ConspectusThis Account presents the development of a suite
of stereospecific
alkyl–alkyl cross-coupling reactions employing nickel catalysts.
Our reactions complement related nickel-catalyzed stereoconvergent
cross-coupling reactions from a stereochemical and mechanistic perspective.
Most reactions of alkyl electrophiles with low-valent nickel complexes
proceed through alkyl radicals and thus are stereoablative; the correct
enantioselective catalyst can favor the formation of one enantiomer.
Our reactions, in contrast, are stereospecific. Enantioenriched ethers
and esters are cleanly converted to cross-coupled products with high
stereochemical fidelity. While mechanistic details are still to be
refined, our results are consistent with a polar, two-electron oxidative
addition that avoids the formation of radical intermediates. This
reactivity is unusual for a first-row transition metal.The
cross-coupling reactions engage a range of benzylic ethers
and esters, including methyl ethers, tetrahydropyrans, tetrahydrofurans,
esters, and lactones. Coordination of the arene substituent to the
nickel catalyst accelerates the reactions. Arenes with low aromatic
stabilization energies, such as naphthalene, benzothiophene, and furan,
serve as the best ligands and provide the highest reactivity. Traceless
directing groups that accelerate reactions of sluggish substrates
are described, providing partial compensation for arene coordination.Kumada, Negishi, and Suzuki reactions provide incorporation of
a broad range of transmetalating agents. In Kumada coupling reactions,
a full complement of Grigard reagents, including methyl, n-alkyl, and aryl Grignard reagents, are employed. In reactions employing
methylmagnesium iodide, ligation of the nickel catalyst by rac-BINAP or DPEphos provides the highest yield and stereospecificity.
For all other Grignard reagents, Ni(dppe)Cl2 has emerged
as the best catalyst. Negishi cross-coupling reactions employing dimethylzinc
are reported as a strategy to increase the functional group tolerance
of the reaction. We also describe Suzuki reactions using arylboronic
esters. These reactions provided the first example in the series of
a switch in stereochemical outcome. The reactions maintain stereospecificity,
but reactions employing different achiral ligands provide opposite
enantiomers of the product. Use of an N-heterocyclic carbene ligand,
SIMes, provides inversion, consistent with our prior work in Kumada
and Negishi coupling reactions. Use of the electron-rich phosphine
PCy3, however, provides retention with stereospecificity,
signaling a change in the mechanistic details.Potential applications
of the reported cross-coupling reactions
include the synthesis of medicinal agents containing the 2-arylalkane
and 1,1-diarylalkane moieties, which are pharmacophores in medicinal
chemistry. These moieties are found in compounds with activity against
a broad range of indications, including cancer, heart disease, diabetes,
osteoporosis, smallpox, tuberculosis, and insomnia. We highlight representative
exa...
