaluation of reuterin and its combinations with suramin, melarsoprol, DL-alpha-difluoromethylornithine and bleomycin in mice infected with Trypanosoma brucei brucei.

1. Trypanosoma brucei brucei-infected mouse models treated with a new antibiotic, reuterin, showed reduction of the levels of parasitemia and prolonged survival of the mice. 2. Cures of the parasitemia were observed in groups of mice treated with combinations of reuterin and suramin or melarsoprol. 3. Reuterin administered in combination with bleomycin or DL-alpha-difluoromethylornithine showed temporary remission of the parasitemia in groups of mice.

The in vitro efficacy of reuterin on the culture and bloodstream forms of Trypanosoma brucei brucei.

1. The in vitro effects of a new antibiotic, reuterin, were determined for culture and bloodstream forms of Trypanosoma brucei brucei. It inhibited growth of the culture forms and motility, viability and DNA and protein syntheses of culture and bloodstream forms. 2. Reuterin administered with inhibitors of ribonucleotide reductase (hydroxyurea and deoxyadenosine) was synergistic only for growth of the culture form of the parasite. 3. Reuterin was trypanocidal at lower doses than DFMO, Mel B, and Suramin and was antagonistic when used with these drugs.