Recruitment of trimeric proliferating cell nuclear antigen by G1-phase cyclin-dependent kinases following DNA damage with platinum-based antitumour agents.

BACKGROUND: In cycling tumour cells, the binary cyclin-dependent kinase Cdk4/cyclin D or Cdk2/cyclin E complex is inhibited by p21 following DNA damage to induce G1 cell-cycle arrest. However, it is not known whether other proteins are also recruited within Cdk complexes, or their role, and this was investigated. METHODS: Ovarian A2780 tumour cells were exposed to the platinum-based antitumour agent 1R,2R-diaminocyclohexane(trans-diacetato)(dichloro)platinum(IV) (DAP), which preferentially induces G1 arrest in a p21-dependent manner. The Cdk complexes were analysed by gel filtration chromatography, immunoblot and mass spectrometry. RESULTS: The active forms of Cdk4 and Cdk2 complexes in control tumour cells have a molecular size of ~140 kDa, which increased to ~290 kDa when inhibited following G1 checkpoint activation by DAP. Proteomic analysis identified Cdk, cyclin, p21 and proliferating cell nuclear antigen (PCNA) in the inhibited complex, and biochemical studies provided unequivocal evidence that the increase in ~150 kDa of the inhibited complex is consistent with p21-dependent recruitment of PCNA as a trimer, likely bound to three molecules of p21. Although p21 alone was sufficient to inhibit the Cdk complex, PCNA was critical for stabilising p21. CONCLUSION: G1 Cdk complexes inhibited by p21 also recruit PCNA, which inhibits degradation and, thereby, prolongs activity of p21 within the complex.

Effects on the monocyte-macrophage system and antitumor activity against L1210 leukemia of cis-bis-cyclopentenecarboxylato-trans-R,R-1,2-diaminocyclohexane -platinum (II) encapsulated in multilamellar vesicles.

Multilamellar vesicles (MLVs) composed of dimyristoyl phosphatidylcholine and dimyristoyl phosphatidylglycerol at a molar ratio of 7:3 were used as carriers of cis-bis-cyclopentenecarboxylato-trans-R,R-1,2-diaminocyclohexane-p latinum (II) (CPDP). The encapsulation efficiency of liposomal CPDP (L-CPDP) was 87.6%, and its stability in normal saline at 14 days was 94.4%. The in vitro and in vivo effects on the function of the monocyte-macrophage system and the antitumor activity against L1210 leukemia were investigated in CD-1 and (C57BL/6J X DBA/2J)F1 mice. L-CPDP and cisplatin (CDDP) caused a comparable inhibition of murine-resident peritoneal macrophage (PM) protein and RNA synthesis and superoxide anion release. PM-mediated tumor cell cytotoxicity was completely inhibited at a concentration of 10 micrograms CDDP and L-CPDP/ml but not at concentrations of 1 and 5 micrograms/ml. The differences in plasma clearance of 99mTc-labeled MLV and phagocytic capacity of the liver among animals pretreated with the maximum tolerated doses of L-CPDP (25 mg/kg), empty liposomes, or CDDP (10 mg/kg) were not statistically significant (plasma clearance % of control: 105, 110, and 100, respectively: P greater than .05; liver uptake % of control: 87, 96, and 104, respectively: P greater than .05). At the maximum tolerated doses, the antitumor activity of L-CPDP against L1210 leukemia was similar to that of CDDP when a single dose was administered [median survival of treated mice/median survival of control mice X 100 (%T/C): 181 vs. 175] and slightly higher with the use of a triple-dose schedule (%T/C: 275 vs. 225). L-CPDP is easy to prepare, has a high-encapsulation efficiency and stability, is not more toxic than CDDP to the monocyte-macrophage system, and is at least as effective as CDDP against L1210 leukemia.

Lipophilic cisplatin analogues entrapped in liposomes: role of intraliposomal drug activation in biological activity.

cis-Bis-neodecanoato-trans-R,R-1,2-diaminocyclohexane platinum (II) (NDDP), a lipophilic cisplatin analogue containing two branched leaving groups of 10 carbon atoms, is undergoing clinical evaluation in a liposomal formulation. In previous studies, NDDP entrapped in multilamellar vesicles composed of dimyristoylphosphatidylcholine (DMPC) and dimyristoylphosphatidylglycerol (DMPG) at a 7:3 molar ratio was non-nephrotoxic in humans, not cross-resistant with cisplatin in different in vitro and in vivo systems, and more active than cisplatin against murine models of experimental liver metastases whereas free NDDP was devoid of in vivo antitumor activity at the optimal dose of L-NDDP and barely active at higher doses. To elucidate the mechanisms by which the liposomal carrier enhances the biological properties to this class of antitumor agents, we studied the effect of the liposome composition, size of the branched leaving groups of the platinum compound, and pH and composition of the aqueous phase on the entrapment efficiency, drug leakage, drug stability, and in vivo toxicity and antitumor activity of different liposomal formulations of these agents. In experiments using normal saline as aqueous phase, the presence of DMPG in the lipid bilayer resulted in a decreased stability and an increased biological activity of NDDP, whereas NDDP entrapped in liposomes composed of DMPC alone (not containing DMPG) was stable but devoid of antitumor activity. In studies with structurally related analogues with branched leaving groups of 5, 6, 7, and 9 carbon atoms, similar trends were observed. In addition, the number of carbon atoms in the leaving groups was directly and inversely related to the entrapment efficiency and stability of the analogues, respectively, independently of lipid composition; increasing the size of the branched leaving groups resulted in an increased in situ degradation of the platinum compound and enhanced biological activity and potency. These results suggest that this class of platinum compounds exerts its biological activity through the formation of active intermediates in situ within the lipid bilayers and that the activation reaction is highly dependent on the presence of DMPG and the size of the lipophilic leaving group.

