Biotransformation of the platinum drug JM216 following oral administration to cancer patients

Raynaud, Florence I.; Mistry, Prakash; Donaghue, A.; Poon, Grace K.; Kèlland, Lloyd R.; Barnard, Christopher F. J.; Murrer, Barry A.; Harrap, K. R.

doi:10.1007/s002800050464

Cited by 108 publications

(78 citation statements)

References 16 publications

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“…Our results show that some metabolites previously observed in patients' plasma ultrafiltrates can be observed intracellularly; those being A, JM383, D and JM 118 (Raynaud et al, , 1996. However, JM216 itself was never detected in patients' plasma ultrafiltrates and a late eluting metabolite F was not seen intracellularly and no JM559 could be measured.…”

Section: Resultsmentioning

confidence: 63%

“…Preclinical studies have shown that multiple administrations give the best anti-tumour responses (McKeage et al, 1994b) and this has been verified in patients, where multiple administrations could overcome the saturability in absorption observed in the single-dose study (McKeage et al, 1994c;Raynaud et al, 1995). It has been shown that JM216 is converted in patients' plasma into at least six different biotransformation complexes and that these biotransformation products are active in vitro and in vivo (Poon et al, 1995;Raynaud et al, 1996). Three of the metabolites present in patients have not yet been identified.…”

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confidence: 99%

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Intracellular metabolism of the orally active platinum drug JM216: influence of glutathione levels

Raynaud

Odell²,

Kelland³

1996

Br J Cancer

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Summary JM216 (bis-acetato ammine dichloro cyclohexylamine Pt IV) is an oral platinum complex presently undergoing phase II clinical trials. Previous studies have identified some of its biotransformation products in clinical materials. This study evaluated the nature of JM216 biotransformation products intracellularly in two different human ovarian carcinoma cell lines, one relatively sensitive to platinum agents (CH1: JM216 4 h IC50 of 5.8 gM) and the other relatively resistant (SKOV3: JM216 4 h IC50 of 60.7 gM). Metabolic profiles were also evaluated at different growth status and in cells pretreated with buthionine sulphoximine (BSO), an agent known to decrease intracellular glutathione levels. Results showed that JM216 enters the cells and that the nature and percentage of biotransformation products was dependent upon glutathione levels. Furthermore, results support the view that the previously reported peak A biotransformation product contains a glutathione adduct. In exponentially growing SKOV3 cells which contain higher glutathione levels than CHI, (82.5 vs 37.8 nmol mg-' protein), peak A represented 89% of total platinum 4 h after JM216 exposure compared with only 24% in CHI. Moreover, 60-70% depletion of glutathione achieved by 24 h pretreatment of cells with BSO resulted in a significant decrease in peak A in both cell lines and increased the cytotoxicity of JM216 in both CHI and SKOV3 by approximately 2-fold. Following a 4 h exposure of exponentially growing SKOV3 cells to JM216, only peak A (89%) and JM216 (11%) could be detected whereas in CHI cells, peak A (24%), JM216 (73%) and JM118 [cis-ammine dichloro (cyclohexylamine) platinum II] (3%) were detected. However, in CH1 cells at confluence, where glutathione is lower (8 nmol mg-' protein) four metabolites (plus JM216 itself) were detected following exposure to 50 tM JM216; peak A, JM1 18, JM383 (bis-acetato ammine (cyclohexylamine) dihydroxy platinum IV) and an unidentified metabolite (D), also observed in patient's plasma ultrafiltrate. In confluent SKOV3 cells exposed to 50 pM JM216, peak A, JM216 and JM1 18 were detected. A further unidentified metabolite observed in patients receiving JM216 (metabolite F) was not formed inside these tumour cells. Overall, these data suggest that glutathione conjugation represents a major deactivation pathway for JM216.

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Section: Resultsmentioning

confidence: 63%

mentioning

confidence: 99%

Intracellular metabolism of the orally active platinum drug JM216: influence of glutathione levels

Raynaud

Odell²,

Kelland³

1996

Br J Cancer

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“…Upon administration of satraplatin, a number of metabolites (JM118, JM383, JM518, JM559 and JM149) are formed [43]. Satraplatin and other platinum-based compounds exhibit anti-tumour activity via the formation of DNA crosslinks in vitro [44] which in turn results in specific cellular responses, namely, apoptosis and inhibition of transcription leading to arrest of cell replication [45][46][47].…”

Section: Discussionmentioning

confidence: 99%

<i>In Vitro</i> Investigation of DNA Damage Induced by the DNA Cross-Linking Agents Oxaliplatin and Satraplatin in Lymphocytes of Colorectal Cancer Patients

