Syuzanna R. Harutyunyan

Catalytic asymmetric conjugate addition and allylic alkylation with Grignard reagents

Catalytic asymmetric C-C bond-forming reactions using organometallic reagents are among the most important of organic transformations. Frequently, these transformations are key steps in the synthesis of complex biologically active molecules. The conjugate addition (CA) and allylic alkylation (AA) with organometallic compounds are especially versatile in asymmetric C-C bond-forming reactions. These transformations are complementary to the catalytic asymmetric allylic alkylation and the Michael addition, both based on soft carbon nucleophiles (Scheme 1A). For both CA and AA, the organic moiety of the organometallic reagent reacts with the sp carbon of an electron-deficient substrate, converting it to an sp carbon (Scheme 1B). In the case of CA, subsequent quenching of the enolate leads to the final product, whereas for the related AA an appropriate leaving group is expelled to form the chiral product. The organometallic compounds used most frequently for these transformations are organozinc, Grignard, organoaluminium, organolithium and cuprate reagents. Over the last three decades considerable effort has been directed toward the development of efficient catalytic systems for the asymmetric CA and AA reactions using organometallic reagents. Complexes derived from Cu salts and chiral ligands have provided the broadest scope in the catalyzed enantioselective CA and AA of organometallic reagents. Organozinc reagents have been the most successful of the organometallic reagents in this respect. Major contributions and progress in the field of asymmetric CA and AA based on organozinc reagents have been summarized in several reviews. Organomagnesium compounds were among the first organometallic compounds to be applied to synthetic organic chemistry and the use of Grignard reagents in Cu-catalyzed CA was first reported in 1941 by Kharash and Tawney. Achieving chemo-, regioand stereocontrol in both asymmetric conjugate addition (ACA) and asymmetric allylic alkylation (AAA), however, has proven to be challenging and has restricted the application of these transformations, in particular, to total synthesis. Typical selectivity issues pertain to 1,2versus 1,4-addition (Scheme 2A) and SN2versus SN2′-substitution (Scheme 2B). The challenge faced in the development of stereoselective C-C bond-forming reactions is apparent when one considers that, despite three decades of intensive research in this area, only recently has efficient Cu-catalyzed enantioselective CA of Grignard reagents been achieved. The earlier discovery of the highly enantioselective Cu-catalyzed CA of dialkylzinc reagents allowed for replacement of Grignard reagents in this asymmetric C-C bond-forming reaction. Dialkylzinc reagents offer distinct advantages over Grignard reagents in their low reactivity in noncatalyzed reactions and their high tolerance to functional groups both on the substrate and on the organozinc reagent itself. Nevertheless, there are several advantages to the use of common mono-alkylMg halide reagents, most importantly their widespread availability and the ability to transfer all of the alkyl groups of the organometallic compound. The synthetic potential of these asymmetric transformations has driven intensive research in this area, and over the past few years major breakthroughs have been realized in the enantioselective CA and AA of Grignard reagents. * Author for correspondence. E-mail: B.L.Feringa@rug.nl Chem. Rev. 2008, 108, 2824–2852 2824

Electrically driven directional motion of a four-wheeled molecule on a metal surface

Propelling single molecules in a controlled manner along an unmodified surface remains extremely challenging because it requires molecules that can use light, chemical or electrical energy to modulate their interaction with the surface in a way that generates motion. Nature’s motor proteins have mastered the art of converting conformational changes into directed motion, and have inspired the design of artificial systems such as DNA walkers and light- and redox-driven molecular motors. But although controlled movement of single molecules along a surface has been reported, the molecules in these examples act as passive elements that either diffuse along a preferential direction with equal probability for forward and backward movement or are dragged by an STM tip. Here we present a molecule with four functional units—our previously reported rotary motors—that undergo continuous and defined conformational changes upon sequential electronic and vibrational excitation. Scanning tunnelling microscopy confirms that activation of the conformational changes of the rotors through inelastic electron tunnelling propels the molecule unidirectionally across a Cu(111) surface. The system can be adapted to follow either linear or random surface trajectories or to remain stationary, by tuning the chirality of the individual motor units. Our design provides a starting point for the exploration of more sophisticated molecular mechanical systems with directionally controlled motion.

A Highly Efficient Ruthenium Catalyst for Metathesis Reactions

The development of accessible metathesis catalysts that combine high activity with excellent tolerance to a variety of functional groups has been key to the widespread application of olefin metathesis in organic synthesis. In spite of the general superb application profile of the ruthenium carbene 1a, its limited thermal stability and the low activity towards substituted double bonds are major drawbacks.[1] Specifically, the preparation of substituted olefins with electron-withdrawing functionality (such as a,b-unsaturated carbonyl compounds, nitriles, sulfones, etc.) through cross metathesis (CM) with terminal alkenes remains a difficult task. The newly introduced highly active ruthenium alkylidene complexes with sterically demanding N-heterocyclic carbene (NHC)[3] ligands have dramatically alleviated this limitation.[2] Compounds of type 1b and 1c were found to be efficient catalysts in the reactions of previously metathesisinactive substrates, including a,b-unsaturated olefins (Scheme 1).[2,4]

Reversing the direction in a light-driven rotary molecular motor

Biological rotary motors can alter their mechanical function by changing the direction of rotary motion. Achieving a similar reversal of direction of rotation in artificial molecular motors presents a fundamental stereochemical challenge: how to change from clockwise to anticlockwise motion without compromising the autonomous unidirectional rotary behaviour of the system. A new molecular motor with multilevel control of rotary motion is reported here, in which the direction of light-powered rotation can be reversed by base-catalysed epimerization. The key steps are deprotonation and reprotonation of the photochemically generated less-stable isomers during the 360° unidirectional rotary cycle, with complete inversion of the configuration at the stereogenic centre. The ability to change directionality is an essential step towards mechanical molecular systems with adaptive functional behaviour.

