Mammalian NAD(P)H:quinone oxidoreductase (NQO1, DT-diaphorase, EC 1.6.99.2) catalyzes the two-electron reduction of quinones and plays one of the main roles in the bioactivation of quinoidal drugs. In order to understand the enzyme substrate specificity, we have examined the reactions of rat NQO1 with a number of quinones with available potentials of single-electron (E(1)(7)) reduction and pK(a) of their semiquinones. The hydride transfer potentials (E(7)(H(-))) were calculated from the midpoint potentials of quinones and pK(a) of hydroquinones. Our findings imply that benzo- and naphthoquinones with a van der Waals volume (VdWvol) < or = 200 A(3) are much more reactive than glutathionyl-substituted naphthoquinones, polycyclic quinones, and FMN (VdWvol>200 A(3)) with the same reduction potentials. The entropies of activation (DeltaS(not equal)) in the reduction of "fast" oxidants are equal to -84 to -76 J mol(-1) K(-1), whereas in the reduction of "slow" oxidants Delta S(not equal)=-36 to -11 J mol(-1) K(-1). The large negative Delta S(not equal) in the reduction of fast oxidants may be explained by their better electronic coupling with reduced FAD or the formation of charge-transfer complexes, since fast oxidants bind at the dicumarol binding site, whereas the binding of some slow oxidants outside it has been demonstrated. The reactivity of quinones may be equally well described in terms of the three-step (e(-),H(+),e(-)) hydride transfer, using E(1)(7), pK(a)(QH*), and VdWvol as correlation parameters, or in terms of single-step (H(-)) hydride transfer, using E(7)(H(-)) and VdWvol in the correlation. The analysis of NQO1 reactions with single-electron acceptors and quinones using an "outer-sphere" electron transfer model points to the possibility of a three-step hydride transfer.