From the 19th century to the present, the complex indole alkaloid strychnine has engaged the chemical community. In this review, we examine why strychnine has been and remains today an important target for directed synthesis efforts. A selection of the diverse syntheses of strychnine is discussed with the aim of identifying their influence on the evolution of the strategy and tactics of organic synthesis.
A broadly useful catalytic enantioselective synthesis of branched allylic esters from prochiral (Z)-2-alkene-1-ols has been developed. The starting allylic alcohol is converted to its trichloroacetimidate intermediate by reaction with trichloroacetonitrile, either in situ or in a separate step, and this intermediate undergoes clean enantioselective S N 2′ substitution with a variety of carboxylic acids in the presence of the palladium(II) catalyst (R p ,S)-di-μ -acetatobis[(η 5 -2-(2'-(4'-methylethyl) oxazolinyl)cyclopentadienyl,1-C,3'-N)(η 4 -tetraphenylcyclobutadiene)cobalt]dipalladium, (R p ,S)-[COP-OAc] 2 or its enantiomer. The scope and limitations of this useful catalytic asymmetric allylic esterification are defined.
The catalytic enantioselective SN2′ displacement of (Z)-allylic trichloroacetimidates catalyzed by the palladium(II) complex [COP-OAc]2 is a broadly useful method for the asymmetric synthesis of chiral branched allylic esters. A variety of experiments aimed at elucidating the nature of the catalytic mechanism and its rate- and enantiodetermining steps are reported. Key findings include: (a) the demonstration that a variety of bridged-dipalladium complexes are present and constitute resting states of the COP catalyst, however, monomeric palladium (II) complexes are likely involved in the catalytic cycle; (b) labeling experiments establishing that the reaction proceeds in an overall antarafacial fashion; (c) secondary deuterium kinetic isotope effects that suggest substantial rehybridization at both C1 and C3 in the rate-limiting step; and (d) DFT computational studies (B3-LYP/def2-TZVP) that provide evidence for bidentate substrate-bound intermediates and an anti-oxypalladation/syn-deoxypalladation pathway. These results are consistent with a novel mechanism in which chelation of the imidate nitrogen to form a cationic palladium (II) intermediate activates the alkene for attack by external carboxylate in the enantiodetermining step. Computational modeling of the transition-state structure for the acyloxy palladation step provides a model for enantioinduction.
Chelated ruthenium catalysts have achieved highly chemoselective olefin metathesis reactions. Terminal and internal Z olefins were selectively reacted in the presence of internal E olefins. Products were produced in good yield and high stereoselectivity for formation of a new Z olefin. No products of metathesis with the internal E olefin were observed. Chemoselectivity for terminal olefins was also observed over both sterically hindered and electronically deactivated alkenes.
2-Vinylchromanes (1), 2-vinyl-1,4-benzodioxanes (2), and 2,3-dihydro-2-vinyl-2H-1,4-benzoxazines (3) can be prepared in high yields (90–98%) and excellent enantiomeric purities (87–98% ee) by [COP-OAc]2-catalyzed cyclization of phenolic (E)-allylic trichloroacetimidate precursors. Deuterium-labeling and computational experiments are consistent with these cyclization reactions taking place by an anti-oxypalladation/syn-deoxypalladation mechanism. 2-Vinylchromanes can be prepared also in good yields and high enantiomeric purities from analogous (E)-allylic acetate precursors, which constitutes the first report that acetate is a competent leaving group in COP-catalyzed enantioselective SN2′ substitution reactions.
The
mechanism of C–H activation at metathesis-relevant ruthenium(II)
benzylidene complexes was studied both experimentally and computationally.
Synthesis of a ruthenium dicarboxylate at a low temperature allowed
for direct observation of the C–H activation step, independent
of the initial anionic ligand-exchange reactions. A first-order reaction
supports an intramolecular concerted metalation–deprotonation
mechanism with ΔG⧧298K = 22.2 ± 0.1 kcal·mol–1 for the parent N-adamantyl-N′-mesityl complex.
An experimentally determined ΔS⧧ = −5.2 ± 2.6 eu supports a highly ordered transition
state for carboxylate-assisted C(sp3)–H activation.
Experimental results, including measurement of a large primary kinetic
isotope effect (kH/kD = 8.1 ± 1.7), agree closely with a computed six-membered
carboxylate-assisted C–H activation mechanism where the deprotonating
carboxylate adopts a pseudo-apical geometry, displacing the aryl ether
chelate. The rate of cyclometalation was found to be influenced by
both the electronics of the assisting carboxylate and the ruthenium
ligand environment.
A broadly useful catalytic enantioselective synthesis of branched allylic esters from prochiral (Z)-2-alkene-1-ols has been developed. The starting allylic alcohol is converted to its trichloroacetimidate intermediate by reaction with trichloroacetonitrile, either in situ or in a separate step, and this intermediate undergoes clean enantioselective S(N)2' substitution with a variety of carboxylic acids in the presence of the palladium(II) catalyst (R(p),S)-di-μ-acetatobis[(η(5)-2-(2'-(4'-methylethyl)oxazolinyl)cyclopentadienyl-1-C,3'-N)(η(4)-tetraphenylcyclobutadiene)cobalt]dipalladium, (R(p),S)-[COP-OAc](2), or its enantiomer. The scope and limitations of this useful catalytic asymmetric allylic esterification are defined.
Olefin metathesis reactions with 3E-1,3-dienes using Z-selective cyclometalated ruthenium benzylidene catalysts are described. In particular, a procedure for employing 3E-1,3-dienes in Z-selective homodimerization and cross-metathesis with terminal alkenes is detailed. The reaction takes advantage of the pronounced chemoselectivity of a recently reported ruthenium-based catalyst containing a cyclometalated NHC ligand for terminal alkenes in the presence of internal E-alkenes. A wide array of commonly encountered functional groups can be tolerated, and only a small excess (1.5 equiv) of the diene coupling partner is required to achieve high yields of the desired internal E,Z-diene crossmetathesis product. Computational studies have been performed to elucidate the reaction mechanism. The computations are consistent with a diene-first pathway. The reaction can be used to quickly assemble structurally complex targets. The power of this cross-metathesis reaction is demonstrated by the concise syntheses of two insect pheromones.
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