Propiolate intermediates

MULTICOMPONENT COUPLING-ADDITION-CYCLOCONDENSATION SEQUENCES VIA PROPIOLATE INTERMEDIATES... 

A more conventional cycloaddition occurs with activated acetylenes, however, the intermediate cyclobutene adducts undergo rearrangement to give insertion of two carbon atoms into the enamine chain (55). Thus the enamine (16) reacted with methyl propiolate to give the dienamino ester (73), presumably via the cycloaddition product (65a). 

With a change to non-polar solvent, the reaction of ylides 269 with alkynes and alkenes changed dramatically, as shown in Scheme 10. With DM AD in toluene the ylides give pyrazolopyridines 272 in good yield (91TL4977), and with methyl propiolate (MEP) give indolizines 273 (92H(33)203). The reaction with acrylates is much less clean, but the variety of products is said to be formed from a diazene intermediate, which splits to give a diradical (93H(35)851). 

Reaction of iV-aminoisoindoline 450 with methyl propiolate affords betaine 451 and its treatment with hydrochloric acid gives intermediate chloro derivative 452, which can be cyclized to 453 by treatment with a base or by heating (Scheme 75) <1995LA817>. 

Reduced fused azepines (e.g. 40) have been used in a new ring expansion strategy to afford fused hexahydroazoninoindoles (e.g. 41) from reaction with methyl propiolate in methanol to give the ylide intermediate A which then ring expanded via the methanol stabilised intermediate B to give 41 <06T1239>. 

The same reaction sequence may be used to convert cyclo-dodecanone to cyclotetradecanone. Preparation of the pyrrolidine enamine of cyclododecanone requires 2-3 days at reflux, and reaction of the enamine with methyl propiolate is best carried out in refluxing hexane. The enamine-propiolate reaction may also be used to convert cycloheptanone to cyclononanone. In this case the procedure must be modified to provide for partial hydrogenation of the intermediate amino ester without prior hydrolysis.8 The reduced intermediate is saponified as described in the present procedure. 

As depicted in Scheme 11, ylides 39 derived from 4-methyl-[l,2,3]triazolo[l,5- ]pyridine react with Michael acceptors, which, upon nucleophilic attack at C3 and ring opening, lead to nucleophilic displacement of nitrogen. The intermediate diradical led to a mixture of compounds, including alkenes and a cyclobutane derivative when methyl acrylate was used, and the indolizine 40 with methyl propiolate as the electrophile <1998T9785>. Heating 4-methyl triazolopyridine with benzenesulfonyl chloride in acetone also confirmed decomposition via a radical pathway. 

The proposed reaction mechanism is as follows (Scheme 16.83). Zinc metal reduces Ni(II) species to Ni(0). A nickelacyclopentadiene may be produced via coordination of two molecules of propiolates and regioselective head-to-head oxidative cyclometallation. Coordination and subsequent insertion of an allene into the Ni(II)-carbon bond give rise to a nickelacycloheptadiene intermediate. Finally, a benzene derivative is produced via reductive elimination followed by isomerization. 

In the [2 + 2] cycloadditions of 10 with iV-phenylmaleimide and dimethyl fumarate, the major cycloadducts were formed with a very high degree of ee transfer from 1,3-dimethylallene8. Similar results were obtained in the reaction of 10 with 1,1-dichloro-2,2-difluoroethene. The reaction with less reactive 1,1-diphenylethene did not lead to cycloadduct formation, but resulted in racemization of the chiral 1,3-dimethylallene instead9, which implies reversible formation of the diradical intermediate in this case. Finally, the cycloaddition of 1,3-dimethylallene to methyl propiolate (14) afforded two cycloadducts, 15 and 16, to which >40% of the initial ee had been transferred (equation 5)11. 

On the basis of the above-mentioned calculations it seems that coordination chemistry is a viable alternative to stabilize this heterocumulene. However, the experimental access to metal complexes containing the tricarbon monoxide ligand remains a challenge. Thus, to date, the coordination chemistry of C3O is confined to [Cr(=C=C=C=0)(C0)s] (89), obtained by treatment of [n-Bu4N] [CrI(CO)5] with the silver acetylide derived of sodium propiolate in the presence of Ag" (Scheme 28) [105]. Reaction of the presumed Tt-alkyne intermediate complex 88 with thiophosgene generates the heterocumulene 89. Neither structural nor reactivity studies were undertaken with this complex. 

The meso-ionic l,3>2-oxathiazol-5-ones (169) show an interesting range of reactions with nucleophiles including ammonia, primary amines, and aqueous alkali. They also react with l,3-dipolarophiles, including dimethyl acetylenedicarboxylate and methyl propiolate, yielding isothiazoles (171) and carbon dioxide. 1,3-Dipolar cycloaddition reactions with alkenes such as styrene, dimethyl maleate, and methyl cinnamate also lead to isothiazoles (171) directly. BicycUc intermediates (cf. 136) were not isolable these cycloaddition reactions with alkenes giving isothiazoles involve an additional dehydrogenation step. 