Axial ligands and alicyclic ring size modulate the activity and biochemical pharmacology of ammine/cycloalkylamine-platinum(IV) complexes in tumor cells resistant to cis-diamminedichloroplatinum(II) or trans-1R,2R-1S,2S-diaminocyclohexanetetrachloroplatinum(IV).

A platinum(II) and 3 platinum(IV) ammine/cycloalkylamine homologous series were evaluated for cytotoxicity and biochemical pharmacology in murine leukemia L1210/0, cis-diamminedichloroplatinum(II)- resistant L1210/DDP, and diaminocyclohexaneplatinum-resistant L1210/1,2-diaminocyclohexane (DACH) cells. Within each series, which contained 4 homologues with differing alicyclic (cycloalkyl) ring size (cyclopropane, cyclobutane, cyclopentane, or cyclohexane), cytotoxicity increased with increasing ring size. This appeared to be due to an increase in partition coefficient, and the resulting increase in drug accumulation and intracellular DNA adducts in ascending each of the series. There were exceptions to this generalization, predominantly in L1210/DACH cells, where the biochemical pharmacology was not entirely consistent with the cytotoxic response and suggested that other factors may be at play. The relationship between structure and ability to circumvent cis-diamminedichloroplatinum(II) and/or trans-1R,2R-1S,2S- diaminocyclohexanetetrachloroplatinum(IV) resistance was complex. Ascending the platinum(II) series caused resistance factors to decrease in L1210/DDP cells but increase in L1210/DACH cells. An increase in resistance factors was also observed in ascending the axial chloroplatinum(IV) series in the L1210/DACH line. In contrast, ascending the axial chloroplatinum(IV) series in the L1210/DDP line and axial acetatoplatinum(IV) and axial hydroxoplatinum(IV) series in both cell lines resulted in increases in resistance factors for the first stepwise increase in the cycloalkylamine ring size, but resistance factors then decreased progressively with further increases in ring size. Reduction of the platinum(IV) analogues to the platinum(II) congener appears to be necessary for binding to DNA. The similarity in biological actions between the platinum(II) and axial chloroplatinum(IV) series is likely due to the rapid reduction of tetravalent members to platinum(II) forms. The axial acetatoplatinum(IV) and axial hydroxoplatinum(IV) complexes were reduced more slowly, which may explain their lower potency, but not the ability of the higher member to circumvent both cis-diamminedichloroplatinum(II) and trans-1R,2R-1S,2S- diaminocyclohexanetetrachloroplatinum(IV) resistances. Explanation for this will require additional studies. The results have demonstrated high dependencies on ring size of the carrier amine ligand, valence state of platinum, and the nature of the axial ligand for modulation of potency, cross-resistance property, and biochemical pharmacology of ammine/cycloalkylamine complexes.

Treatment and prophylaxis of experimental liver metastases of M5076 reticulosarcoma with cis-bis-neodecanoato-trans-R,R-1,2-diaminocyclohexaneplatinum (II) encapsulated in multilamellar vesicles.

cis-Bis-neodecanoato-trans-R,R-1,2-diaminocyclohexaneplatinum++ +-(II) (NDDP) was encapsulated in multilamellar vesicles composed of dimyristoyl phosphatidylcholine and dimyristoyl phosphatidylglycerol at a 7:3 molar ratio. Compared with cisplatin, i.v. administration of an equimolar dose of liposome-encapsulated NDDP (L-NDDP) resulted in 15-fold higher peak platinum levels in the spleen (204.7 versus 13.3 micrograms/g dry tissue), 5-fold higher in the lungs (116.4 versus 21.0 micrograms/g dry tissue), 3-fold higher in the liver (71.6 versus 23.9 micrograms/g dry tissue), and 4-fold higher in the blood (14.8 versus 3.9 micrograms/ml). At the optimal dose and schedule, L-NDDP administered i.p. in mice bearing peritoneal L1210 leukemia resulted in the percentage of median survival time of treated mice divided by median survival time of control mice (%T/C) of 312 versus 225 for cisplatin and free NDDP. When administered i.v., L-NDDP was also more active than cisplatin against L1210 leukemia inoculated i.v. (%T/C 186 versus 142). L-NDDP was markedly active against L1210 leukemia resistant to cisplatin (%T/C, 200 versus 112 for cisplatin). In mice bearing liver metastases of M5076 reticulosarcoma, L-NDDP was significatnly more effective than cisplatin at equimolar doses (mean survival time, 57 +/- 9 (SD) days for L-NDDP versus 42 +/- 3 days for cisplatin, P less than 0.05). L-NDDP was also effective in preventing liver metastases of M5076 when administered up to 24 h prior to tumor inoculation (mean survival, 28 +/- 2 days for L-NDDP versus 22 +/- 2 days for cisplatin, P less than 0.05). L-NDDP is significantly non-cross-resistant with cisplatin and more effective against phagocytic and nonphagocytic murine tumors.

