Enamines deprotonated

Whereas carbenoid character is definitely present in metalated alkyl vinyl ethers, lithiated alkyl and aryl vinyl sulfides and thioesters, which are easily available by hydrogen-lithium exchange, do not display carbenoid-typical reactions . They rather behave like nucleophilic reagents, so that their discussion is beyond the scope of this overview despite their utility in synthesis The same appiies to various derivatives of enamines, deprotonated in the vinyiic a-nitrogen position - . 

The fact that lithiation usually occurs in hydrocarbon solvents suggests that the enamine deprotonation will only occur if it undergoes a Lewis acid-base interaction forming a complex with the base used. This is consistent with the assertions of a number of authors that formation of a cyclic transition state is necessary to explain the regiochemistry of these reactions53. 

Later it turned out that activation of enamine components could not only be achieved by deprotonation of the nitrogen atom but also by connecting it with certain metals, e.g. Ni(II), Pd(II), or Co(II), and subsequent treatment with base. 

Thus the reactions of cyclic or acyclic enamines with acrylic esters or acrylonitrile can be directed to the exclusive formation of monoalkylated ketones (3,294-301). The corresponding enolate anion alkylations lead preferentially to di- or higher-alkylation products. However, by proper choice of reaction conditions, enamines can also be used for the preferential formation of higher alkylation products, if these are desired. Such reactions are valuable in the a substitution of aldehydes, which undergo self-condensation in base-catalyzed reactions (117,118). Monoalkylation products are favored in nonhydroxylic solvents such as benzene or dioxane, whereas dialkylation products can be obtained in hydroxylic solvents such as methanol. The difference in products can be ascribed to the differing fates of an initially formed zwitterionic intermediate. Collapse to a cyclobutane takes place in a nonprotonic solvent, whereas protonation on the newly introduced substitutent and deprotonation of the imonium salt, in alcohol, leads to a new enamine available for further substitution. 

Due to mechanistic requirements, most of these enzymes are quite specific for the nucleophilic component, which most often is dihydroxyacetone phosphate (DHAP, 3-hydroxy-2-ox-opropyl phosphate) or pyruvate (2-oxopropanoate), while they allow a reasonable variation of the electrophile, which usually is an aldehyde. Activation of the donor substrate by stereospecific deprotonation is either achieved via imine/enamine formation (type 1 aldolases) or via transition metal ion induced enolization (type 2 aldolases mostly Zn2 )2. The approach of the aldol acceptor occurs stereospecifically following an overall retention mechanism, while facial differentiation of the aldehyde is responsible for the relative stereoselectivity. 

Oxo esters are accessible via the diastereoselective 1,4-addition of chiral lithium enamine 11 as Michael donor. The terr-butyl ester of L-valine reacts with a / -oxo ester to form a chiral enamine which on deprotonation with lithium diisopropylamide results in the highly chelated enolate 11. Subsequent 1,4-addition to 2-(arylmethylene) or 2-alkylidene-l,3-propanedioates at — 78 °C, followed by removal of the auxiliary by hydrolysis and decarboxylation of the Michael adducts, affords optically active -substituted <5-oxo esters232 (for a related synthesis of 1,5-diesters, see Section 1.5.2.4.2.2.1.). In the same manner, <5-oxo esters with contiguous quaternary and tertiary carbon centers with virtually complete induced (> 99%) and excellent simple diastereoselectivities (d.r. 93 7 to 99.5 0.5) may be obtained 233 234. 

Under the same reaction conditions, -keto esters which have been alkylated on the a-carbon atom (thus leading to 3,4-disubstituted 5-pyrazolones upon treatment with hydrazine) give allenic esters in good (50-70%) yield (158). The mechanism (Scheme 36) again appears to involve thallation of the enamine tautomer of the 5 -pyrazolone, but deprotonation now takes place... 

Different rate-determining steps are observed for the acid-catalyzed hydration of vinyl ethers (alkene protonation, ks kp) and hydration of enamines (addition of solvent to an iminium ion intermediate, ks increasing stabilization of a-CH substituted carbocations by 71-electron donation from an adjacent electronegative atom results in a larger decrease in ks for nucleophile addition of solvent than in kp for deprotonation of the carbocation by solvent. 

It appeared that triethylamine is the base of choice for generating nitrosals (343). However, sterically less hindered amines deprotonate the C-4 atom to give, after retro-[4 + 2]-cycloaddition of the intermediate enamines (346), the corresponding conjugated enoximes (347). 

The y-lactone degradation products of cefdinir were found to be also subject to C(6)-epimerization in neutral to basic solutions. The mechanism proposed for this epimerization involves deprotonation of the enamine N-atom,... 

In Section 7.7.2 we met enamines as products from addition-elimination reactions of secondary amines with aldehydes or ketones. Enamines are formed instead of imines because no protons are available on nitrogen for the final deprotonation step, and the nearest proton that can be lost from the iminium ion is that at the P-position. 