Catalytic asymmetric carbon–carbon bond formation via allylic alkylations with organolithium compounds

Carbon–carbon bond formation is the basis for the biogenesis of natures essential molecules. Consequently, it lies at the heart of the chemical sciences. Chiral catalysts have been developed for asymmetric C–C bond formation to yield single enantiomers from several organometallic reagents. Remarkably, for extremely reactive organolithium compounds, which are among the most broadly used reagents in chemical synthesis, a general catalytic methodology for enantioselective C–C formation has proven elusive, until now. Here, we report a copper-based chiral catalytic system that allows carbon–carbon bond formation via allylic alkylation with alkyllithium reagents, with extremely high enantioselectivities and able to tolerate several functional groups. We have found that both the solvent used and the structure of the active chiral catalyst are the most critical factors in achieving successful asymmetric catalysis with alkyllithium reagents. The active form of the chiral catalyst has been identified through spectroscopic studies as a diphosphine copper monoalkyl species. Organolithiums are the prototypical nucleophilic reagent, but the direct use of them as nucleophiles in catalytic asymmetric synthesis has been problematic. Long sought after, conditions have now been identified that allow the highly enantioselective catalytic formation of C–C bonds by a direct SN2′ reaction of organolithiums with allylic halides.

Manganese catalysed asymmetric cis-dihydroxylation with H2O2

High turnover enantioselective alkene cis-dihydroxylation is achieved with H(2)O(2) catalysed by manganese based complexes containing chiral carboxylato ligands.

Copper-catalyzed asymmetric ring opening of oxabicyclic alkenes with organolithium reagents

A highly efficient method is reported for the asymmetric ring opening of oxabicyclic alkenes with organolithium reagents. Using a copper/chiral phosphoramidite complex together with a Lewis acid (BF(3)·OEt(2)), full selectivity for the anti isomer and excellent enantioselectivities were obtained for the ring opened products.

Biologically active Phytophthora mating hormone prepared by catalytic asymmetric total synthesis

A Phytophthora mating hormone with an array of 1,5-stereogenic centers has been synthesized by using our recently developed methodology of catalytic enantioselective conjugate addition of Grignard reagents. We applied this methodology in a diastereo- and enantioselective iterative route and obtained two of the 16 possible stereoisomers of Phytophthora hormone α1. These synthetic stereoisomers induced the formation of sexual spores (oospores) in A2 mating type strains of three heterothallic Phytophthora species, P. infestans, P. capsici, and P. nicotianae but not in A1 mating type strains. The response was concentration-dependent, and the oospores were viable. These results demonstrate that the biological activity of the synthetic hormone resembles that of the natural hormone α1. Mating hormones are essential components in the sexual life cycle of a variety of organisms. For plant pathogens like Phytophthora, sexual reproduction is important as a source of genetic variation. Moreover, the thick-walled oospores are the most durable propagules that can survive harsh environmental conditions. Sexual reproduction can thus greatly affect disease epidemics. The availability of synthetic compounds mimicking the activity of Phytophthora mating hormone will be instrumental for further unravelling sexual reproduction in this important group of plant pathogens.

Asymmetric Allylic Alkylation of Acyclic Allylic Ethers with Organolithium Reagents

A highly efficient, regio- and enantioselective Cu(I)/phosphoramidite-catalyzed asymmetric allylic alkylation of allyl ethers with organolithium reagents is reported (see scheme). The use of organolithium reagents is essential for this catalytic C-C bond formation due to their compatibility with different Lewis acids. The versatility of allylic ethers under the copper-catalyzed reaction conditions with organolithium reagents is demonstrated in the shortest synthesis of (S)-Arundic acid.

Catalytic asymmetric addition of Grignard reagents to alkenyl-substituted aromatic N-heterocycles

Copper adds alkyls asymmetrically Nitrogen-bearing rings are very common features in the molecular structures of modern drugs. Reactions that can modify these N heterocycles selectively are thus especially useful to optimize pharmaceutical properties. Jumde et al. developed a method to append alkyl groups in a single mirror-image orientation to substituted C=C double bonds dangling from N heterocycles. The copper-catalyzed reaction, which relies on Grignard reagents to introduce the alkyl groups, manifests high selectivity across a broad range of substrates, with no interference from the nitrogen. Science, this issue p. 433 A chiral copper catalyst alkylates a class of compounds of interest in medicinal chemistry research. Catalytic asymmetric conjugate addition reactions represent a powerful strategy to access chiral molecules in contemporary organic synthesis. However, their applicability to conjugated alkenyl-N-heteroaromatic compounds, of particular interest in medicinal chemistry, has lagged behind applications to other substrates. We report a highly enantioselective and chemoselective catalytic transformation of a wide range of β-substituted conjugated alkenyl-N-heteroaromatics to their corresponding chiral alkylated products. This operationally simple methodology can introduce linear, branched, and cyclic alkyl chains, as well as a phenyl group, at the β-carbon position. The key to this success was enhancement of the reactivity of alkenyl-heteroaromatic substrates via Lewis acid activation, in combination with the use of readily available and highly reactive Grignard reagents and a copper catalyst coordinated by a chiral chelating diphosphine ligand.