Biochemical pharmacology of homologous alicyclic mixed amine platinum(II) complexes in sensitive and resistant tumor cell lines.

Three homologous alicyclic mixed amine cis-(NH3)(R-NH2)Cl2Pt(II) complexes, in which R = C3H5, C6H11, and C8H15 (complexes abbreviated C3, C6, and C8, respectively), were evaluated with reference compounds cisplatin and tetraplatin for antitumor activities and biochemical pharmacology in wild-type (murine leukemia L1210/0 and human ovarian A2780) and corresponding variant cell lines resistant to cisplatin (L1210/DDP and 2780CP) and tetraplatin (L1210/DACH and 2780TP). Cytotoxicities, measured by either a 3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyltetrazolium bromide or a clonogenic assay, were maximal for the C6 complex, which was up to 12-, 40-, and 6-fold more potent than C3 against wild-type, cisplatin-resistant, and tetraplatin-resistant models, respectively, and up to 2-fold more potent than C8 against these cell lines. In general, cross-resistance to mixed amine analogues was partial in cisplatin- and tetraplatin-resistant cells and decreased (in L1210/DDP and 2780CP) or increased (in L1210/DACH and 2780TP) with increase in the alicyclic ring size. The increase in ring size resulted in a corresponding increase in partition coefficient, which correlated directly with intracellular accumulations of mixed amine analogues in all cell lines. However, the intracellular DNA-platinum adducts, and not cellular platinum content, was the pharmacological entity that corresponded closely to potencies of the molecules. DNA adduct formation was disproportionate to the level of cellular drug accumulation. For instance, complex C8, which accumulated to the greatest extent in any given cell line, produced adduct levels that were similar to or lower than those produced by C6. A partial explanation for this observation was the demonstrated reduced rate of binding of C8 to DNA. This study has highlighted the significance of alicyclic ring size in modulating the potency, cross-resistance profile, and biochemical pharmacology of mixed amine platinum(II) complexes in sensitive and cisplatin- or tetraplatin-resistant tumor cells.

Toxicity and antitumor activity of cis-bis-cyclopentenecarboxylato-1,2-diaminocyclohexane platinum(II) encapsulated in multilamellar vesicles.

The potential of multilamellar vesicles (MLVs) as carriers of cis-bis-cyclopentenecarboxylato-1,2-diaminocyclohexane platinum(II) (CPDP), a lipophilic cisplatin derivative, was assessed. MLVs composed of dimyristoyl phosphatidylcholine (DMPC), dimyristoyl phosphatidylglycerol (DMPG), and cholesterol at different molar ratios were tested. The MLV-CPDP preparation with the highest antitumor activity against L1210 leukemia in vivo was DMPC:DMPG 7:3-CPDP. The encapsulation efficiency of this preparation was 66 +/- 4% (SD); the stability in 0.9% NaCl solution at 4 degrees C was 89% at 14 days and 93% 18 h after incubation in human AB serum at 37 degrees C. The toxicities of DMPC:DMPG 7:3-CPDP and free CPDP (suspended in hydroxypropyl cellulose) administered i.p. were similar (50% lethal dose = 75 versus 91 mg/kg; blood urea nitrogen values 96 h after the administration of the 50% lethal dose = 32.0 versus 34.4 mg/dl). The mean %T/C [(median survival time of treated mice divided by median survival time of control mice) X 100] obtained after a single i.p. injection of the optimal dose of each preparation tested was 215 (range 200 to 232) for DMPC:DMPG 7:3-CPDP, 175 (range 158 to 209) for DMPG-CPDP, 162 (range 136 to 179) for free CPDP, and 178 (range 169 to 189) for cisplatin. Using a multiple i.p. injection schedule (injections on Days 1, 5, and 9), DMPC:DMPG 7:3-CPDP was more active than free CPDP and cisplatin (%T/C: 403, 284, and 253% respectively). DMPC:DMPG 7:3-CPDP is less toxic and more active against L1210 leukemia in vivo than is cisplatin. The encapsulation of CPDP in MLVs composed of DMPC:DMPG 7:3 provides an adequate vehicle for the administration of this lipophilic compound and enhances its antitumor activity against L1210 leukemia.

Modulation of cytotoxicity and cellular pharmacology of 1,2-diaminocyclohexane platinum (IV) complexes mediated by axial and equatorial ligands.

