The synthetic phosphagen cyclocreatine phosphate inhibits the growth of a broad spectrum of solid tumors.

BACKGROUND: The brain isoform of creatine kinase (CKBB), an enzyme involved in energy metabolism, has been implicated in cellular transformation process. Cyclocreatine (CCr), a creatine kinase (CK) substrate analogue, was shown to inhibit the growth of a broad spectrum of solid tumors expressing high levels of CK. Cyclocreatine phosphate (CCrP) generated by CK, was proposed to be the active form responsible for growth inhibition. MATERIALS AND METHODS: We synthesized CCrP and tested its cellular uptake and anti tumor activity in stem cell assays and in athymic mouse models. RESULTS: CCrP seems to be taken up by cells and inhibits the growth of solid tumors with high levels of CK. CCr and CCrP have similar specificity and potency. CONCLUSION: The observation that only high-CK cell lines were responsive to CCrP, similar to CCr, indicates that the enzyme requirement was not bypassed. We propose that CK is a target for CCrP, and is involved in mediating its antiproliferative activity.

Creatine and phosphocreatine analogs: anticancer activity and enzymatic analysis.

The brain isoform of creatine kinase has been implicated in cellular transformation processes. Cyclocreatine, a creatine kinase substrate analog, was previously shown to be cytotoxic to a broad spectrum of solid tumors. We have synthesized, enzymatically characterized, and evaluated the antitumor activity of a series of substrate analogs of creatine kinase. Using in vitro assays, we demonstrate that several of these analogs are cytotoxic to the human ME-180 cervical carcinoma, the MCF-7 breast adenocarcinoma and the HT-29 colon adenocarcinoma cell lines at low mM concentrations. Analogs that were active in vitro delayed the growth of a subcutaneously implanted rat 13,762 mammary adenocarcinoma. Tumor growth delays of 6-8 days were achieved, which is comparable to effects seen with standard regimens of currently used anticancer drugs. These studies further establish the creatine kinase system as a promising and novel target for anticancer chemotherapy drug design.

Specific targeting of tumor cells by the creatine analog cyclocreatine.

Creatine kinase (CK) an enzyme involved in cellular ATP homeostasis has been implicated in tumorigenesis. Cyclocreatine (CCr) a CK substrate analog was shown to be cytotoxic to a broad spectrum of solid tumors. We have measured and compared the CK activity and CCr sensitivity of 49 transformed and non-transformed cell lines. Among tumor cell lines, there was a strong correlation between the two (p = 0.0026, regression analysis); cell lines expressing high levels of CK (>0.10 Units/mg protein) were generally sensitive to the drug and cell lines with low CK were resistant. Tumor cell lines highest in CK and most sensitive to CCr were derived from prostate, small cell lung and neuronal tissue. The hematopoetic tumor lines tested were generally low in CK and all were resistant to CCr. Fourteen non-transformed cell lines were examined and all were resistant to the compound, including six with high levels of CK. Thus, CCr preferentially targeted tumor cells. Further, CCr inhibited tumor cell proliferation more efficiently than macromolecular synthesis indicating that, rather than exerting a general effect on energy metabolism, CCr may act on a specific pathway involved in controlling tumor cell proliferation.

beta-cyclodextrin tetradecasulfate/tetrahydrocortisol +/- minocycline as modulators of cancer therapies in vitro and in vivo against primary and metastatic Lewis lung carcinoma.

