Subject from enol silyl ethers

Nucleophilic displacement of chlorine, in a stepwise manner, from cyanuric chloride leads to triazines with heteroatom substituents (see Section 6.12.5.2.4) in symmetrical or unsymmetrical substitution patterns. New reactions for introduction of carbon nucleophiles are useful for the preparation of unsymmetrical 2,4,6-trisubstituted 1,3,5-triazines. The reaction of silyl enol ethers with cyanuric chloride replaces only one of the chlorine atoms and the remaining chlorines can be subjected to further nucleophilic substitution, but the ketone produced from the silyl enol ether reaction may need protection or transformation first. Palladium-catalyzed cross-coupling of 2-substituted 4,6-dichloro-l,3,5-triazine with phenylboronic acid gives 2,4-diaryl-6-substituted 1,3,5-triazines <93S33>. Cyanuric fluoride can be used in a similar manner to cyanuric chloride but has the added advantage of the reactions with aromatic amines, which react as carbon nucleophiles. New 2,4,6-trisubstituted 1,3,5-triazines are therefore available with aryl or heteroaryl and fluoro substituents (see Section 6.12.5.2.4). 

This area of reactivity has been the subject of excellent reviews (J5). Silyl enol ethers are not sufficiently nucleophilic to react spontaneously with carbonyl compounds they do so under the influence of either Lewis acids or fluoride ion, as detailed above. Few clear trends have emerged from the somewhat limited number of definitive studies reported so far, with ambiguities in diastereoisomeric assignments occasionally complicating the issue even further. 

Palladium-catalyzed bis-silylation of methyl vinyl ketone proceeds in a 1,4-fashion, leading to the formation of a silyl enol ether (Equation (47)).121 1,4-Bis-silylation of a wide variety of enones bearing /3-substituents has become possible by the use of unsymmetrical disilanes, such as 1,1-dichloro-l-phenyltrimethyldisilane and 1,1,1-trichloro-trimethyldisilane (Scheme 28).129 The trimethylsilyl enol ethers obtained by the 1,4-bis-silylation are treated with methyllithium, generating lithium enolates, which in turn are reacted with electrophiles. The a-substituted-/3-silyl ketones, thus obtained, are subjected to Tamao oxidation conditions, leading to the formation of /3-hydroxy ketones. This 1,4-bis-silylation reaction has been extended to the asymmetric synthesis of optically active /3-hydroxy ketones (Scheme 29).130 The key to the success of the asymmetric bis-silylation is to use BINAP as the chiral ligand on palladium. Enantiomeric excesses ranging from 74% to 92% have been attained in the 1,4-bis-silylation. 

A number of silyl enol ethers of acyl silanes have been produced from alkenes by subjection to 50 atmospheres of carbon monoxide in the presence of 0.1 equivalents of trialkylsilane and 2 mol% of an iridium catalyst (Scheme 26)102. Hydrolysis to the acyl silanes was achieved using hydrochloric acid-acetone. 

Since the formation of silyl enol ethers from the corresponding ketones is subject to dther thermodynamic or kinetic control, Ais reagent can be used (as demonstrated in equation 36) to achieve useful regiospecific cleavages. 

Nucleophilic attack on ( -alkene)Fp+ cations may be effected by heteroatom nucleophiles including amines, azide ion, cyanate ion (through N), alcohols, and thiols (Scheme 39). Carbon-based nucleophiles, such as the anions of active methylene compounds (malonic esters, /3-keto esters, cyanoac-etate), enamines, cyanide, cuprates, Grignard reagents, and ( l -allyl)Fe(Cp)(CO)2 complexes react similarly. In addition, several hydride sources, most notably NaBHsCN, deliver hydride ion to Fp(jj -alkene)+ complexes. Subjecting complexes of type (79) to Nal or NaBr in acetone, however, does not give nncleophilic attack, but instead results rehably in the displacement of the alkene from the iron residue. Cyclohexanone enolates or silyl enol ethers also may be added, and the iron alkyl complexes thus produced can give Robinson annulation-type products (Scheme 40). Vinyl ether-cationic Fp complexes as the electrophiles are nseful as vinyl cation equivalents. ... 

Diketones often are protected as enol ethers or enamines and these selectively functionalized compounds may be subjected to complementary transformations (Scheme 94). Also silylenes can be prepared from diketones and -hydroxycarbonyl compounds by reaction with dimethyldicyanosilane. Naturally, these blocking groups are relatively sensitive to hydrolysis. On the other hand, partial solvolysis can open a route to monoprotected derivatives (e.g. 101), usually blocked at the sterically less demanding carbonyl function as 0-silyl cyanohydrins (see Scheme 95). Deprotection is finally achieved with silver fluoride in THF. 

Silyl enol ethers need Lewis acid catalysis for efficient Michael reactions, such as the more substituted (and conjugated) isomer 110 forming a 1,5-diketone 111 from cyclohexenone in good yield.39 This product 111 is a mixture of diastereoisomers as have been many of the products in this chapter. We have also seen some reactions giving single diastereoisomers but without explanation. It is high time that we addressed the question of stereoselectivity and this is the subject of the next chapter. 

Synthesis of 7 -amino acid-oxazole fragment 68 of calyculins A and B from D-erythronol-actone 58 has been reported by conversion to 59," which was subjected to oxidation reaction to afford the hemiaminal 60 (Scheme 9) Acetylation of 60 furnished 61, which was converted to ketone 62 in 88% yield. Conversion of 62 to a silyl enol ether, ozonolysis with reductive workup and O-methylation of the resultant alcohol 63 furnished 7 -lactam 64. Treatment of 64 with CAN led to 65 (60%), which was reacted with (CHj)2 A1 derivative of 66 to provide 67 (62%), which upon removal of the silyl group provided 68. 

The protection of the hemiacetal hydroxyl in step C is followed by a purification of the dominant stereoisomer. The C-6 methyl group is introduced in step C by conjugate addition of dimethylcuprate. The enolate is trapped as the silyl enol ether and oxidized to the enone by palladium acetate. The enone from step D is then subjected to a Wittig reaction. As in several of the other syntheses, the hydrogenation in step E is used to establish the configuration at C-4 and C-6. 

These observations led us to test the idea that an N-tritylamino group of an aminoketone could be used as a 1,3-allylic stereocontrol element for the electrophilic fluorination of silyl enol ethers. This was deemed feasible since the approach trajectory of nucleophiles to the carbonyl group of N-tritylated aminoketones along the Dunitz angle is not all that different from the perpendicular approach trajectory of electrophiles to the n-bond of the enol ether and therefore might be subject to the same type of stereochemical control (Figure 2). 

---