Isomers (R,R-, S,S-, and cis-) of 1,2-diaminocyclohexane (DACH) platinum(IV) complexes with selected axial and equatorial ligands were synthesized and evaluated for in vitro antitumor activity, cellular uptake, and total DNA-Pt adducts. L1210 cells, sensitive to cis-diamminedichloroplatinum(II) (CDDP) and tetraplatin (L1210/0), 160-fold resistant to CDDP [L1210/diamminedichloroplatinum (DDP)], or 70-fold resistant to tetraplatin (L1210/DACH), were used in conjunction with compounds having the general structure DACH-Pt(IV)-X2Y2, where X and Y are axial and equatorial ligands and X2Y2 are specifically Cl2Cl2,Ac2Cl2, (TFA)2Cl2, (OH)2Cl2, and Cl2CBDCA (Cl, chloro; Ac, acetato; TFA, trifluoroacetato; OH, hydroxo; CBDCA, 1,1-cyclobutanedicarboxylato). Comparison of cytotoxicities between isomers of Cl2Cl2,Ac2Cl2, or Cl2CBDCA indicated that R,R-isomers were the most effective against all three cell lines. The relatively lower activity of the S,S- and cis-isomers was cell line dependent: against L1210/DACH, both isomers of Cl2Cl2 were only 2- to 3-fold less effective, and this contrasted with 7- and 26-fold lower cytotoxicities, respectively, against L1210/DDP. Cross-resistance factors in the L1210/DDP and L1210/DACH lines depended on both isomeric form and the nature of axial or equatorial ligand. The L1210/DDP cells were 6- to 9-fold cross-resistant to the R,R-isomer, 8- to 15-fold to S,S-isomer, and 13- to 38-fold to cis-isomer. The L1210/DACH line was only 4- to 7-fold cross-resistant to the three isomers of Ac2Cl2 but cross-resistance to the isomers was 47- to 79-fold for Cl2Cl2 and 22- to 56-fold for Cl2CBDCA complexes. Compared with CDDP, accumulation (2 h at 100 microM drug concentration) of Ac2Cl2 in the three L1210 cell lines was 26-50%, while uptake of Cl2Cl2 and (TFA)2Cl2 was 100-170% and 320-570%, respectively. The greatest DNA binding was seen with Cl2Cl2 in all cell lines, followed by (TFA)2Cl2, CDDP, and Ac2Cl2. DNA binding correlated directly with potency (1/concentration producing 50% inhibition) in the L1210/0 model (r = 0.973, P < 0.016) but not in the L1210/DDP and L1210/DACH models. Accumulation and DNA-binding studies indicated that binding efficiency to DNA was: Cl2Cl2 > Ac2Cl2 > CDDP > (TFA)2Cl2. In a nonreducing environment, the Pt(IV) complexes (20 microM) did not react with salmon sperm DNA. Reduced glutathione (100 microM), as a reducing agent, rendered full binding capacity to Cl2Cl2; binding was 25-30% of the expected maximum for (TFA)2Cl2, while Ac2Cl2 remained inert.(ABSTRACT TRUNCATED AT 400 WORDS)

Increased cytotoxicity and reversal of resistance to cis-diamminedichloro-platinum(II) with entrapment of cis-Bis-neodecanoato-trans-R,R-1,2-diaminocyclohexaneplatinum (II) in multilamellar lipid vesicles.

The role of liposome entrapment in modulating the cytotoxicity of a lipophilic cisplatin derivative was assessed. cis-Bis-neodecanoato-trans-R,R-1,2-diaminocyclohexaneplatinum++ +(II) (NDDP) was tested in suspension (free NDDP) or entrapped in multilamellar vesicles composed of dimyristoylphosphatidyl choline and dimyristoylphosphatidyl glycerol (L-NDDP). Against LoVo colon carcinoma cells sensitive to cisplatin, L-NDDP was two times more cytotoxic in vitro than free NDDP and cisplatin (Do 7 microM for L-NDDP, 15 microM for free NDDP, and 16 microM for cisplatin). Against LoVo cells resistant to a concentration of 3 micrograms/ml of cisplatin, L-NDDP was three times more cytotoxic than free NDDP and cisplatin (Do 14 microM for L-NDDP, 45 microM for free NDDP, and 48 microM for cisplatin). In in vivo studies, free NDDP was less potent and less active than L-NDDP against i.p. L-1210 leukemia (free NDDP, optimum %T/C 148 at a dose of 75 mg/kg; L-NDDP, optimum %T/C 185 at a dose of 25 mg/kg) and i.p. L1210/PDD leukemia (free NDDP, optimum %T/C 128 at a dose of 50 mg/kg on Days 1, 5, and 9; L-NDDP, optimum %T/C 200 at a dose of 12.5 mg/kg on Days 1, 5, and 9). Free NDDP administered i.v. was inactive against liver metastases of M5076 reticulosarcoma (%T/C 102) while L-NDDP showed significant activity (%T/C 140). The single dose i.v. LD50 in mice of free NDDP and L-NDDP were similar (79.4 mg/kg for free NDDP and 64.5 mg/kg for L-NDDP). These studies show that NDDP is a liposome-dependent drug since it can only be satisfactorily formulated in the liposomal form and since the liposomal carrier plays a crucial role in determining its antitumor activity.

Ascorbato(1,2-diaminocyclohexane):platinum(II) complexes, a new series of water-soluble antitumor drugs.

