Estrogen platinum-diamine complexes: preparation of a non-steroidal estrogen platinum-diamine complex labeled with platinum-191 and a study of its binding to the estrogen receptor in vitro and its tissue distribution in vivo.

We have prepared in radiolabeled form (platinum-191) a non-steroidal estrogen platinum-diamine complex (Pt-diamine complex) that is reported to have selective cytostatic activity in estrogen receptor positive mouse mammary tumors. We then studied the interaction of this metal radiolabeled complex with the estrogen receptor in vitro and its distribution in immature rats in vivo. The radiolabeled complex was prepared by incubation of the non-steroidal estrogen diamine with [191Pt](II)Cl(-2)4 (t 1/2 = 2.96 days, sp. act. 7.54 Ci/mmol) in dimethylformamide (DMF)/H2O, followed by purification by HPLC. The final radiolabeled product coeluted with an authentic standard of the unlabeled Pt-diamine complex, with a retention time distinct from those of the precursor diamine and chloroplatinate. In competitive radiometric receptor binding assays with rat uterine estrogen receptor, samples of the unlabeled diamine and Pt-diamine complex have apparent binding affinities of 53 +/- 3% and 32 +/- 11%, respectively, relative to estradiol (RBA = 100% as standard). However, attempts to observe the binding of the 191Pt-diamine complex with the estrogen receptor were complicated by a very high level of non-receptor binding, an irreversible binding to proteins in the receptor preparation, and a degradation of the platinum complex that, in part, releases the diamine. As a result, it is difficult to be certain whether the binding affinity measured for the Pt-diamine complex in the competitive binding assays is due to the complex itself, or whether it arises from diamine released upon degradation of the complex. In tissue distribution studies in immature female rats, much of the 191Pt-diamine complex was deposited in the liver; there was no evidence of selective uptake of this compound by estrogen target tissues. Thus, it is not clear, from these studies, that the observed bioactivity of this complex arises from the interaction of the Pt complex or the diamine ligand with the estrogen receptor.

Technetium- and rhenium-labeled progestins: synthesis, receptor binding and in vivo distribution of an 11 beta-substituted progestin labeled with technetium-99 and rhenium-186.

In an effort to develop radiopharmaceuticals useful for the diagnostic imaging of steroid receptor-positive breast tumors, we have radiolabeled an analog of the antiprogestin RU486 (mifepristone), modified to incorporate an N2S2 chelate system in the 11 beta-position, with 99Tc, 99mTc, and 186Re. For the 99Tc-labeled analogs (3), a syn pair and two individual antidiastereomers (linker methylene versus metal-oxo, relative to the N2S2 plane) were isolated. In competitive radiometric binding assays, the syn pair (3syn1,2) had affinity for the progesterone receptor that was 25% that of (promegestone) R5020 (or 161% that of progesterone), and the individual anti-diastereomers had affinities of 47% (3anti1) and 7% (3anti2) that of R5020 (or 303% and 45% that of progesterone). The specific-to-nonspecific binding ratio of the 99mTc (4) and 186Re (5) 11 beta-linked syn systems are 75/25 and 54/46, respectively. In vivo, conjugates 4 and 5 showed progesterone receptor-mediated uptake in rat uterus, but also high uptake in non-target tissues, presumably because of the high lipophilicity of the metal complexes. Modified systems may be useful in vivo as receptor-directed agents for diagnostic imaging or treatment of steroid receptor-positive tumors.

Progestin-rhenium complexes: metal-labeled steroids with high receptor binding affinity, potential receptor-directed agents for diagnostic imaging or therapy.

In order to investigate the possibility of developing diagnostic imaging agents for steroid-positive tumors that are labeled with the readily available radionuclide technetium-99m, we prepared four conjugate systems in which a progestin is linked to a metal chelate system. Three of these are bis-amino bis-thiol (BAT or N2S2) systems and are linked through carbon-21 of progesterone or the 17 alpha- or 11 beta-position of a nortestosterone type progestin. The fourth, an amino-amido-thiol-alcohol chelate (N2OS) system, is linked at the 16 alpha,17 alpha-positions of a dihydroprogesterone. As a model for technetium-labeled complexes, all four chelate systems were converted to their oxo-rhenium complexes. Of the four possible diastereomers in the 16 alpha,17 alpha-system, only one was isolated, while of the four possible diastereomers in the other systems, a syn pair and an anti pair (linker methylene vs rhenium-oxo, relative to the N2S2 plane) were separated in the 17 alpha-substituted series, a syn pair was isolated in the 21-substituted series, and a syn pair and the two individual anti diastereomers were separated in the 11 beta-substituted series. In competitive radiometric receptor binding assays, the 21-, 17 alpha-, and 16 alpha,17 alpha-linked systems had low affinity for the progesterone receptor (less than 0.3% that of promegestone (R5020) or 2% that of progesterone). By contrast, the two anti diastereomers of the 11 beta-linked system had affinities that were 10% and 44% that of R5020 (or 64% and 283% that of progesterone) and the syn pair had an affinity 25% that of R5020 (or 161% that of progesterone). The latter finding indicates that it is possible to prepare metal-labeled steroids that retain high affinity for steroid receptors. These and related systems, when complexed with radioactive metals, may be useful in vivo as receptor-directed agents for diagnostic imaging or therapy of steroid receptor-positive tumors.