Human P450c17 catalyzes the 17alpha-hydroxylation of pregnenolone to 17OH pregnenolone and of progesterone to 17alpha-OH progesterone; the same P450c17 enzyme also catalyzes 17,20 lyase activity on the same active site, converting 17OH-pregnenolone to DHEA. Rodent and porcine P450c17 also catalyze 17,20 lyase activity with delta4 substrates, converting 17OH-progesterone to delta4 androstenedione, but human P450c17 catalyzes this reaction very inefficiently, so that virtually all human C19 sex steroids are made via 17OH pregnenolone and DHEA. P450c17 is encoded by a single gene and a single species of mRNA. Many mutations of this gene have been described, but until recently all of these either entirely eliminated both 17alpha-hydroxylase and 17,20 lyase activity, or affected each activity equivalently. We have identified and characterized the first patients with P450c17 mutations that selectively ablate 17,20 lyase activity while retaining 17alpha-hydroxylase activity. Through a combination of enyzmologic experiments in transfected mammalian cells and in genetically manipulated yeast, plus a computer model of human P450c17, we have proven that the responsible mutations, R347H and R358Q lie in the redox-partner binding site of P450c17. This site, through which P450c17 interacts with P450 oxidoreductase to receive the electrons needed for catalysis, can be allosterically influenced by cytochrome b5. These two mutations have contributed substantially to our understanding of the mechanisms by which 17alpha-hydroxylase and 17,20 lyase activities are regulated independently, and thus have contributed to the study of regulated 17,20 lyase activity in adrenarche, aging, and the polycystic ovary syndrome.