Dichloro-1,2-diaminocyclohexane (DACH):platinum(II), the prototype DACH:platinum complex, had good antitumor activity, was not cross-resistant with cis-dichlorodiammineplatinum(II) (DDP), but was, unfortunately, virtually insoluble in water and was, therefore, not evaluated clinically. This paper summarizes some of the chemical and biological attributes of a series of cis-bisascorbato-DACH:platinum(II) complexes (DAP). Although the primary emphasis has been placed on the DAP complex consisting of the isomeric mixture DACH, a series of complexes using the isomers of either DACH or ascorbic acid have also been synthesized. The synthetic procedure entailed reacting the water-soluble sulfato-DACH:platinum(II) with barium ascorbate, and the water-soluble product DAP was removed from the BaSO4 precipitate by filtration. Based upon elemental analysis, all the complexes had stoichiometric composition of one DACH:one platinum and two ascorbate monoanions. High-pressure liquid chromatography of cis-bisascorbato (mixed-isomer DACH):platinum revealed a series of platinum-containing, ultraviolet-absorbing peaks. All the DAP complexes had significant in vitro cytotoxicity against L1210 leukemia cells (L1210/0) with 50%-inhibitory dose values ranging from 2 to 5 micrograms/ml. None of the complexes was cross-resistant with DDP when tested in vitro against L1210 cells 50-fold resistant to DDP (L1210/DDP). The cis-bisascorbato (mixed-isomer DACH):platinum (DAP-1) was administered i.p. to C57BL X DBA/2 F1 mice inoculated i.p. with 10(6) L1210/0 cells. When administered on Days 1, 5, and 9, the DAP-1 complex consistently produced treated:control values in excess of 200% with several long-term survivors (alive 60 days after tumor inoculation). Further, the DAP-1 complex was totally non-cross-resistant with DDP when tested in vivo against a DDP-resistant L1210 line. Toxicological investigations revealed that DAP-1 was relatively nonnephrotoxic but did cause the expected bone marrow and gastrointestinal toxicity. In summary, the DAP complexes are highly water-soluble, nonnephrotoxic platinum complexes with sufficient antitumor activity to warrant further pharmacological, biochemical, and chemical investigations.

Water-soluble N-substituted iminodiacetato(1,2-diaminocyclohexane)-platinum(II) complexes as potential antitumor agents.

A series of water-soluble N-substituted iminodiacetato(1,2-diaminocyclohexane)-platinum(II) complexes (IDP) were synthesized and tested for chemical stability, antitumor activity, and toxicity. The results obtained suggest that these complexes are relatively stable for more than 48 h when dissolved in water or phosphate buffer. All complexes had good in vitro cytotoxicity and were not cross-resistant with cis-dichloro-diammineplatinum(II) (DDP) in a DDP-resistant cell line in vitro. When the complexes were administered as a single i.p. injection to C57BL/6 X DBA/2F1 (hereafter called B6D2F1) mice inoculated with L1210 leukemia cells, a significant increase in mean survival time was observed, but there were few long-term survivors. When the complexes were administered on Days 1, 5, and 9 after tumor inoculation, however, cure rates of 50 to 85% were obtained. The oncolytic activity of the IDP complexes against L1210 ascites appeared much greater than that of DDP. The IDP complexes also had good antitumor activity when administered i.p. on Days 1, 5, and 9 following i.p. inoculation of B16 melanoma to B6D2F1 mice. Five of the six IDP complexes had no significant nephrotoxicity (as evidenced by lack of elevated blood urea nitrogen levels). N-Benzyl-iminodiacetato(1,2-diaminocyclohexane)-platinum(II) resolved into three distinct peaks of UV-absorbing material that corresponded with three distinct peaks of platinum-containing material. The exact chemical identity of the active component of this mixture is currently under investigation. The results obtained to date, however, suggest that the N-substituted iminodiacetato(1,2-diaminocyclohexane)-platinum(II) complexes are good candidates for further developmental studies.

Cellular pharmacology of liposomal cis-bis-neodecanoato-trans-R,R-1,2-diaminocyclohexaneplatinum(II) in A2780/S and A2780/PDD cells.

We studied the cytotoxicity, cellular accumulation, and DNA interactions induced by liposome-entrapped NDDP (L-NDDP) and cisplatin in A2780 human ovarian carcinoma cells sensitive (A2780/S) and resistant (A2780/PDD) to cisplatin. L-NDDP was 2-fold more cytotoxic than cisplatin against A2780/S cells with 5-h or 24-h drug exposure. Both cell lines were equally sensitive to L-NDDP, while A2780/PDD cells were 4-fold resistant to cisplatin (resistance indexes, 1.30-1.85 and 4.02-4.50, respectively). Using a drug exposure time of 24 h, L-NDDP cytotoxicity was independent of the liposome composition used, whereas with shorter drug exposure (5 h), the cytotoxicity of L-NDDP was directly related to the relative content of DMPG in the liposome carrier. However, changes in liposome composition or drug exposure time did not alter the resistance index of L-NDDP in this cell system. The cellular accumulation of L-NDDP was similar in both cell lines and 2- to 5-fold higher than that of cisplatin in A2780/S cells, whereas the cellular accumulation of cisplatin was reduced by 2- to 3-fold in A2780/PDD cells. The presence of DMPG in the lipid bilayer enhanced by 2-fold the cellular accumulation of L-NDDP, in good correlation with the direct relation between cytotoxic potency of L-NDDP and the presence of DMPG in the liposome carrier. Pt/DNA levels were determined at different time points after drug exposure for 1 h. Peak Pt/DNA levels were observed at 6 h for cisplatin and at 9 h for L-NDDP. Peak Pt/DNA levels and Pt/DNA over time of L-NDDP were about 1.5- and 3-fold higher than those of cisplatin in A2780/S and A2780/PDD cells, respectively, when equimolar concentrations of both drugs were used. Cisplatin induced significant DNA interstrand and DNA-protein cross-links in A2780/S cells, and a good correlation was observed between cytotoxicity against both cell lines and both types of lesions. In contrast, equimolar concentrations of L-NDDP induced only minimal DNA interstrand cross-links in either cell line.(ABSTRACT TRUNCATED AT 400 WORDS)

Cellular pharmacology of liposomal cis-bis-neodecanoato-trans-R,R-1,2-diaminocyclohexaneplatinum (II) in mouse resident peritoneal macrophages, Kupffer cells, and hepatocytes.