Alotaibi¹,

Baumgartner²,

Najafzadeh³

et al. 2012

JCT

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Exposure to toxic chemicals, especially chemotherapeutic drugs, may induce several DNA lesions, including DNA interstrand crosslinks. These crosslinks are considered toxic lesions to the dividing cells since they can induce mutations, chromosomal rearrangements, and cell death. Many DNA interstrand crosslinks lesions can be generated by platinum-based chemotherapeutic agents. Satraplatin is a novel orally administered platinum-based chemotherapeutic agent. In the present study, we investigated DNA interstrand crosslinks lesions induced by oxaliplatin and satraplatin in lymphocytes obtained from colorectal cancer patients and healthy volunteers. Satraplatin demonstrated an increase in interstrand crosslinks in a dose-dependent manner in the Comet assay (p < 0.001). In addition, satraplatin and oxaliplatin increased significantly the number of sister chromatid exchanges up to 8.5-fold and 5.1-fold (p < 0.001) respectively, when treated with 2 µM concentration in comparison to untreated colorectal cancer cells. Further, the γH2AX foci formation was investigated by an immunofluorescence assay with oxaliplatin and satraplatin. The γH2AX foci formation rate was increased by approximately 9-fold when lymphocytes were treated with 2 μM oxaliplatin. Satraplatin was found to significantly induce the number of γH2AX foci by 8.5-fold and 11-fold with both 0.2 μM and 2.0 μM, respectively, compared to the control volunteers that may indicate the repair system in cancer cells experiences a loss of ability to cope with the repair of DSBs. In conclusion, oxaliplatin and satraplatin effectively induced DNA interstrand crosslinks in lymphocytes obtained from colorectal cancer patients and healthy volunteers in vitro. Here, to the best of our knowledge we report for the first time evidence of DNA double strand breaks formation as a possible molecular mechanism of action for satraplatin.

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“…It also gives confidence that the exposure achieved in man (and therefore potential anticancer activity) is equivalent to that seen in the mouse models (Raynaud et al, 1997). In contrast to some other recently investigated novel platinum compounds such as satraplatin, AMD473 is not subject to extensive degradative metabolism (McKeage et al, 1995;Raynaud et al, 1996;Judson et al, 2000).…”

Section: Discussionmentioning

confidence: 98%

A Phase I clinical and pharmacological study of cis-diamminedichloro(2-methylpyridine) platinum II (AMD473)

et al. 2003

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AMD473 is a novel sterically hindered platinum cytotoxic with demonstrated ability to overcome acquired resistance to cisplatin in vitro and in human tumour xenografts. A single-agent dose escalating Phase I study was performed. AMD473 was initially administered intravenously as a 1 h infusion every 21 days to patients with advanced solid tumours. In total, 42 patients received a total of 147 cycles (median 3, range 1 -8) of treatment at doses of 12, 24, 48, 96, 110, 120, 130, and 150 mg m À2 . Dosing intervals of 21 and 28 days were explored at the recommended dose. Neutropenia and thrombocytopenia proved dose limiting. Other toxicities included moderate nausea, vomiting, anorexia, and a transient metallic taste. There was no significant alopecia. The maximum tolerated dose was 150 mg m À2 . Plasma pharmacokinetics were linear. Two patients with heavily pretreated ovarian cancer showed partial response. Five patients (mesothelioma, ovary, nonsmall cell lung, and melanoma) showed prolonged stable disease. AMD473 demonstrates encouraging activity in patients, including those with prior platinum exposure. Toxicity is predictable with linear pharmacokinetics, as was predicted by preclinical studies. A dose of 120 mg m À2 every 21 days is recommended for Phase II evaluation although there is evidence that chemo-naive patients and those of good performance status may tolerate a higher dose.

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Biotransformation of the platinum drug JM216 following oral administration to cancer patients

Cited by 108 publications

References 16 publications

Intracellular metabolism of the orally active platinum drug JM216: influence of glutathione levels

Intracellular metabolism of the orally active platinum drug JM216: influence of glutathione levels

<i>In Vitro</i> Investigation of DNA Damage Induced by the DNA Cross-Linking Agents Oxaliplatin and Satraplatin in Lymphocytes of Colorectal Cancer Patients

A Phase I clinical and pharmacological study of cis-diamminedichloro(2-methylpyridine) platinum II (AMD473)

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Biotransformation of the platinum drug JM216 following oral administration to cancer patients

Cited by 108 publications

References 16 publications

Intracellular metabolism of the orally active platinum drug JM216: influence of glutathione levels

Intracellular metabolism of the orally active platinum drug JM216: influence of glutathione levels

&lt;i&gt;In Vitro&lt;/i&gt; Investigation of DNA Damage Induced by the DNA Cross-Linking Agents Oxaliplatin and Satraplatin in Lymphocytes of Colorectal Cancer Patients

A Phase I clinical and pharmacological study of cis-diamminedichloro(2-methylpyridine) platinum II (AMD473)

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<i>In Vitro</i> Investigation of DNA Damage Induced by the DNA Cross-Linking Agents Oxaliplatin and Satraplatin in Lymphocytes of Colorectal Cancer Patients