RESUMO
3ß-Hydroxysteroid dehydrogenase type 1 (3ß-HSD1) is selectively expressed in human placenta, mammary glands and breast tumors in women. Human 3ß-HSD2 is selectively expressed in adrenal glands and ovaries. Based on AutoDock 3 and 4 results, we have exploited key differences in the amino acid sequences of 3ß-HSD1 (Ser194, Arg195) and 3ß-HSD2 (Gly194, Pro195) by designing a selective inhibitor of 3ß-HSD1. 2,16-Dicyano-4,5-epoxy-androstane-3,17-dione (16-cyano-17-keto-trilostane or DiCN-AND) was synthesized in a 4-step procedure from androstenedione. In purified 3ß-HSD inhibition studies, DiCN-AND competitively inhibited 3ß- HSD1 with Ki=4.7µM and noncompetitively inhibited 3ß-HSD2 with a 6.5-fold higher Ki=30.7µM. We previously reported similar isoenzyme-specific inhibition profiles for trilostane. Based on our docking results, we created, expressed and purified the chimeric S194G-1 mutant of 3ß-HSD1. Trilostane inhibited S194G-1 (Ki=0.67µM) with a noncompetitive mode compared to its 6.7-fold higher affinity, competitive inhibition of 3ß-HSD1 (Ki=0.10µM). DiCN-AND inhibited S194G-1 with a 6.3-fold higher Ki (29.5µM) than measured for 3ß-HSD1 (Ki=4.7µM) but with the same competitive mode for both enzyme species. Since DiCN-AND noncompetitively inhibits 3ß-HSD2, which has the Gly194 and Pro195 of 3ß-HSD2 in place of the Ser194 and Arg195 in 3ß-HSD1, this suggests that Arg195 alone in 3ß-HSD1 or S194G-1 is required to bind DiCN-AND in the substrate binding site (competitive inhibition). However, both Ser194 and Arg195 are required to bind trilostane in the 3ß-HSD1 substrate site based on its noncompetitive inhibition of S194G-1 and 3ß-HSD2. In support of this hypothesis, DiCN-AND inhibited our chimeric R195P-1 mutant noncompetitively with a Ki=41.3µM (similar to the 3ß-HSD2 inhibition profile). Since DiCN-AND competitively inhibited S194G-1 that still contains R195 but noncompetitively inhibited R195P-1 that still contains S194, our data provides strong evidence that the Arg195 being mutated to Pro195 (as present in 3ß-HSD2) shifts the inhibition mode from competitive to noncompetitive in 3ß-HSD1. This supports the key role of Arg195 in 3ß-HSD1 for the high affinity, competitive binding of the trilostane analogs. Our new structure/function information for the design of targeted 3ß-HSD1 inhibitors may lead to important new treatments for the prevention of spontaneous premature birth.