Experimental study of combination therapy with S-1 against pancreatic cancer.

PURPOSE: To determine the most effective combination chemotherapy with S-1 against pancreatic cancer and to clarify the mechanism of synergy between S-1 and the partner drug. METHODS: We tested a combination of S-1 with the following antitumor drugs in an in vitro MTT assay against pancreatic cancer cell line MIA PaCa-2: gemcitabine (GEM), cisplatin (CDDP), irinotecan (CPT-11), mitomycin C, adriamycin, and paclitaxel. The efficacy of S-1, GEM, and a combination of S-1 and GEM was also tested in vivo by administering S-1 (10 mg/kg) orally to nude mice five times a week for 3 weeks, and GEM (100 mg/kg) intravenously every 2-3 days for a total of six times. A treated-to-control ratio (T/C) of relative mean tumor weight values less than 50% was determined to be effective. Furthermore, we investigated the mechanism of the synergistic effect of S-1 and GEM on the cell cycle by flow cytometry, because both S-1 and GEM are known as antimetabolic drugs. To verify cell death induced by a change in the distribution of the cell cycle phases, we investigated apoptosis by sub-G1 analysis and a TUNEL assay. RESULTS: From classical isobolography analysis of the in vitro MTT assay, the combination of S-1 plus GEM was found to be the most effective of the combinations tested. In vivo, T/C (percentage) with the combination of S-1 plus GEM was 48.2%, which was lower than that of S-1 or GEM alone, and the combination enhanced antitumor activity. Cell cycle analysis showed greater cell cycle delay with the combination treatment (S-1 plus GEM) than for each single drug treatment, and apoptotic cells were detected only in treatments including GEM. CONCLUSION: The combination chemotherapy of S-1 and GEM appears to be useful for pancreatic cancer. Both cycle delay by S-1 plus GEM and apoptosis induced by GEM are involved in this synergistic mechanism.

Jerantinines A-G, cytotoxic Aspidosperma alkaloids from Tabernaemontana corymbosa.

Seven new indole alkaloids of the Aspidosperma type, jerantinines A-G (1-7), were isolated from a leaf extract of the Malayan Tabernaemontana corymbosa. The structures were established using NMR and MS analysis. Five of the alkaloids isolated and two derivatives (1-5, 8, 9) displayed pronounced in vitro cytotoxicity against human KB cells (IC50 < 1 microg/mL).

Biologically active aspidofractinine alkaloids from Kopsia singapurensis.

Ten new indole alkaloids of the aspidofractinine type, in addition to several recently reported indole alkaloids and 20 other known alkaloids, were obtained from the leaf and stem-bark extract of the Malayan Kopsia singapurensis, viz., kopsimalines A-E (1-5), kopsinicine (6), kopsofinone (7), and kopsiloscines H-J (8-10). The structures of these alkaloids were determined using NMR and MS analysis. Kopsimalines A (1), B (2), C (3), D (4), and E (5) and kopsiloscine J (10) were found to reverse multidrug-resistance in vincristine-resistant KB cells, with 1 showing the highest potency.

Biologically active aspidofractinine, rhazinilam, akuammiline, and vincorine alkaloids from Kopsia.

Eleven new indole alkaloids, in addition to the previously reported rhazinal (1), and 14 other known alkaloids, were obtained from the Malayan Kopsia singapurensis, viz., kopsiloscines A-F (2-7), 16-epikopsinine (8), kopsilongine- N-oxide (9), 16-epiakuammiline (10), aspidophylline A (11), and vincophylline (12). The structures of these alkaloids were determined using NMR and MS analyses. Rhazinal (1), rhazinilam (17), and rhazinicine (18) showed appreciable cytotoxicity toward drug-sensitive as well as vincristine-resistant KB cells, while kopsiloscines A (2), B (3), and D (5) and aspidophylline A (11) were found to reverse drug-resistance in drug-resistant KB cells.

Biologically active indole alkaloids from Kopsia arborea.

Nine new indole alkaloids, rhazinoline (1), 19(S)-methoxytubotaiwine (2), 19(R)-methoxytubotaiwine (3), kopsamidine A (4), kopsamidine B (5), kopsinidine A (6), kopsinidine B (7), paucidactine C (8), and pericine N-oxide (9), in addition to several recently reported novel indoles and 34 other known ones, were obtained from the stem-bark extract of the Malayan Kopsia arborea. The structures were determined using NMR and MS analysis. Valparicine (12) showed pronounced cytotoxic effects against KB and Jurkat cells (IC(50) 13.0 and 0.91 microM, respectively).

Leuconoxine, kopsinitarine, kopsijasmine, and kopsinone derivatives from Kopsia.

Four new indole alkaloids were obtained from two Kopsia species, 6-oxoleuconoxine (1) from the leaf extract of K. griffithii and kopsinitarine E (2), kopsijasminine (3), and kopsonoline (4) from the stem-bark extract of K. teoi. The structures of these alkaloids were determined using NMR and MS analysis. Kopsijasminine (3) showed moderate activity in reversing multidrug resistance in vincristine-resistant KB cells.

[Experimental chemotherapy against human esophageal carcinoma xenografts with TS-1, cisplatin and docetaxel].

Three strains of human esophageal carcinoma xenografts established in our institution were tested against combination chemotherapy in vivo and in vitro. TS-1 plus cisplatin (CDDP) was shown to be an effective combination against two carcinoma strains of moderately-differentiated type. Determination of the thymidylate synthase (TS) demonstrated a higher inhibition of the enzyme by adding CDDP to 5-FU, suggesting biochemical modulation. The remaining strain of poorly-differentiated type was resistant to the combination and an attempt was made to add docetaxel (DTX) to show that the three-drug combination was effective against the strain. Combination chemotherapy including TS-1 and CDDP thus appears to be useful treatment choice for esophageal carcinoma.

Suppression of cancer cachexia by 20S,21-epoxy-resibufogenin-3-acetate-a novel nonpeptide IL-6 receptor antagonist.

While screening for novel IL-6 inhibitors, we synthesized 20S,21-epoxy-resibufogenin-3-acetate (ERBA). ERBA dose-dependently suppressed IL-6-induced cell growth with an IC(50) value of 5.3 microM and caused a parallel rightward shift of dose-response curves to IL-6. Analysis of data yields a pA2 of 5.83 and a slope of 0.99. ERBA did not affect IL-2-, IL-3-, and GCSF-dependent cell growth, or tumor necrosis factor alpha-induced growth suppression, nor did ERBA affect osteoclast formation induced by IL-11, leukemia inhibitory factor, and 1alpha,25-dihydroxyvitamin D(3). Receptor assay showed that ERBA dose-dependently suppressed IL-6 binding to IL-6 receptor (IL-6R). Furthermore, no band existing at the position of IL-6R in Western blots of ERBA-treated cells when stimulated with IL-6:ERBA suppresses IL-6 activity by blocking the binding of IL-6 to IL-6R. In an experimental model of colon 26-induced cancer cachexia, ERBA markedly inhibited body weight loss. ERBA is a specific small molecule with IL-6R-antagonist activity.