Abstract
Hydroxysteroid dehydrogenases (HSDs) are essential for the biosynthesis and mechanism of action of all steroid hormones. We report the complete kinetic mechanism of a mammalian HSD using rat 3alpha-HSD of the aldo-keto reductase superfamily (AKR1C9) with the substrate pairs androstane-3,17-dione and NADPH (reduction) and androsterone and NADP(+) (oxidation). Steady-state, transient state kinetics, and kinetic isotope effects reconciled the ordered bi-bi mechanism, which contained 9 enzyme forms and permitted the estimation of 16 kinetic constants. In both reactions, loose association of the NADP(H) was followed by two conformational changes, which increased cofactor affinity by >86-fold. For androstane-3,17-dione reduction, the release of NADP(+) controlled k(cat), whereas the chemical event also contributed to this term. k(cat) was insensitive to [(2)H]NADPH, whereas (D)k(cat)/K(m) and the (D)k(lim) (ratio of the maximum rates of single turnover) were 1.06 and 2.06, respectively. Under multiple turnover conditions partial burst kinetics were observed. For androsterone oxidation, the rate of NADPH release dominated k(cat), whereas the rates of the chemical event and the release of androstane-3,17-dione were 50-fold greater. Under multiple turnover conditions full burst kinetics were observed. Although the internal equilibrium constant favored oxidation, the overall K(eq) favored reduction. The kinetic Haldane and free energy diagram confirmed that K(eq) was governed by ligand binding terms that favored the reduction reactants. Thus, HSDs in the aldo-keto reductase superfamily thermodynamically favor ketosteroid reduction.
Highlights
Hydroxysteroid dehydrogenases (HSDs) are essential for the biosynthesis and mechanism of action of all steroid hormones
We report the complete kinetic mechanism of a mammalian HSD using rat 3␣-HSD of the aldo-keto reductase superfamily (AKR1C9) with the substrate pairs androstane-3,17-dione and NADPH and androsterone and NADP؉
Rat liver 3␣-HSD (AKR1C9), which shares 69% sequence identity with its human homologs, represents the best system to relate structure to function for HSDs, because crystal structures exist for the apoenzyme (E) [18], the E1⁄7NADPϩ binary complex [19], and the E1⁄7NADPϩ1⁄7testosterone ternary complex [20]
Summary
Hydroxysteroid dehydrogenases (HSDs) are essential for the biosynthesis and mechanism of action of all steroid hormones. Four human HSDs from the AKR superfamily, AKR1C1– AKR1C4, can reduce 3-, 17-, and 20-ketosteroids in different ratios [14, 15] They catalyze the 4-pro-R hydride transfer from NADPH to the acceptor carbonyl on the steroid substrate in an ordered bi-bi reaction where NAD(P)(H) binds first and leaves last [16, 17]. Rat liver 3␣-HSD (AKR1C9), which shares 69% sequence identity with its human homologs, represents the best system to relate structure to function for HSDs, because crystal structures exist for the apoenzyme (E) [18], the E1⁄7NADPϩ binary complex [19], and the E1⁄7NADPϩ1⁄7testosterone ternary complex (where testosterone is a competitive inhibitor) [20] These “snapshots” of the enzyme along the reaction pathway reveal that significant conformational changes occur upon the binding of each ligand and provide a structural basis for the ordered bi-bi mechanism (Fig. 1). Portions of loop structures are colored for the apoenzyme (A), for the binary complex (B), and for the ternary complex (C) according to the following scheme: loop The E1⁄7NADPϩ
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