The possible mechanisms by which the administration of drugs may alter the gonadal function in humans are considered in this review. Based on personal data, and on data published in the literature, the following events may occur: (1) blockade of gonadal steroidogenesis; (2) interaction of drug(s) with the steroid-binding protein system in plasma, and (3) interference of drug(s) at the level of the feedback control of gonadotropin secretion. Representative examples of the above mechanisms are as following: (1) Ketoconazole possesses inhibitory effects in vitro on cytochrome P-450. When given in adult males, it decreased the plasma concentrations of testosterone (T) and androstenedione and increased 17 alpha-hydroxyprogesterone levels, suggesting that this drug acts in vivo on gonadal steroidogenesis by blocking the 17,20-lyase. (2) Danazol is a progestagen with high affinity for sex steroid-binding protein (SBP); when given in high dosages in normal males, it increased rapidly the dialyzable fraction (percent protein unbound or free fraction) of T. This suggests that by interacting with the binding sites of SBP, danazol and/or its metabolites displace the fraction of T bound to SBP. However, in males as well as in females, the long-term administration of danazol decreased also the binding capacity of SBP, and consequently increased the free fraction of sex steroid hormones. (3) Dihydrotestosterone (DHT), the most active androgen in many target cells, given at therapeutic dosages to adult males, resulted in a decrease in plasma concentrations of luteinizing hormone (LH) and T, without any significant change in the percent of free T, even though the affinity of DHT for SBP is higher than that of T. This suggests that the main effect of DHT is to inhibit gonadotropin secretion at the central level. (4) Flutamide, a nonsteroidal antiandrogen, increased both LH and T levels, demonstrating its pure antiandrogenic activity on gonadotropin secretion. The consequence(s) of the effects of such drugs on the production, the metabolic clearance rate and the bioavailability of sex steroid hormones are discussed.