Tetrahydrocortisol, beta-cyclodextrin tetradecasulfate, and minocycline used alone or in combination are not very cytotoxic toward EMT-6 mouse mammary tumor cells growing in monolayer. Tetrahydrocortisol (100 microM, 24 h) and beta-cyclodextrin tetradecasulfate (100 microM, 24 h) protected EMT-6 cells from the cytotoxicity of CDDP, melphalan, 4-hydroperoxycyclophosphamide, BCNU, and X-rays under various conditions of oxygenation and pH. Minocycline (100 microM, 24 h) either had no effect upon or was additive with the antitumor alkylating agents or X-rays in cytotoxic activity toward the EMT-6 cells in culture. The combination of the three modulators either had no effect upon or was to a small degree protective against the cytotoxicity of the antitumor alkylating agents or X-rays. The Lewis lung carcinoma was chosen for primary tumor growth-delay studies and tumor lung-metastases studied. Tetrahydrocortisol and beta-cyclodextrin tetradecasulfate were given in a 1:1 molar ratio by continuous infusion over 14 days, and minocycline was given i.p. over 14 days, from day 4 to day 18 post tumor implantation. The combination of tetrahydrocortisol/beta-cyclodextrin tetradecasulfate diminished the tumor growth delay induced by CDDP and melphalan and produced modest increases in the tumor growth delay produced by cyclophosphamide and radiation. Minocycline co-treatment increased the tumor growth delay produced by CDDP, melphalan, radiation, bleomycin, and, especially cyclophosphamide, where 4 of 12 animals receiving minocycline (14 x 5 mg/kg, days 4-18) and cyclophosphamide (3 x 150 mg/kg, days 7, 9, 11) were long-term survivors. The 3 modulators given in combination produced further increases in tumor growth delay with all of the cytotoxic therapies, and 5 of 12 of the animals treated with the 3-modulator combination and cyclophosphamide were long-term survivors. Although neither tetrahydrocortisol/beta-cyclodextrin tetradecasulfate, minocycline, nor the three modulator combination impacted the number of lung metastases, there was a decrease in the number of large lung metastases. Treatment with the cytotoxic therapies alone reduced the number of lung metastases. Addition of the modulators to treatment with the cytotoxic therapies resulted in a further reduction in the number of lung metastases. These results indicate that agents that inhibit the breakdown of the extracellular matrix can be useful additions to the treatment of solid tumors.

Effect of hypoxia and acidosis on the cytotoxicity of mitoxantrone, bisantrene and amsacrine and their platinum complexes at normal and hyperthermic temperatures.

In an effort to synthesize drugs which would become much more cytotoxic at clinically achievable hyperthermic temperatures, complexes of the tetrachloro-platinum(II) dianion were made with two anthracene dye derivatives, MITOX and BISANT, and the acridine dye derivative m-AMSA. As compared with the parent drug, PtCl4(MITOX)2 was less cytotoxic at 37 degrees C and more cytotoxic at 42 degrees C and 43 degrees C especially at pH 6.45. In contrast, the PtCl4(BISANT)2 was more cytotoxic than BISANT under all conditions. M-AMSA was again shown to be less cytotoxic at elevated temperatures but PtCl4(m-AMSA)2 was more cytotoxic especially at 43 degrees C and pH 6.45. Platinum levels in cells treated for 1 hr with 25 microM at 37 degrees C, 42 degrees C and at pH 7.40 versus pH 6.45 demonstrated no significant differences depending on temperature or pH except for PtCl4(MITOX)2 where approximately 4 times higher intracellular platinum levels were present at pH 6.45 versus pH 7.40, although this finding did not correlate with cytotoxicity. These results suggest that PtCl4(MITOX)2 and PtCl4(m-AMSA)2 may be highly interactive drugs with local hyperthermia.

Beta-carotene and/or vitamin E as modulators of alkylating agents in SCC-25 human squamous carcinoma cells.