Hine has demonstrated that simple amino acids, such as glycine and p-alanine, are not capable of intramolecular deprotonation in the reaction with isobutyraldehyde-2-d (Scheme 8) [62], Apparently, the carboxylate moiety in the iminium ion intermediate 29 is a relatively weak base and, as such, external bases, present in the buffer used (e.g. acetate ions), are largely responsible for the formation of the enamine intermediate 30. 

In 2006, our research group reported a novel MCR based on the reactivity of a-acidic isocyano esters (1) toward 1-azadienes (84) generated by the 3CR between phosphonates, nitriles, and aldehydes [169]. Remarkably, the dihydropyridone products (85) for this 4CR contained the intact isonitrile function at C3. The exceptional formation of the 3-isocyano dihydropyridone scaffold can be explained by the Michael-attack of the a-deprotonated isonitrile (1) to the (protonated) 1-azadiene (84), followed by lactamization via attack of the ester function by the intermediate enamine. Although in principle the isocyano functionality is not required for the formation of the dihydropyridone (85) scaffold, all attempts using differently functionalized esters (e.g., malonates, ot-nitro, and a-cyano esters) gave lower yields of the dihydropyridone analogs [170] (Fig. 26). 

Direct /3-metalation of a tetrahydropyridine has not been achieved, but as with exocyclic enamine systems (Section V,A,2), halogen-metal exchange has been performed successfully. Thus, 2-aryl-3-bromo-l-methyltetrahydropyridines have been metalated with either n-BuLi or t-BuLi, in a procedure that starts with bromination of the parent system to give an a-bromoiminium salt, which can then be deprotonated to give the desired /3-bromoenamine (Scheme 147) [77JA8356 82BSF(2)297]. If the... 

The carbanion generated by ot-proton abstraction of a 2-alkyloxazoline is capable of typical enolate chemistry. Thus, the carbanion was found to react with nitriles to give an enamine, with formate esters to give an aldehyde that can be trapped,with chiral sulfinate esters to give chiral sulfoxides,and with alkylating agents. A carbamate-protected aminomethyl chiral oxazoline was deprotonated and alkylated with diastereoselectivities up to 92% de. ... 

The anhydro bases, e.g. (61), formed by deprotonation of 2- and 4-alkylquinolinium salts, are more stable than the pyridone methides and are usually isolable. They are reactive enamines and some typical chemistry is shown in Scheme 50. 

Aminoallyl carbanions, obtained by deprotonation of enamines or allylamines, are well-known homoenolate equivalents, since electrophilic attack occurs, in most cases, highly regiose-lectively to give the 3-substituted enamines, hydrolysis of which leads to the corresponding carbonyl compounds15 24,25. 

Chiral (5)-2-(methoxymethyl)-l -[( )-3-phenyl-2-propenyl]pyrrolidine obtained from (S)-2-(meth-oxymethyl)pyrrolidine26,30 and ( )-3-bromo-1-phenyl-1-propene, is deprotonated by potassium rert-butoxide/ferf-butyllithium27-28 generating the chiral allyl carbanion, the alkylation of which affords the enamines, which can be hydrolyzed to give 3-alkylated 3-phenylpropanals. 

The conditions for the deprotonation of chiral allylamine 8 depend on the substituent. For the phenyl compound only butyllithium is needed, however, with the alkyl compounds potassium /err-butoxide/tert-butyllithium must be used, giving access to the potassium salts 9 in these cases only. Alkylation with iodoalkanes afforded the unstable enamines, which were hydrolyzed either by water alone but preferably with dilute acid to afford the chiral 3-phenylalkanones. 

The chiral a-cyano allylamines prepared from ( )-3-phenylpropenal, potassium cyanide and (L)-ephcdrinc [(17 ,2S )-2-methylamino-l-phenylpropanol] hydrochloride as a mixture (1 1) of C-l epimers, were deprotonated using 2 equivalents of LDA in THF to give the dilithio compound37. Alkylation at C-3 afforded regioselectively a mixture of (E)- and (Z)-enamines in variable amounts depending on reaction conditions. Diastereoselectivity varied from moderate to excellent. Addition of HMPA and especially lithium iodide improved the diastereoselectivity. De-aggregation is proposed to be the reason for the effect of these additives. 

Aldolases have been classified into mechanistically distinct classes according to their mode of donor activation. Class 1 aldolases achieve stereospecific deprotonation via covalent imine/enamine formation at an active-site lysine residue, while Class II aldolases utilize a divalent transition metal cation for substrate coordination as an essential Lewis acid cofactor (usually Zn ) to facilitate deprotonation... 

While most of the work has been done commencing with the nickel(II) complex (51), the chemistry is quite general. The enamine complex (53) can be deprotonated on nitrogen to yield the neutral imine complex (55). Even the protons of the methyl group in the enol ether complex (52) are sufficiently acidic for the formation of the neutral complex (54). Both of these reactivity features occur together in the alkylation reaction shown in Scheme 18.126 The macrocyclic rings in complexes such as (52), (53) and especially the more flexible complex (56) are not planar but bowl-... 

These structures are sufficiently acidic to deprotonate in neutral solution to yield enamines. 

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