The observed 1° isotope effect on 2° KIEs in H-transfer reactions has recently been explained on the basis of a H-tunneling mechanism that uses the concept that the tunneling of a heavier isotope requires a shorter donor-acceptor distance (DAD) than that of a lighter isotope. The shorter DAD in D-tunneling, as compared to H-tunneling, could bring about significant spatial crowding effect that stiffens the 2° H/D vibrations, thus decreasing the 2° KIE. This leads to a new physical organic research direction that examines how structure affects the 1° isotope dependence of 2° KIEs and how this dependence provides information about the structure of the tunneling ready states (TRSs). The hypothesis is that H- and D-tunneling have TRS structures which have different DADs, and pronounced 1° isotope effect on 2° KIEs should be observed in tunneling systems that are sterically hindered. This paper investigates the hypothesis by determining the 1° isotope effect on α- and β-2° KIEs for hydride transfer reactions from various hydride donors to different carbocationic hydride acceptors in solution. The systems were designed to include the interactions of the steric groups and the targeted 2° H/D's in the TRSs. The results substantiate our hypothesis, and they are not consistent with the traditional model of H-tunneling and 1°/2° H coupled motions that has been widely used to explain the 1° isotope dependence of 2° KIEs in the enzyme-catalyzed H-transfer reactions. The behaviors of the 1° isotope dependence of 2° KIEs in solution are compared to those with alcohol dehydrogenases, and sources of the observed "puzzling" 2° KIE behaviors in these enzymes are discussed using the concept of the isotopically different TRS conformations.
The secondary kinetic isotope effects for the hydride transfer reactions from aliphatic alcohols to two carbocations (NAD(+) models) in acetonitrile were determined. The results suggest that the hydride transfer takes place by tunneling and that the rehybridizations of both donor and acceptor carbons lag behind the H-tunneling. This is quite contrary to the observations in alcohol dehydrogenases where the importance of enzyme motions in catalysis is manifested.
We
recently reported abnormal secondary deuterium kinetic isotope
effects (2° KIEs) for hydride transfer reactions from alcohols
to carbocations in acetonitrile (Chem. Comm. 2012, 48, 11337). Experimental 2° KIE values were found to
be inflated on the 9-C position in the xanthylium cation but deflated
on the β-C position in 2-propanol with respect to the values
predicted by the semi-classical transition-state theory. No primary
(1°) isotope effect on 2° KIEs was observed. Herein, the
KIEs were replicated by the Marcus-like H-tunneling model that requires
a longer donor–acceptor distance (DAD) in a lighter isotope
transfer process. The 2° KIEs for a range of potential tunneling-ready-states
(TRSs) of different DADs were calculated and fitted to the experiments
to find the TRS structure. The observed no effect of 1° isotope
on 2° KIEs is explained in terms of the less sterically hindered
TRS structure so that the change in DAD due to the change in 1°
isotope does not significantly affect the reorganization of the 2°
isotope and hence the 2° KIE. The effect of 1° isotope on
2° KIEs may be expected to be more pronounced and thus observable
in reactions occurring in restrictive environments such as the crowded
and relatively rigid active site of enzymes.
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