Dietary levels of beta-carotene and vitamin E have been associated with cancer prevention and to a lesser extent, with therapeutic enhancement of cancer treatment. We report on the cytotoxicity of beta-carotene, vitamin E, and the combination of beta-carotene and vitamin E in human SCC-25 squamous carcinoma cells under various environmental conditions found in solid tumor masses. Beta-Carotene was selectively cytotoxic toward normally oxygenated cells and was generally more cytotoxic at normal pH than at acidic pH (6.45). Vitamin E was selectively cytotoxic toward normally oxygenated cells following 6 h exposure at normal pH and was generally equally cytotoxic toward normally oxygenated and hypoxic cells under the other conditions tested. Beta-Carotene was an effective modulator of cisplatin (CDDP) cytotoxicity toward SCC-25 cells, whereas vitamin E was not. Both beta-carotene and vitamin E were effective modulators of melphalan cytotoxicity toward SCC-25 cells. Treatment of SCC-25 cells with beta-carotene (70 microM, 2h) resulted in a reduction in superoxide dismutase activity, in glutathione-S-transferase activity, and in nonprotein sulfhydryl levels in the cells. Exposure to vitamin E or to a combination of beta-carotene and vitamin E increased the glutathione-S-transferase activity in SCC-25 cells by 40%-45% over the control value. Treatment with beta-carotene, vitamin E, or canthaxanthin reduced the incorporation of [3H]-thymidine into SCC-25 cells but not that into normal human keratinocytes. The most marked reduction in [3H]-thymidine incorporation into SCC-25 cells occurred following treatment with the combination of beta-carotene and melphalan. We hope to continue to explore the mechanisms of this effect and to study these combinations in vivo.

Effect of hypoxia and acidosis on the cytotoxicity of six metal(ligand)4(rhodamine-123)2 complexes at normal and hyperthermic temperatures.

Several analogues of PtCl4(Rh-123)2 in which the metal may be Pt or Pd and the coordinated ligand may be -Cl, -CN or -NO2 were prepared and tested in cell culture with EMT-6 cells at normal (37 degrees C) and hyperthermic (42 degrees C and 43 degrees C) temperatures and various environmental conditions (normally oxygenated vs. hypoxic and pH 7.40 vs. pH 6.45). Pd is a much more reactive metal than Pt, while -CN and -NO2 are more tightly bound ligands than is -Cl. The goal of these studies was to define the complex with the least cytotoxicity at 37 degrees C and the greatest enhancement in cytotoxicity under hyperthermic conditions. The Pt complexes Pt(CN)4(Rh-123)2 and Pt(NO2)4(Rh-123)2 were much less cytotoxic than PtCl4(Rh-123)2 under both normothermic and hyperthermic conditions. The Pd complexes were, in general, more cytotoxic than the corresponding Pt complexes. The level of metal (Pt or Pd) in the cells did not appear to be a major factor in the level of cytotoxicity obtained. Complexes which were not cytotoxic at 37 degrees C regardless of oxygenation level or pH did not become cytotoxic at hyperthermic temperatures. In conclusion, the optimal members of this series were the complexes with chloro ligands, indicating that aquation is probably a necessary step in the cytotoxic mechanism and cytotoxicity at 37 degrees C was necessary to obtain cytotoxicity at higher temperatures.

Characteristics of five human tumor cell lines and sublines resistant to cis-diamminedichloroplatinum(II).

In order to study the mechanisms responsible for resistance to CDDP, 5 human tumor cell lines were made resistant to CDDP by repeated in vitro exposures. After cloning it was found that the cell lines developed were between 3.3-fold and 17-fold more resistant to CDDP than the parental cell lines at the IC90. These lines were also resistant to carboplatin and tetraplatin; however, resistance to tetraplatin was lower than to the other platinum complexes. Sensitivity was also assessed to Adria, MTX, 5-FU, chlorambucil, 4-HC, 4-HIF, BCNU, Thiotepa, HN2, Mito C and L-PAM, and no consistent cross-resistance was observed. As compared with the parental lines, non-protein sulfhydryl content was elevated in 3 resistant lines, and protein sulfhydryl was elevated in all 5 lines, as was glutathione-S-transferase activity. Measurements of platinum in whole cells and nuclei after exposure of the cultures to 25 microM CDDP for either 1 or 6 hr showed that nuclear levels reflected those in whole cells and that, per mg protein, platinum levels were lower in resistant cells at both time points. Formation of DNA cross-links, determined by alkaline elution, was lower in resistant cell lines than in parental cell lines, but did not correlate with the absolute cell kill observed. These results indicate that cellular resistance to CDDP often involves decreases in drug accumulation and increases in protein sulfhydryl content. Possible strategies for overcoming these mechanisms are discussed.