The in vitro and in vivo interaction of liposomal cis-bis-neodecanoato-trans-R,R-1,2-diaminocyclohexaneplatinum++ + (II) (L-NDDP) with mouse resident peritoneal macrophages (RPM), Kupffer cells (KC), and hepatocytes was studied. The peak in vitro uptake of L-NDDP by RPM was 12.5 ng elemental platinum/100 micrograms cell protein and constituted 0.2% of the platinum available for phagocytosis. The subsequent release of platinum by RPM was rapid initially, with a 20-fold increase over the first 4 h, followed by a plateau; ultrafilterable (free) platinum constituted 50% of the total platinum released at 24 h. The retained intracellular platinum in RPM at 24 h was close to 50% of that initially present. The peak in vitro uptake of L-NDDP by KC was 11.3 ng platinum/100 micrograms cell protein and amounted to 0.2% of the platinum available for phagocytosis. The release of platinum by KC was detectable only after 4 h of incubation and increased 3-fold over the next 14 h. The ultrafilterable platinum released by KC at 18 h was 40% of the total platinum released. The retained intracellular platinum in KC at 18 h was 33% of that initially present. The peak in vitro uptake of L-NDDP by hepatocytes was almost 50 ng platinum/100 micrograms cell protein and constituted 0.8% of the platinum available for intake. Following the i.v. injection of L-NDDP, hepatocytes contained up to 6-fold higher platinum concentrations than KC. This observation was supported by transmission electron microscopy showing a higher concentration of multilamellar vesicles within hepatocytes than in KC, 5 min after i.v. injection of L-NDDP. These findings suggest that L-NDDP becomes available to the liver following i.v. injection, that both macrophages and hepatocytes play a role in the metabolism of L-NDDP, and that Kupffer cells could mediate a sustained release of platinum in the liver following the interaction with L-NDDP, indicating the potential of L-NDDP for the treatment of tumors in the liver.

Antitumor activity against human tumor samples of cis-diamminedichloroplatinum(II) and analogues at equivalent in vitro myelotoxic concentrations.

We compared the antitumor activity of cis-diamminedichloroplatinum(II) (cisplatin; CDDP) with three CDDP analogues: cis-diammine-1,1-cyclobutanedicarboxylateplatinum(II) (CBDCA), N-methyliminodiacetato-1,2-diamino(cyclohexane)platinum(II) (MIDP), and N-(2-hydroxyethyl)-iminodiacetato-1,2-diamino(cyclohexane)platinum (II) (HIDP). Fresh human tumor samples in the adhesive tumor culture system were utilized for this comparison. The equitoxic concentrations of all four drugs were derived based on their inhibitory activity against human bone marrow samples. For these normalized concentrations, CDDP proved to have a higher cytotoxic activity than its analogues. CBDCA's in vitro activity had a significant correlation with CDDP activity (r = 0.67) in vitro. However, the structurally similar substances MIDP and HIDP demonstrated a much greater degree of association (r = 0.90). Our data suggest that CBDCA, HIDP, and MIDP have overall less activity than CDDP when tested at equitoxic in vitro concentrations. Close association between CDDP and CBDCA also reflects known clinical experience with these two drugs, suggesting the method of comparison used here is probably appropriate. These conclusions, however, must be validated by clinical trials.

Increased therapeutic efficacy induced by tumor necrosis factor alpha combined with platinum complexes and whole-body hyperthermia in rats.

This study examined the effect of a trimodality therapy of the combination of recombinant human tumor necrosis factor alpha (TNF), whole-body hypertheria (WBH), and cis-diamminedichloroplatinum(II) (CDDP) or cis-diammine-1,1-cyclobutane dicarboxylate platinum(II) (CBDCA) on a fibrosarcoma and normal tissue in F344 rats. TNF (1 x 10(5) units/kg) increased the antitumor effect of both CDDP (1.5 mg/kg) + WBH (2 h at 41.5 degrees C) and CBDCA (30 mg/kg) + WBH. Tumor growth delay, which was 1.9 days for CDDP + WBH and 2.7 days for CBDCA + WBH (P less than 0.01 compared to control), was significantly increased to 2.9 days with TNF + CDDP + WBH and 5.4 days with TNF + CBDCA + WBH (P less than 0.05). WBH, TNF, CDDP or CBDCA alone, TNF + CDDP, TNF + CBDCA, or TNF + WBH had no significant effect on tumor growth. In contrast, administration of TNF did not enhance the CDDP- or CBDCA-mediated dose limiting normal tissue toxicity. CDDP + WBH-mediated acute renal injury and CBDCA + WBH-mediated acute myelosuppression, as determined by blood urea nitrogen and peripheral blood cell counts, respectively, were not increased with the addition of TNF to either dual modality therapy. Histopathologically, addition of TNF produced no significant alterations in the kidney and the bone marrow as compared to CDDP + WBH or CBDCA + WBH. These data show that TNF enhanced the platinum + WBH-mediated antitumor effect without increasing normal tissue toxicity, suggesting that TNF may increase the therapeutic efficacy of CDDP or CBDCA combined with WBH.

