Isonitriles esters

Hydrodeamination.6 ct-Amino acid esters can be deaminated by conversion to isonitrile esters followed by reduction with this hydride (equation 1). 

The same authors have broadened the scope of the solid-phase application of this reaction by employing different cyclic amidines instead of only the 2-aminopyridine nucleus and using a Wang resin-bound isonitrile ester [357]. In this paper the authors justified the use of catalytic PTS A instead of a carboxylic acid such as AcOH, because the latter would trigger a Passerini [342, 358] side reaction (Scheme 93). 

Two general type of processes that proceed by way of a putative enolate-metal complex have been documented (1) those in which the metaiioenoiate nucleophile is generated following deprotonation of C-H acid 257—>258, and (2) those in which the metaiioenoiate is generated upon desilylative metallation of an enol silane 261—>262 (Scheme 21). Examples of the former processes have been documented and utilize activated C-H acids with pK (H2O)<20 such as isonitrile esters 259, nitroalkanes 260, and ketones. Fewer cases have been reported for the catalytic addition of enol silanes through a putative metaiioenoiate intermedi-... 

TosMIC reagents. For example, glyoxylic acid ethyl ester undergoes cycloaddition with (2-naphthyl) tosylmethyl isonitrile (17) to produce oxazole 18 in good yield. ... 

The mechanism of the condensation in Part D probably involves thioformylation of the metallated isocyanoacetate followed by intramolecular 1,1-addition of the tautomeric enethiol to the isonitrile. This thi2izole synthesis is analogous to the formation of oxazoles from acylation of metallated isonitriles with acid chlorides or anhydrides. " Interestingly, ethyl formate does not react with isocyanoacetate under the conditions of this procedure. Ethyl and methyl isocyanoacetate have been prepared in a similar manner by dehydration of the corresponding N-formylglycine esters with phosgene and trichloromethyl chloroformate, respectively. The phosphoryl chloride method described here was provided to the submitters by Professor U. Schollkopf and is based on the procedure of Bohme and Fuchs. The preparation of O-ethyl thioformate in Part C was developed from a report by Ohno, Koi/.uma, and Tsuchihaski. " ... 

In the presence of Bu OK, (benzotriazole-l-yl)methyl isocyanide (BetMIC) 697 undergoes alkylation on the methylene group to give isocyanide 698. The anion derived from 698, upon its treatment with Bu OK, adds to the electron-deficient double bonds of ajl-unsaturated ketones, esters or nitriles to produce pyrroles 699. A similar reaction of isocyanide 698 with Schiff bases provides imidazoles 700. In both cases, use of unsubstituted isonitriles 697 in the reactions leads to heterocycles 699 and 700 with R1 = H (Scheme 108) <1997H(44)67>. 

The acidity of the propargylic proton of the starting compound 18 allows the equilibration with the allene 19 induced by bases such as tertiary amines or alcoholates (Scheme 7.4). Such prototropic rearrangements furnish the title compounds 19 with at least one proton at the terminal carbon atom, often in good yields. The EWG group involves carboxylic acids [33], esters [34], ketones [35, 36], isonitriles [37], sul-fones [38], sulfoxides [39, 40] and phosphonates [41], The oxidation of easily accessi-... 

The following compounds are unaffected by bis(p-methoxyphenyl) telluroxide dithi-olanes, enamines, aldehydes, ketones, alcohols, pyrroles, indoles, amino acids, aromatic amines, monohydroxyarenes, esters, hindered thiocarbonates, isonitriles, oximes, arylhy-drazones, sulphides, and selenides. ... 

Esters of -hydroxy- or )8-mercapto-AAs react with n-butyl isonitrile to give 5-substituted methyloxazoline (or thiazoline)-4-carboxylates in the presence of PdCla as a catalyst (74SC97). The enamine-protected AAs were also tranformed into oxazolidin-5-ones after reaction with alkyl chloroform-ates (Scheme 28) (75S724). 

Guanidines have been prepared by the reaction between an amine, or an amine salt, and a host of other reagents, such as a thiourea in the presence of lead or mercuric oxide [83, 157, 158], carbodi-imides [140, 174, 175],calcium cyanamide [176, 177], isonitrile dichlorides [178—180], chloroformamidines [181], dialkyl imidocarbonates [182], orthocarbonate esters [183], trichloro-methanesulphenyl chloride [184], and nitro- or nitroso-guanidines [185-188]. Substituted ureas can furnish guanidines, either by treatment with amines and phosphorus oxychloride [189], or by reaction with phenylisocyanate [190] or phosgene [191]. 