Effect of acidic pH on radiosensitization of FSaIIC cells in vitro by misonidazole, etanidazole, or cis-diamminedichloroplatinum (II).

Because acidic regions may coexist with hypoxic regions in solid tumors, we have studied the effect of acidic extracellular pH on the abilities of misonidazole, etanidazole, and cis-diaminedichloroplatinum(II) (CDDP) to radiosensitize hypoxic FSaIIC cells in vitro. For 1-h exposures to misonidazole prior to and during irradiation, the sensitizer enhancement ratios (SERs) were 2.10 +/- 0.18 at 1 mM drug and 2.50 +/- 0.16 at 5 mM drug at pH 7.40 but only 1.90 +/- 0.14 and 2.30 +/- 0.14, respectively, at pH 6.45. For etanidazole the SERs at pH 7.40 at 1 and 5 mM drug were 1.90 +/- 0.13 and 2.40 +/- 0.18, respectively, but only 1.25 +/- 0.13 and 1.70 +/- 0.17, respectively, at pH 6.45. The decrease in the SERs for both 2-nitroimidazole compounds was statistically significant (P less than 0.01). When CDDP at concentrations of 1 and 5 microM was tested, SERs of 1.30 +/- 0.15 and 1.60 +/- 0.18, respectively, were observed at pH 7.40, and the increase was not significant at pH 6.45 (1.35 +/- 0.15 and 1.80 +/- 0.19, respectively). The cellular levels of misonidazole, etanidazole, and CDDP did not vary significantly at the environmental conditions tested. These results demonstrate that pH is a potentially important variable in the action of hypoxic cell radiosensitizing drugs and suggest that future evaluations of such agents should test the effects of pH.

Interaction with hyperthermia of tetrachloroplatinum(II)(Nile blue)2 and tetrachloroplatinum(II)(neutral red)2 in EMT6 murine cells and the murine FSaIIC fibrosarcoma.

Complexes of the tetrachoroplatinum(II) dianion with positively charged nuclear dyes were prepared in an effort to produce agents which gain ready access into the nucleus and become very cytotoxic at clinically relevant hyperthermia temperatures. Pt(Nile blue)2 and Pt(neutral red)2 are complexes of tetrachloroplatinum(II) with two closely related p-quinonediamine dyes. Pt(Nile blue)2 and Pt(neutral red)2 were only moderately cytotoxic to exponentially growing normally oxygenated or hypoxic EMT6 cells in vitro at pH 7.40 and 37 degrees C. At pH 7.40 and 42 degrees C and especially at 43 degrees C, however, Pt(Nile blue)2 became far more cytotoxic. At pH 6.45 Pt(Nile blue)2 became more toxic toward hypoxic cells (cell kill of 3.5 logs at 500 microM, 42 degrees C for 1 h). Pt(neutral red)2 became much more cytotoxic at pH 6.45 and 42 degrees C or 43 degrees C compared to pH 7.4, and the cell kill observed was similar in both euoxic and hypoxic cells (3 logs at pH 6.45, 43 degrees C with only 100 microM). Tumor cell survival studies in the FSaIIC murine fibrosarcoma demonstrated that both drugs killed in a dose-dependent log-linear manner. Hyperthermia treatment (43 degrees C, 30 min) immediately after either drug resulted in a dose modifying effect. The tumor growth delay produced by Pt(Nile blue)2 (100 mg/kg) was 4.6 days and by Pt(neutral red)2 (100 mg/kg) was 3.8 days. Both drugs were markedly improved by hyperthermia (tumor growth delay 1.4 days for hyperthermia; tumor growth delay 10.9 days for Pt(Nile blue)2 and 8.0 days for Pt(neutral red)2. Intracellular platinum levels were approximately 200 times higher after exposure of EMT6 cells to 25 microM of Pt(Nile blue)2 or Pt(neutral red)2 for 1 h at 37 degrees C than after exposure to the same concentration of cis-diamminedichloroplatinum(II). Treatment of cells with the drugs at 42 degrees C (1 h) resulted in no change in platinum levels with cis-diamminedichloroplatinum(II), but with Pt(Nile blue)2 and Pt(neutral red)2 an increase of 2- to 3-fold was found. Since previous work has shown that both of these complexes are active radiosensitizing agents, these new drugs seem quite well suited for further development as antitumor agents for use against solid tumors alone and in conjunction with hyperthermia and/or radiation therapy.

