Enolates ambident character

The reactions of nitroalkenes (42) with various enols (43b) (vinyl ethers, silyl, and acyl enolates, ketene acetals) have been studied in most detail (110, 111, 125—154). As a mle, these reactions proceed smoothly to give the corresponding nitronates (35f) in yields from high to moderate. As in the reactions with enamines, the formation of compounds (44b) is attributed to the ambident character of the anionic centers in zwitterionic intermediates analogous to those shown in Scheme 3.43. 

In this fourth part we outline some aspects of the reaction of lithium enolates with electrophilic reagents and their nucleophilic addition onto saturated carbonyl groups. Two significant problems associated with these reactions are (i) the site (C/O) selectivity due to the ambident character of enolates, and (ii) the facial discrimination which controls the stereochemistry of the overall process. 

The proposed intramolecular solvation is not the only feature differentiating between the polystyryl and polymethyl methacrylate salts. The former are classified as the salts of carbanions, whereas the latter are ambident salts having the character of allylic enolates with the cation interacting with the partially negatively charged carbon and oxygen atoms. The degree to which the one or the other interaction is favored is affected by the size of the cation. 

These results clearly show that the potential energy surface can contain a series of minima. The fact that selectivity in re-attack by the F ions can be observed indicates that the differences between the energy barriers for the secondary reactions control the distribution of the final products. The multistep character of these processes is further illustrated by the reactions observed when enolate anions are used as reactant ions. The ambident enolate anions may react with methyl pentafluorophenyl ether at the carbon or the oxygen site. If they react with the carbon site at the fluorine-bearing carbon atoms, then the molecule in the F ion/molecule complex formed contains relatively acidic hydrogen atoms so that proton transfer to the displaced F ion may occur. An example is given in (47) where the enolate anion, generated by HF loss, is not observed. An intramolecular nucleophilic aromatic substitution occurs instead and leads to a second F ion/ molecule complex. The F" ion in this complex then re-attacks the substituted benzofuran molecule formed, either by proton transfer or SN2 substitution. 

Azlactone is commonly utilized as a precursor of a-quatemary a-amino acids and various heterocyclic compounds [28-30]. Because the enol form of azlactone has aromatic character, facile deprotonation from the C4-position affords the corresponding enolate under the influence of various bases. Interestingly, the enolate ion shows ambident reactivity and attacks the electrophile at either the C4-position (a-addition) or the C2-position (y-addition), thus acting as an a-amino enolate or an acyl anion equivalent, respectively (Fig. 1). The site-selectivity associated with this enolate seems to be heavily dependent on its stereoelectronic characteristics, and introduction of a bulky substituent into the Cl- or C4-position suppresses the nucleophilicity at the particular position. 

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