Fu H,
Lam H,
Emmanuel MA,
Kim JH,
Sandoval BA,
Hyster TK.
*
Princeton University and Cornell University, Ithaca, USA
Ground-State Electron Transfer as an Initiation Mechanism for Biocatalytic C–C Bond
Forming Reactions.
J. Am. Chem. Soc. 2021;
143: 9622-9629
DOI:
10.1021/jacs.1c04334
Key words
hydroalkylation - alkenes - reductase - ground-state electron transfer - ketones
Significance
Hyster and co-workers report intra- and intermolecular reductive hydroalkylations
of aromatic olefins to form cyclopentanones or linear ketones in excellent yields
and enantioselectivities. Quadruply mutated or wild-type nicotinamide-dependent cyclohexanone
reductase (NCR), respectively, serve as efficient biocatalysts. Starting from α-bromo
ketones, ground-state electron transfer from a flavinmononucleotide generates a ketyl
radical that, through mesolytic C–Br bond cleavage, generates the reactive α-ketonyl
radical. Notably, whereas the stereocenter in the cyclization reaction is set in the
C–C bond-forming step, the enantiocontrol in intermolecular reactions originates from
a stereoselective radical-terminating hydrogen-atom transfer.
Comment
Flavin-dependent ene-reductases (EREDs) have been previously applied in photoenzymatic
settings (see, for example: K. F. Biegasiewicz et al. Science
2019, 364, 1166). Whereas those reactions rely on the photoexcitation of a charge-transfer
complex between enzyme, cofactor, and substrates, the analogous ground-state electron
transfer had not previously been utilized as an initiation mechanism in C–C bond-forming
reactions. The authors therefore selected α-bromo ketones as substrates due to their
relatively high reduction potential, rendering ground-state reactivity kinetically
feasible. Although the present method is an impressive example of enantiocontrol over
real radical intermediates, the extension to less-stabilized nonaromatic substrates
represents a considerable challenge for future research.