Phase I clinical and pharmacological study of liposome-entrapped cis-bis-neodecanoato-trans-R,R-1,2-diaminocyclohexane platinum(II).

cis-Bis-neodecanoato-trans-R,R-1,2-diaminocyclohexaneplatinum++ +(II) (NDDP) is a liposome dependent cisplatin analogue since the liposome carrier is required for its i.v. administration and for its biological activity. A Phase I study of liposome entrapped NDDP (L-NDDP) was performed using a single i.v. injection every 4 weeks. L-NDDP was prepared and characterized at M. D. Anderson Cancer Center. The maximum tolerated dose of L-NDDP was 312.5 mg/m2. The dose-limiting toxicity was myelosuppression, affecting all three blood cell lineages. The granulocyte nadir occurred on days 14-18, and the platelet nadir consistently earlier (days 11-12). The median day of recovery of blood cell counts was day 21 (range, 18-32). Other toxicities included grade 2 nausea and vomiting, fever consisting of a single temperature spike in most patients, grade 1 diarrhea after 60% of courses, and grade 1-2 malaise lasting for 5-10 days after the infusion in 73% of courses. Transient alanine aminotransferase elevations without clinical relevance were common. No signs of renal dysfunction or ototoxicity were observed. One patient with a preexisting peripheral neuropathy showed some progression of the neuropathy after a cumulative dose of 1605 mg/m2. Except for fever and transient liver dysfunction, no liposome related side effects were observed in spite of the high doses of lipid administered. The blood clearance of L-NDDP fits a two-compartment model at lower doses and a single-compartment model at the maximum tolerated dose, suggesting that saturation of the reticuloendothelial organs occurs at the maximum tolerated dose. Two minimal responses were observed. L-NDDP has a toxicity profile similar to that of carboplatin. Phase II studies to address the issue of how the therapeutic index of platinum compounds is affected by liposome entrapment are being planned.

Effect of carboplatin combined with whole body hyperthermia on normal tissue and tumor in rats.

The antitumor activity and normal tissue toxicity of cis-diammine-1,1-cyclobutane dicarboxylate platinum (II) (carboplatin) in combination with whole body hyperthermia (WBH) (41.5 degrees C, 120 min.) were examined in an F344 rat model. Carboplatin data were compared with those of cis-diamminedichloroplatinum (II) (cisplatin). At 37 degrees C, carboplatin showed minimal activity against a rat fibrosarcoma, but when combined with WBH, the antitumor effect-of the drug was greatly enhanced. The major carboplatin-induced acute toxicity at both normothermic and hyperthermic temperatures was marked hypocellularity of the bone marrow. A significant decrease in peripheral blood platelet counts was caused by the maximum tolerated doses (MTD) of carboplatin alone and with WBH. While the lethal dose of carboplatin alone caused only minimal renal damage, mild acute tubular necrosis was observed at the MTD of carboplatin with WBH, although no significant increase in blood urea nitrogen occurred. Therapeutic ratios of the combined chemotherapy and WBH modalities were calculated by comparing tumor growth response at the MTD of drug alone and drug combined with WBH. The combination of the nephrotoxic cisplatin with WBH resulted in a therapeutic ratio of only 0.8, whereas when carboplatin was combined with WBH, a value of 3.0 was obtained, representing a 3- to 4-fold increase over cisplatin in the therapeutic ratio. These data indicate that the less nephrotoxic carboplatin in combination with WBH improves therapeutic gain and may provide a more promising clinical combination for cancer treatment than cisplatin combined with WBH.

Bimodal effects of 1R,2R-diaminocyclohexane(trans-diacetato)(dichloro)platinum(IV) on cell cycle checkpoints.

1R,2R-Diaminocyclohexane(trans-diacetato)(dichloro)-platinum(IV) (DACH-acetato-Pt) is a novel platinum-based agent that is highly effective against cisplatin-resistant ovarian tumor cells. To probe its cellular mechanism, the effects of DACH-acetato-Pt (0-6.4 microM) on cell cycle checkpoints were examined using the ovarian cancer A2780 cell line as the model system. We found that DACH-acetato-Pt at > or =0.2 microM dramatically inhibited cell growth and induced cell death. At concentrations < or =0.6 microM (low effective concentrations), DACH-acetato-Pt specifically induced G(1) phase arrest by selectively inhibiting cyclin-dependent kinase 4 (Cdk4) and Cdk2 activities. The Cdc2 activity, which regulates G(2)-M phase progression, was unaffected by the drug at these concentrations. At concentrations >0.6 microM (high effective concentrations), DACH-acetato-Pt first transiently inhibited S-phase progression and then blocked cell cycle progression at both G(1) and G(2) phases. These cell cycle effects were associated with sequential inhibitions of Cdk2/cyclin A activity, Cdk4 and Cdk2 activities, and Cdc2 kinase activity. Following the cell cycle effects, both the low and high effective concentrations of DACH-acetato-Pt induced cell death through apoptosis. These results indicate that DACH-acetato-Pt activates multiple cell cycle checkpoints in a bimodal manner and suggest that the cell cycle effects demonstrated in these studies may be linked to its ability to induce apoptosis.

Expression of p53 in cisplatin-resistant ovarian cancer cell lines: modulation with the novel platinum analogue (1R, 2R-diaminocyclohexane)(trans-diacetato)(dichloro)-platinum(IV).

