5-Substituted 3-pyrrolin-2-ones

Addition of lithium derivatives of acetylenides (Li—C=C-C02R) to chiral nitrones proceeds with high stereoselectivity, giving a-acetylene substituted hydroxylamines (410a,b) (656). This reaction has been successfully applied to the synthesis of y-hydroxyamino-a, 3-ethylene substituted acids (411a,b), formed in the reduction of (410) with Zn in the presence of acid (657, 658), and to chiral 5-substituted-3-pyrroline-2-ones (412a,b) (Scheme 2.184) (658). 

F. L. Tejero, T. Ready access to enantiopure 5-substituted 3-pyrrolin-2-ones from N-benzyl-2,3-O-isopropylidene-D-glyceraldehyde nitrone. Tetrahedron Asymmetry 1998, 9,1759— 1769. 

Flash vacuum pyrolysis of other isopropylidene /V,/V-disubstituted aminomethylenemalonates (1244) also gave 1-substituted pyrrolin-4-ones (1245) [84HCA1402 85CC213 88JCS(P 1)863]. 

Peptidomimetics based on 3,5-linked, 5-substituted pyrrolin-4-ones have many structural features common to a-peptide chains (Figure 16). The carbonyl... 

With dimethyl fumarate, methyl acrylate, and methyl methacrylate as dipolarophiles, substituted pyrrolines are obtained.52-54 In contrast, the reaction of 2-phenyl-2-oxazolin-5-onium perchlorate with benzyl-ideneaniline follows a different course to give the imidazolin-4-one (24).55... 

Barluenga and coworkers utilized a dilithiation reaction involving allylic amines to prepare 3- and 4-substituted 3-pyrrolin-2-ones (1988TL4859, 1993TL7777). Sequential treatment of allylic amines (e.g., 247) with -butyIlithium, teri-butyllithimn and then diethyl carbonate gives 3-pyrro-Un-2-ones (e.g., 249), presumably via dilithiated intermediates such as 248 (Scheme 61). Yus and coworkers used CO2 as an electrophile in a similar sequence used to prepare l,5-dimethyl-4-phenyl-3-pyrrolin-one (1995 TA2081). 

Complex reactions occur on the autoxidation of pyrroles (see Section 3.05.1.4) predictably, susceptibility to autoxidation increases with increasing alkyl substitution, llie photosensitized reaction of pyrrole and oxygen yields 5-hydroxy-A -pyrrolin-2-one, probably by way of an intermediate cyclic peroxide (Scheme 28) (76JA802). 

As pointed out in the introduction, if one of the substituents on the nitrogen atom is a hydrogen atom, tautomeric equilibrium between enamino and imino forms strongly favors the latter form 18,140,141). According to physiochemical measurements, the occurrence of simply substituted /1 -pyrrolines and zl -piperideines is very improbable. The formulation of this type of compound with a double bond in the position (used mainly by early authors) was of formal meaning only, having no experimental evidence (142-144). 

Although pyrrole appears to be both an amine and a conjugated diene, its chemical properties are not consistent with either of these structural features. Unlike most other amines, pyrrole is not basic—the pKa of the pyrrolin-ium ion is 0.4 unlike most other conjugated dienes, pyrrole undergoes electrophilic substitution reactions rather than additions. The reason for both these properties, as noted previously in Section 15.5, is that pyrrole has six 77 electrons and is aromatic. Each of the four carbons contributes one... 

This method for preparing 2-phenyl-1-pyrroline, and assorted 2-substituted 1-pyrrolines, is one of the best currently available, particularly because it reproducibly affords clean materials. Generally, the procedure is amenable to various aromatic esters 2 it has also been applied successfully to aliphatic esters (Table I).3 An advantage of this method is the use of readily available, inexpensive N-vinyl-pyrrolidin-2-one as a key starting material. This compound serves effectively as a 3-aminopropyl carbanion equivalent. The method illustrated in this procedure has been extended to include the synthesis of 2,3-disubstituted pyrrolines. Thus, alkylation of the enolate of the intermediate keto lactam, followed by hydrolysis, leads to various disubstituted pyrrolines in good yields (see Table II).3... 