Winterfeldt has shown that the reaction of dimethyl sulfoxide with DMAD gives tetramethyl furantetracarboxylate (345), and it was suggested that this reaction may proceed through the intermediates 342, 343, and.344 (Scheme 52). The reaction of /-butylsulfenic acid with methyl propiolate, however, gives /3v -bis(/ra/is-carbomethoxy)divinyl sulfoxide (348) (Scheme 53). The penicillin S-oxide (349) is known to react with DMAD to give the adduct 352, and this reaction has been assumed to proceed through the sulfenic acid intermediate 350 (Scheme 54). ... 

Wilson and Tebby have studied the reaction of triphenylphosphine with different acetylenic esters in alcohol medium and have shown that /3-alkoxyvinylphosphonium ylides and vinyl ethers are formed through the alcoholysis of vinyl phosphonium intermediates. Thus, triphenylphosphine reacts with DMAD in methanol to give the phosphorane (432) [Eq. (62)]. The reaction with propiolic esters, on the... 

Isopropenylbenzofuran (124), on reaction with dimethyl acetylenedicar-boxylate, affords the dibenzofuran 130 (Scheme 32), the intermediate dihy-drodibenzofuran undergoing dehydrogenation at the expense of the diene in as much as some 2-isopropylbenzofuran was isolated. Methyl propiolate similarly afforded the dehydrogenated adduct 131. Advantage has been... 

A potentially useful route to reserpine alkaloids has been suggested by the application of the amino-Claisen reaction (Scheme 52) to the indolyl-substituted isoquinuclidine (268). Treatment of (268) with methyl propiolate gave the intermediate zwitterion (269) which rapidly rearranged to (270). This latter compound has all the necessary functionality for further elaboration into the reserpine ring system (B-82MI20700). 

Following are further examples of reversed reactivity order. The formation of 5-oxo-TPs is achieved by means of condensations of AT (in the presence of sodium ethoxide) with ethyl 3,3-diethoxypropionate or 3-ethoxyacrylate (64ZOB499), propiolic acid (70CB3266), and cyanoacetate (61CPB801 64CB1373, 64IZV1475), respectively. In the last case (formation of 12), the fusion of reactants without catalyst allows the isolation of intermediate amide 11 (Scheme 5). 

The quinoline portion of the target alkaloids was prepared by condensing p-anisidine 9 with ethyl propiolate, followed by bromination. Coupling of 10 with the boronic ester 8 proceeded to give 11, the intermediate for the synthesis of both 1 and 2. Selective direct epoxidation of 11 using the usual reagents failed, but Sharpless asymmetric dihydroxylation was successful, providing the diol in > 96 4... 

Chuan He of the University of Chicago has observed (J. Org. Chem. 2004,69, 3669) that an Au catalyst will rearrange ethyl propiolate 7 to give an intermediate that inserts into aromatic C-H bonds to give the Z-alkene 8. 

The cyclazine (Iv) was the only product isolated in poor yield from reaction of pyridine and methyl propiolate in acetonitrile. The indolizine derivative (35) may be an intermediate, since it was obtained from a similar reaction in ether.39 2-Acetylpyridine and ethyl pyridine-2-carboxylate reacted similarly.40... 

The iV-aminopyrrole - benzene ring methodology has been applied to a synthesis of the 9,10-dihydrophenanthrene juncusol (218) (81TL1775). Condensation of the tetralone (213) with pyrrolidine and reaction of the enamine with ethyl 3-methoxycarbonylazo-2-butenoate gave pyrrole (214). Diels-Alder reaction of (214) with methyl propiolate produced a 3 1 mixture of (215) and its isomer in 70% yield. Pure (215) was reduced selectively with DIBAL to the alcohol, reoxidized to aldehyde, and then treated with MCPBA to generate formate (216). Saponification to the phenol followed by O-methylation and lithium aluminum hydride reduction of the hindered ester afforded (217), an intermediate which had been converted previously to juncusol (Scheme 46). 

Similarly, cyclization of 3-amino-l, 2,4-triazoles (65) with methyl propio-late or methyl phenylpropiolate gave a mixture of the l,2,4-triazolo[4,3-a]pyrimidin-7-ones 97 and the l,2,4-triazolo[l,5-a]pyrimidin-7-ones 98 (70CB3266 71CB2702). In addition, methyl tram-3-(3-amino-l,2,4-triazol-l-yl)acrylates (99) were also obtained. Production of the 1,2,4-triazolopy-rimidines 97 and 98 started by condensation of the ester function with the amino group of 65, followed by cycloaddition of the triazole N4 or N1 of the two tautomeric intermediates 96a and 96b, respectively, onto the carbon-carbon triple bond of the side chain. In contrast, formation of the triazolyl acrylates 99 took place through addition only of the triazole N1 onto the propiolate carbon-carbon triple bond. The relative amounts of products were found to depend on the reaction conditions (temperature, solvent, and time) (70CB3266) (Scheme 42). 

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