Interaction with hyperthermia of platinum complexes of triaminotriphenylmethane dyes.

Complexes of the tetrachloroplatinum(II) dianion PtCl4 with positively charged nuclear dyes have been designed in an effort to create new anticancer drugs for use with hyperthermia and/or radiation. The PtCl4 complexes with the monocationic triaminotriphenylmethane dye basic fuchsin [Pt(basic fuchsin)2] and the dicatrionic triaminotriphenylmethane dye methyl green [Pt(methyl green)], as well as the free dyes, were tested in exponentially growing EMT6 cells in vitro. Both the platinum complexes and free dyes were only moderately cytotoxic at pH 7.40 and 37 degrees C in normally oxygenated and hypoxic cells where cell killing by these drugs ranged from 0.5 to 1.5 logs at 500 microM. Each agent, however, became more cytotoxic at hyperthermic temperatures and pH 7.40. Pt(methyl green) and Pt(basic fuchsin)2 were slightly more cytotoxic to euoxic as opposed to hypoxic cells. Both platinum complexes became even more cytotoxic at pH 6.45 and 43 degrees C. Under these conditions, Pt(basic fuchsin)2 killed more hypoxic than euoxic cells (4.5 versus 2.5 logs at 500 microM), but Pt(methyl green) killed more euoxic than hypoxic cells (4.5 versus 2.5 logs at 100 microM). Methyl green was less cytotoxic than Pt(methyl green) at pH 6.45 and 43 degrees C, but basic fuchsin was the most cytotoxic drug under these conditions (cell kill of 3.5 logs in both euoxic and hypoxic cells at 100 microM). Intracellular platinum levels measured after 1 h exposure to 25 microM cisplatin, K2PtCl4, PT(methyl green), and PT(basic fuchsin)2 showed that approximately 1 ng of platinum per 10(6) cells was present after treatment with CDDP at pH 7.40 and pH 6.45 and at 37 degrees C and 42 degrees C; and approximately 0.2 ng was present after exposure to K2PtCl4 under each of these conditions. After exposure to Pt(methyl green), approximately 2.5 ng of platinum per 10(6) cells at pH 7.40, 37 degrees C, and 42 degrees C were present but increased to about 6.5 ng at pH 6.45 and 42 degrees C. With Pt(basic fuchsin)K, 726 ng of platinum were present at 37 degrees C, pH 7.40; 920 ng at 42 degrees C, pH 7.40; 313 ng at 37 degrees C, pH 6.45; and 413 ng at 42 degrees C, pH 6.45. Since Pt(methyl green) was more cytotoxic to cells at pH 6.45 and 42 degrees C, some of this effect could be attributed to increased uptake under these conditions.(ABSTRACT TRUNCATED AT 400 WORDS)

Interaction of platinum complexes of thiazin and xanthene dyes with hyperthermia.