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). 

One way to gain fast access to complex stmctures are multicomponent reactions (MCRs), of which especially the isocyanide-based MCRs are suitable to introduce peptidic elements, as the isonitrile usually ends up as an amide after the reaction is complete. Here the Ugi-4 component reaction (Ugi CR) is the most suitable one as it introduces two amide bonds to form an M-alkylated dipeptide usually (Fig. 2). The Passerini-3CR produces a typical element of depsipeptides with ester and amide in succession, and the Staudinger-3CR results in p-lactams. The biggest unsolved problem in all these MCRs is, however, that it is stUl close to impossible to obtain products with defined stereochemistry. On the other hand, this resistance, particularly of the Ugi-reaction, to render diastereo- and enantioselective processes allows the easy and unbiased synthesis of libraries with all stereoisomers present, usually in close to equal amounts. 

The only known example of 2-monoalkylaminopyran 123 in the series of tetrahydrochromenes was obtained by the less common three-component reaction of alkylisonitriles 124, acetylenedicarbonic esters 125, and dimedone or 1,3-cyclohexanedione 103 (03M1585) (Scheme 42). This example illustrates how the isonitrile —N =C group can be involved in the formation of a 2-aminopyran ring, similar to the other groups with triple bonds - nitrile C=N and alkynyl C=C. 

C=0)-halogen, 0-(C=0)-halogen, S02-halogen, N=C=0, N=C=S, N-C(=S)-N Acyclic C(=0)-S, acyclic C(=S)-0, acyclic N=C=N Anhydride, aziridine, epoxide, ortho ester, nitroso Quaternary amines, methylene, isonitrile Acetals, thioacetal, N-C-O acetals Nitro group, >1 chlorine atom... 

Oxazoles. Activated isonitriles react with selenol esters in the presence of triethylamine and Cu20 at 25° to form oxazoles, presumably via a j8-keto isonitrile (equation I).1... 

Various approaches have been used to prepare pyrroles on insoluble supports (Figure 15.1). These include the condensation of a-halo ketones or nitroalkenes with enamines (Hantzsch pyrrole synthesis) and the decarboxylative condensation of N-acyl a-amino acids with alkynes (Table 15.3). The enamines required for the Hanztsch pyrrole synthesis are obtained by treating support-bound acetoacetamides with primary aliphatic amines. Unfortunately, 3-keto amides other than acetoacetamides are not readily accessible this imposes some limitations on the range of substituents that may be incorporated into the products. Pyrroles have also been prepared by the treatment of polystyrene-bound vinylsulfones with isonitriles such as Tosmic [28] and by the reaction of resin-bound sulfonic esters of a-hydroxy ketones with enamines [29]. 

Sodium cyanide solution dissolves certain metals (I) with absorption of oxygen, e.g.. gold, silver, mercury, lead, and (2) with evolution of hydrogen, e.g.. copper, nickel, iron. zinc, aluminum, magnesium and solid sodium cyanide, when heated with certain oxides, e.g.. lead monoxide PhO. stannic oxide SnO.. yields the metal of the oxide, e.g.. lead. tin. respectively. and sodium cyanate NaCNO. Two classes of esters arc known, cyanides or nitriles, and isocyanides, isonitriles or carbylatnincs. the latter being very poisonous and of marked nauseating odor... 

Except for the well-documented conjugate additions of diethylaluminum cyanide,92 triethylaluminum-hydrogen cyanide and Lewis acid-tertiary alkyl isonitriles,93 examples of Lewis acid catalyzed conjugate additions of acyl anion equivalents are scant Notable examples are additions of copper aldimines (233),94, 94b prepared from (232), and silyl ketene acetals (234)940 to a,(3-enones which afford 1,4-ketoal-dehydes (235) and 2,5-diketo esters (236), respectively (Scheme 37). The acetal (234) is considered a glyoxylate ester anion equivalent. 

The synthesis of 6-substituted pipecolic acid derivatives has been carried out, in most cases with excellent stereoselectivities (> 95 5 transicis) and yields, by U-3CR between six-membered cyclic imines 53, carboxylic acids and the convertible isonitriles 52. Representative examples are reported in Scheme 1.20. On the other hand, when the chirality was present only on the isocyanide no stereoselectivity was observed, as expected [57]. In situ treatment of enamides 54 with an appropriate nucleophile allowed the conversion into the final products. The same trend in stereoselectivity was observed when similar imines were condensed with isocyanoace-tic acid methyl ester and Boc-glycine to give a series of tripeptides [58]. 

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