The compound (1R,2R-diaminocyclohexane)(transdiacetato)(dichloro)platinum(IV) (DACH-acetato-Pt) is a novel platinum-based antitumor agent with clinical potential against cisplatin-resistant disease that is under development in our laboratory. In view of the central role of the wild-type p53 tumor suppressor gene in drug-induced apoptosis, we evaluated the cytotoxicity of cisplatin and DACH-acetato-Pt in a panel of cisplatin-resistant ovarian tumor models with differing p53 status. Cisplatin was relatively more effective against mutant or null p53 cell lines (continuous drug exposure IC50, 1.2-3.3 microM) than it was against those harboring wild-type p53 (IC50, 2.8-9.9 microM). In contrast, DACH-acetato-Pt was considerably more active in wild-type p53 models (IC50, 0.17-1.5 microM) than it was in mutant or null models (IC50, 2.7-11.3 microM). Inactivation of wild-type p53 function in OVCA-429 cells by the human papillomavirus type 16 (HPV 16) E6 plasmid increased resistance to DACH-acetato-Pt by 3-5-fold, which confirmed the drug's dependence on wild-type p53 for its high cytotoxic potency. Differences between the two platinum agents were also evident in cell cycle studies: cisplatin arrested both wild-type and mutant p53 cells in G2-M, whereas DACH-acetato-Pt arrested wild-type p53 cells in G1 and mutant p53 cells in G2-M. The G1 arrest by DACH-acetato-Pt was abrogated in HPV 16 E6 transfectant clones of OVCA-429 cells. In agreement with effects on cell cycle progression, a 2-h pulse exposure to low concentrations (< or =25 microM) of DACH-acetato-Pt induced marked increases in p53 and p21Waf1/Cip1 expression in OVCA-429 cells. Cisplatin, in direct contrast, had no effect on expression of p53 or p21Waf1/Cip1 until the drug concentration was increased to 125 microM. In HPV 16 E6 transfectants of OVCA-429 cells, induction of p53 by the two agents was severely attenuated, and corresponding increases in p21Waf1/Cip1 were abrogated. This suggests that p21Waf1/Cip1 increases were p53 dependent. Collectively, the results demonstrate that DACH-acetato-Pt is very distinct from cisplatin. In particular, the greater activity of DACH-acetato-Pt in cisplatin-resistant wild-type p53 ovarian tumor models can be ascribed to its ability to more efficiently induce p53 protein and activate p53 functions.

Phase I clinical and pharmacological study of liposome-entrapped NDDP administered intrapleurally in patients with malignant pleural effusions.

cis-Bis-neodecanoato-trans-R,R-1,2-diaminocyclohexane platinum(II) (NDDP) is a lipophilic non-cross-resistant platinum compound formulated in large multilamellar liposomes (1-3 micrometer). The maximum tolerated dose (MTD) of liposomal-entrapped NDDP (L-NDDP) administered i.v. in humans is 300 mg/m2, and myelosuppresion is the dose-limiting toxicity. L-NDDP administered i.p. is absorbed slowly from the peritoneal cavity of rats. Recently, i.p. cisplatin has been shown to be superior to i.v. cisplatin in improving the survival of patients with ovarian carcinoma and minimal residual disease. We conducted a Phase I study to determine the MTD, side effects, kinetics of absorption into the systemic circulation, and preliminary antitumor activity of L-NDDP administered intrapleurally in patients with free-flowing malignant pleural effusions. Twenty-one patients were treated with escalating doses of L-NDDP by intrapleural administration over 30 min every 21 days. Fourteen patients had adenocarcinoma of the lung, 5 patients had malignant pleural mesothelioma (MPM), and 2 patients had ovarian carcinoma. The dose-limiting toxicity of L-NDDP was chest pain secondary to chemical pleuritis, which was severe in three of four patients treated at 550 mg/m2. The MTD was 450 mg/m2. At this dose, the only toxicity observed was grade 1-2 nausea and vomiting presenting 6-8 h after drug administration. Neither myelosuppression nor nephrotoxicity was observed. Loculation of residual pleural fluid with continued decrease over a period of weeks to months was observed in seven patients; in one of these patients (MPM), the pleural effusion disappeared without evidence of recurrence for 19 + months, and in six patients (three adenocarcinoma of the lung, two MPM, and one ovarian carcinoma), the pleural effusion was reduced by >50% for 5+, 10+, 18+, 8, 5+, and 2+ months. Plasma pharmacokinetic studies showed that the absorption of L-NDDP from the pleural cavity was rapid during the first 2 h, with levels becoming steady (bioavailable or free platinum) or increasing slowly (total plasma platinum) between 6 and 24 h after administration. Urinary excretion was negligible (1-3%). We conclude that: (a) the MTD of intrapleural L-NDDP is 50% higher than the MTD after i.v. administration; (b) intrapleural L-NDDP causes mild nausea and vomiting and no myelosuppression at the MTD; and (c) the absorption of L-NDDP into the systemic circulation is much slower than that of the parent compound cisplatin. Because of the favorable depot effect, lack of systemic toxicity, and control of the pleural effusion in three of five patients with MPM, a disease similar to ovarian carcinoma in that it tends to remain confined to a body cavity, a Phase II study of intrapleural L-NDDP administered in patients with MPM is in progress.