Kirk L. Sorgi, Cynthia A. Maryanoff, David F. McComsey, and Bruce E. Maryanoff 215 N-VINYLPYRROLIDIN-2-ONE AS A 3-AMINOPROPYL CARBANION EQUIVALENT IN THE SYNTHESIS OF SUBSTITUTED 1-PYRROLINES PREPARATION OF 2-PHENYL-1-... 

Although terrestrial cyanobacteria are well-recognized producers of a wide range of bioactive compounds, marine species have received less attention until recently [159]. One of the most abundant and studied marine cyanobacteria is the pantropic Lyngbya majuscula (Oscillatoriaceae). A prolific producer of metabolites, it has so far yielded more than 110 secondary metabolites including compounds that exhibit antiproliferative, immunosuppressants, antifeedant and molluscidal activities [159,160]. Shallow water varieties of the cyanophyte contain N-substituted amides of 75-methoxytetradec-4E-enoic acid and of 7S-methoxy-9-methylhexa-dec-4 -enoic acid called malyngamides, a sub-class of which contains the 4-methoxy-3-pyrrolin-2-one system [158]. 

While enantiomerically pure a-substituted isocyanoacetates have been used in Passerini condensation without significant racemization [4-6], the same class of compounds is believed to be configurationally unstable under the conditions of U-4CRs [7]. However, one notable exception is the reaction shown in Scheme 1.1, where L-isoleucine-derived isocyanide 2 has been condensed without such problems with pyrroline 1 [8]. The bulkiness of this isocyanide or the use of a preformed cyclic imine, thus avoiding the presence of free amine in solution, may be the reasons for the absence of racemization. 

Intermolecular addition of carbon nucleophiles to the ri2-pyrrolium complexes has shown limited success because of the decreased reactivity of the iminium moiety coupled with the acidity (pKa 18-20) of the ammine ligands on the osmium, the latter of which prohibits the use of robust nucleophiles. Addition of cyanide ion to the l-methyl-2//-pyr-rolium complex 32 occurs to give the 2-cyano-substituted 3-pyrroline complex 75 as one diastereomer (Figure 15). In contrast, the 1-methyl-3//-pyrrolium species 28, which possesses an acidic C-3-proton in an anti orientation, results in a significant (-30%) amount of deprotonation in addition to the 2-pyrroline complex 78 under the same reaction conditions. Uncharacteristically, 78 is isolated as a 3 2 ratio of isomers, presumably via epimerization at C-2.17 Other potential nucleophiles such as the conjugate base of malononitrile, potassium acetoacetate, and the silyl ketene acetal 2-methoxy-l-methyl-2-(trimethylsiloxy)-l-propene either do not react or result in deprotonation under ambient conditions. 

Annelation of steroidal dienamines with substituted phenacyl bromides (7 examples) or with benzenediazonium salts (11 examples) has been shown to lead to the corresponding furano- and indolo-steroids.89 Thus the A3,5-dienamine derived from A4-androstene-3,17-dione reacted with p-bromophenacyl bromide to yield the A5-androstano[3,4-h]furan (199) in 26% yield, and reaction of the same A3,5-dienamine with benzenediazonium fluoroborate at -45 °C led to formation of the hydrazone (200) which underwent Fischer-indole cyclization on treatment with phosphorus oxychloride to produce the A4-androstano[6,7-6]indole (201). The A3,5-dienamine derived from 17/3-acetoxyandrost-4-en-3-one has been converted into the benz[4,5,6]-steroid (202 R1 = Me, R2 = H) by reaction with methyl vinyl ketone and into the analogous benzsteroid (202 R1 = H, R2 = Me) on treatment with crotonal-dehyde.90 A route to the condensed pyrroline ring system (203) has been devised... 

N-Vinylpyrrolidin-2-one as a 3-Aminopropyl Carbanion Equivalent in the Synthesis of Substituted 1-Pyrrolines Preparation of 2-Phenyl-1-pyrroline. 

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