Stereoselectivity Robinson annulation

While this example of the Robinson annulation is clearly not enantioselec-tive, the same antibody converts the mero-ketone [120] into the Wieland-Miescher (WM) decalenedione product kcM = 0.086 min-1 and Km = 2.34 mM at 25°C, parameters that give an impressive ER of 3.6 x 106. Good evidence suggests that the mechanism of the reaction involves the formation of a ketimine with the e-amino group of a buried lysine residue in the antibody, as shown in Fig. 39. Most significantly, the reaction delivers the ( )-(+)-WM product in 96% ee (by polarimetry) and in 95% ee by nmr and hplc analysis for a 100 mg scale reaction. A recent report tells that this antibody is to be made commercially available at a cost of 100 for 10 mg. The realization of that objective would mark the start of a new era of application of abzymes to organic stereoselective synthesis. 

Strategies based on two consecutive specific reactions or the so-called "tandem methodologies" very useful for the synthesis of polycyclic compounds. Classical examples of such a strategy are the "Robinson annulation" which involves the "tandem Michael/aldol condensation" [32] and the "tandem cyclobutene electrocyclic opening/Diels-Alder addition" [33] so useful in the synthesis of steroids. To cite a few new methodologies developed more recently we may refer to the stereoselective "tandem Mannich/Michael reaction" for the synthesis of piperidine alkaloids [34], the "tandem cycloaddition/radical cyclisation" [35] which allows a quick assembly of a variety of ring systems in a completely intramolecular manner or the "tandem anionic cyclisation approach" of polycarbocyclic compounds [36]. 

Historical perspective C. H. Heathcock, Comp. Org. Syn. 2, 133-179 (1991). General review T. Mukaiyama, Org. React. 28,203-331 (1982). Application of lithium and magnesium enolates C. H. Heathcock, Comp. Org. Syn. 2, 181-238 (1991) of boron enolates B. M. Kim etal, ibid. 239-275 of transition metal enolates I. Paterson, ibid. 301-319. Stereoselective reactions of ester and thioester enolates M. Braun, H. Sacha, J. Prakt. Chem. 335,653-668 (1993). Review of asymmetric methodology A. S. Franklin, I. Paterson, Contemp. Org. Syn. 1,317-338 (1994). Cf. Claisen-Schmidt Condensation Henry Reaction Ivanov Reaction Knoevenagel Condensation Reformatskv Reaction Robinson Annulation. 

Developed in the early 1970s, this reaction, also called the Hajos-Parrish reaction or Hajos-Parrish-Ender-Sauer-Wiechert reaction, is one of the earliest processes for the stereoselective synthesis of Wieland-Miescher ketone, an important building block for steroids and terpenoid synthesis. This reaction is a proline mediated asymmetric variation to the Robinson annulation. Hajos and Parrish of Hoffmann-La Roche Inc. in 1971 and 1974 published an asymmetric aldol cyclization of triketones such as that of structure 39, which affords optically active annulation products in the presence of catalytic amounts of (S)-proline (Z-proline). One of the early examples is the synthesis of 41 from the triketone 39 (a product of the Michael addition of MVK to the corresponding 2-methylcyclopentane-l,3-dione), the reaction is performed in two steps first by ring formation in the presence of 3 mol % of (iS)-proline in DMF to afford the ketol 40 in 100% yield after crystallization with 93% ee and then by reaction with toluenesulfonic acid to give the dehydrated adduct 41. The formation of the Wieland-Miescher Ketone 44 follows the same synthetic route, starting from the tri-ketone 42 to give the end product in 75% optical purity and 99.8% of optical yield. 

There are different approaches for stereocontrol for the Robinson annulation the control can either arise fi-om the inherent nature of the starting ketone and/or the vinyl ketones substituents in combination with the reaction conditions, or by the use of a chiral catalyst. In the first case, an example is the stereoselective aldol cyclization to give the ketol intermediate 50. In this case the cyclization is kinetically controlled under protic basic conditions of sodium ethoxide and ethanol as it gives the cw-fused adduct rather than the more stable trans-fased ketol, which is not detected at any time during the reaction. 

Total syntheses of diterpenoid hydrokempenones have been accomplished by Paquette et al.,f using the Pd-catalyzed [3 + 2] cycloaddition methodology. One example is outlined on Scheme 43 and describes the synthesis of an isomeric compound 208 of 3/3-hydroxy-7/3-kemp-8(9)-en-6-one, a defense secretion agent of the neotropical species Nasutitermes octopilis. 3-AUcoxy-2-cyclohexenone 204 was efficiently functionalized and transformed to bicylic adduct 205 via a Robinson annulation reaction. Reduction of the double bond followed by condensation of dimethyl carbonate and oxidation gave the keto ester 206, which was treated with [2-(acetoxymethyl)-3-allyl]trimethylsilane, palladium acetate, and triisopropyl phosphite in refluxing tetrahydrofuran to afford a 98% yield of 207. Substituted methylenecyclopentane 207 was then functionalized by stereoselective reduction and protections, and final closure was done under basic conditions after an ozonolysis step. A modified Barton-McCombie reaction produced the desired tetracyclic adduct 208. 

The large number of research programs aimed at the syntheses of steroids produced a phenomenal wealth of reaction methods for organic synthesis. The development of the asymmetric proline-catalyzed Robinson annulation reaction for the preparation of the Wieland-Miescher ketone (36, Equation 3) in the early 1970s [41] is noteworthy and marks an important milestone for catalysis by small organic molecules. Asymmetric amine-catalyzed aldol reactions represent an additional variant of the stereoselective aldol addition reaction. The mechanism of the proline-catalyzed aldol addition reaction has been the subject of extensive debate, but the general consensus, based on recent mechanistic studies and quantum mechanical calculations, supports the notion of the involvement of a single amino acid molecule in the transition state structure (39, Scheme 4.4) [42]. 

Anilide 2a catalysed asymmetric intramolecular Michael reaction of formyl enones to chiral cyclic keto-aldehydes in excellent yields with good stereoselectivity (eqn. (1) in Scheme 6.3). The intramolecular Michael addition of a ketosulfone to an unsaturated ketone (eqn. (2) in Scheme 6.3) catalysed by 15e has heen used as a key step in the synthesis of the carbon tricyclic framework of Lycopodine. The same sulfonylprolinamide served as catalyst in the construction of all-carhon substituted quaternary stereocentre via Robinson-type annulation process (eqn. (3) in Scheme 6.3). 

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