Role of the glutathione S -transferase P1 (GSTP1) electrophile binding site (H-site) in protection from doxorubicin -mediated cytotoxicity

The hypothesis addressed in this project was that novel variants of naturally occurring human glutathione S-transferase P1 (GSTP1) can be created by random mutagenesis of the GSTP1 active site to yield polypeptides with increased enzymatic activity against electrophilic substrates. Specifically, the mutant proteins would metabolize and inactivate selected electrophiles more efficiently than wild-type GSTP1 and confer significant cytoprotection, as measured by reduced apoptosis and increased clonogenic survival. Glutathione S-transferase P1, a major electrophile metabolizing and detoxifying enzyme, is encoded by a polymorphic genetic locus. This locus contains nucleotide transitions in the region encoding the active site of the peptide that yields proteins with significant structural and functional differences. The method of Degenerate Oligonucleotide Mediated Random Mutagenesis (DOMRM) was used to generate cDNAs encoding unique GSTP1 polypeptides with mutations within electrophile binding site (H-site) while leaving the glutathione binding site unaffected. A prokaryotic expression library of the mutant GSTP1 polypeptides was created and screened for increased resistance to cisplatin. This screen resulted in the isolation of 96 clones representing 22 distinct mutant cDNA sequences. To investigate the effects of the changes in the H-site on the biological activity of GSTP1, the cDNA of wild-type GSTP1c and two of the identified mutants were stably transfected into human LNCaP-Pro5 prostate cancer cells that do not endogenously express GSTP1. Wild-type transfectants were resistant to doxorubicin-induced apoptosis and displayed increased clonogenic survival compared to vector controls. However, contrary to the hypothesis, in both assays the mutant transfectants were no more resistant to doxorubicin than the wild-type transfectants. To elucidate the mechanisms underlying GSTP1-mediated survival, an in-vitro assay was developed to determine whether active GSTP1 protein directly metabolizes doxorubicin by conjugation to reduced glutathione (GSH). Although GSH did promote the appearance of a unique doxorubicin conjugate, conjugate formation was not substantially increased by the addition of GSTP1 in a variety of reaction conditions. ^

IN VITRO METABOLISM OF 6-THIOGUANINE IN RAT SUBCELLULAR FRACTIONS

The metabolism of the antitumor agent 6-thioguanine (TG, NSC-752) by rat liver was studied in vitro. Livers from adult male Sprague-Dawley rats were homogenized and the "liver homogenate" was subjected to differential centrifugation to obtain the "10,000 x g pellet", the "post-mitochondrial fraction", the "cytosol fraction", and the "microsomes". The homogenity of each fraction was estimated by appropriate marker enzyme assays. To delineate the in vitro metabolism of TG by rat liver, 0.2 mM of {8-('14)C}TG was incubated with different subcellular fractions in KCl-Tris-MgCl(,2) buffer, pH 7.4 at 37(DEGREES). The metabolites formed were identified by chromatography, UV spectrometry, as well as mass spectrometry. After a 1 hr incubation, TG was metabolized by the liver homogenate, the 10,000 x g pellet and the post-mitochondrial fraction mainly to 6-thioguanosine (TGR), accompanied by varying lesser amounts of 6-thiouric acid (TUA), allantoin, guanine-6-sulfinic acid (G-SO(,2)H) and an unknown product. In comparison, the cytosal fraction converted TG almost entirely to TGR and TUA in equal amounts. The formation of TGR from TG was limited by the endogenous supply of ribose-1-phosphate. With the microsomal fraction, however, TG was metabolized significantly to G-SO(,2)H and the unknown, accompanied with some TGR. After a 5 hr incubation the metabolism of TG was changed to favor the catabolic route, yielding mostly TUA in the post-mitochondrial and cytosol fractions; but mainly allantoin in the liver homogenate fraction. The kinetic studies of TG metabolism by the subcellar fractions indicated that the formation of TGR served as a depot form of TG. The level of TGR decreased when the catabolism of TG became prominent. The oxidation of TG to GSO(,2)H mediated by the hepatic microsomes represented a new catabolic pathway of TG. This GSO(,2)H, under acidic conditions, readily decomposes to guanine and inorganic sulfate. In the presence of reduced glutathione in Tris buffer, pH 7.8 at 25(DEGREES), GSO(,2)H is adducted to glutathione chemically to form S-(2-amino-purin-6-yl) glutathione and conceivably, inorganic sulfate. Therefore, the formation of GSO(,2)H from TG might have implication in the desulfuration mechanism of TG. On the other hand, the unknown formed from TG by the action of the microsomal enzymes appeared to be a TG conjugate. However, it is neither a glutathione, a glucuronide, nor a ribose conjugate. Additionally, the deamination of TG by guanine deaminase (E.C.3.5.4.3) isolated from rat liver was also investigated. TG is a poorer substrate (Km = 4.8 x 10('-3)M) for guanine deaminase than that of guanine (Km = 4.7 x 10('-6)M) at pH 7.25, optimal pH for TG as a substrate. TG is also a competitive inhibitor of guanine for guanine deaminase, with a ki of 2.2 x 10('-4)M. ^