In an attempt to develop platinum-containing drugs for use with hyperthermia that would be relatively nontoxic at 37 degrees C but would become very cytotoxic at 42 degrees or 43 degrees C, several nuclear dyes were complexed to the tetrachloroplatinum(II) dianion (PtCl4) at a ratio of 2:1. The cytotoxicity of PtCl4 complexes of three thiazin dyes (thionin, azure B, and methylene blue), the xanthene dye pyronin Y, and the thiazole dye thioflavin was examined in exponentially growing euoxic and hypoxic EMT6 cells in vitro at 37 degrees, 42 degrees, and 43 degrees C and at pH 7.40 and 6.45. Of the thiazin dye complexes, the cytotoxicity of Pt(methylene blue)2 was most enhanced at hyperthermic temperatures. Both Pt(pyronin Y)2 and Pt(thioflavin)2 also became markedly more cytotoxic at 42 degrees and 43 degrees C at pH 6.45 vs pH 7.40. In vivo tumor excision assays in the FSaIIC fibrosarcoma showed that with each of the thiazin dye-platinum complexes, hyperthermia enhanced cell kill [most effectively on Pt(methylene blue)2] but was not dose-modifying. For both Pt(pyronin Y)2 and Pt(thioflavin)2, however, administration of 43 degrees C, 30-min hyperthermia to the tumor immediately after i.p. drug injection was dose-modifying. Tumor growth delay studies in the FSaIIC tumor system demonstrated that, as with the in vitro studies, Pt(pyronin Y)2 and Pt(methylene blue)2 were most enhanced by hyperthermia [tumor growth delay increased by 4.8- and 3.0-fold, respectively, vs only 1.3-fold for cisplatin (CDDP)]. Examination of intracellular platinum levels after exposure of EMT6 cells to 25 microM of drug for 1 h at 37 degrees and 42 degrees C and at pH 7.40 and 6.45 showed that each platinum-dye complex achieved platinum levels that were 100-600 times higher at 37 degrees C and pH 7.40 than those obtained using CDDP. The platinum levels for each drug dropped markedly when exposure took place at pH 6.45. Exposure at 42 degrees C only moderately increased platinum levels in cells exposed to these drugs. Thus, for several of these drugs the level of cytotoxicity observed was in great part independent of the intracellular platinum levels achieved. Pt(pyronin Y)2 is an effective drug for use with hyperthermia, and further studies using this combination with and without radiation are under way.

Interaction of PtCl4(Fast Black)2 with hyperthermia.

We are developing complexes of negatively charged PtCl4 with positively charged nuclear dyes as new antitumor agents for use alone and in conjunction with hyperthermia and/or radiation. Elemental analysis has shown that the complex PtCl4(Fast Black)2 is a tight ion pair. In experimentally growing EMT6 cells in vitro, PtCl4(Fast Black)2 killed cells in a log-linear manner which increased as the temperature of the exposures was increased from 37 to 42 degrees C or 43 degrees C. In addition, cell kill was also increased under conditions of low pH (6.45), especially in hypoxic cells treated at elevated temperature. Measurement of intracellular platinum levels after exposure to 25 microM cisplatin or PtCl4(Fast Black)2 demonstrated that platinum levels were between 170- and 200-fold higher after exposure to PtCl4(Fast Black)2. In vivo studies in the FSaIIC murine fibrosarcoma showed, again, that PtCl4(Fast Black)2 killed in a log-linear manner. Treatment of tumors placed in the thigh with 43 degrees C, 30-min hyperthermia immediately following i.p. injection of PtCl4(Fast Black)2 was dose modifying. One hundred mg/kg of PtCl4(Fast Black)2 produced a 4.6-day tumor growth delay which increased to 6.4 days with 43 degrees C, 30-min hyperthermia immediately following i.p. injection of PtCl4(Fast Black)2 was does modifying. One hundred mg/kg of PtCl4(Fast Black)2 produced a 4.6-day tumor growth delay which increased to 6.4 days with 43 degrees C, 30-min hyperthermia (growth delay for hyperthermia alone was 1.4 days), and 500 mg/kg produced a 5.6-day delay which increased to 11.0 days with hyperthermia. In contrast, cisplatin (5 mg/kg) produced a 4.4-day delay which increased to 5.9 days with hyperthermia. PtCl4(Fast Black)2 was well tolerated by animals, and the maximally tolerated dose was approximately 650 mg/kg. This new complex appears quite active as an antitumor agent alone and in conjunction with hyperthermia, and, since other studies have shown it to interact positively with radiation, this agent seems a very appropriate candidate for further development as a clinical anticancer drug.