posted on 2015-12-17, 01:43authored bySeoung-ryoung Choi, Martin Breugst, Kendall N. Houk, C. Dale Poulter
The biosynthetic pathways to isoprenoid
compounds involve transfer
of the prenyl moiety in allylic diphosphates to electron-rich (nucleophilic)
acceptors. The acceptors can be many types of nucleophiles, while
the allylic diphosphates only differ in the number of isoprene units
and stereochemistry of the double bonds in the hydrocarbon moieties.
Because of the wide range of nucleophilicities of naturally occurring
acceptors, the mechanism for prenyltransfer reactions may be dissociative
or associative with early to late transition states. We have measured δ-secondary
kinetic isotope effects operating through four bonds for substitution
reactions with dimethylallyl derivatives bearing deuterated methyl
groups at the distal (C3) carbon atom in the double bond under dissociative
and associative conditions. Computational studies with density functional
theory indicate that the magnitudes of the isotope effects correlate
with the extent of bond formation between the allylic moiety and the
electron-rich acceptor in the transition state for alkylation and
provide insights into the structures of the transition states for
associative and dissociative alkylation reactions.