Amino acids Weinreb amides

A useful modification of the Knorr pyrrole synthesis was developed in the laboratory of J.M. Hamby for the construction of tetrasubstituted pyrroles. The necessary a-amino ketones were prepared from A/-methoxy-A/-methylamides of amino acids (Weinreb amides). These Weinreb amides were prepared by the mixed anhydride method and treated with excess methylmagnesium bromide in ether to afford the corresponding Cbz-protected a-amino ketones in excellent yield. The Cbz group is removed by catalytic hydrogenation in the presence of the active methylene compound (e.g., acetoacetic ester), the catalyst is then filtered and the resulting solution is heated to reflux to bring about the condensation. 

This approach was also found to be successfully applicable to the asymmetric alkylation of Weinreb amide derivative 31, utilizing 9f as a catalyst (Scheme 11.6). The resultant optically active a-amino acid Weinreb amides 32 were efficiently... 

In 2001, De Luca and GiacomeUi " reported a new simple and high-yielding one-flask synthesis of Weinreb amides from carboxylic acids and A-protected amino acids that uses different 1,3,5-triazine derivatives (such as 236) as the coupling agents (Scheme 104). The method allows the preparation of Weinreb amides 237 and hydroxamates as O-benzyl and 0-silyl hydroxamates that can be easily transformed into hydroxamic acids. 

The other stereoselective synthesis/281 shown in Scheme 8, foresees conversion of Boc-L-Asp-OtBu 20 into the related (3-aldehyde 22 via the Weinreb amide 21 and its reduction with diisobutylaluminum hydride (DIBAL-H). Wittig condensation of 22 with the ylide derived from (3-carboxypropyl)triphenylphosphonium bromide using lithium hexamethyldisilaza-nide at —78 to 0°C, produces the unsaturated compound 23 which is catalytically hydrogenated to the protected L-a-aminosuberic acid derivative 24. Conversion of the co-carboxy group into the 9-fluorenylmethyl ester, followed by TFA treatment and reprotection of the M -amino group affords Boc-L-Asu(OFm)-OH (25). 

Different solid-phase techniques for the synthesis of C-terminal peptide aldehydes have gained much attention and allowed greater accessibility to such compounds. Solid-phase techniques have been used to synthesize peptide aldehydes from semicarbazones, Weinreb amides, phenyl esters, acetals, and a, 3-unsaturated y-amino acids)47-50,60 63 The examples presented below use unique linkers to enhance the automated efficiency of C-terminal peptide aldehyde synthesis)47 For instance, the reduction of phenyl esters led to the aldehyde as the major product, but also a small amount of alcohol)50 The cleavage of u,p-unsaturated y-amino acids via ozonolysis yielded enantiomeric pure C-terminal peptides)49,61 The semicarbazone from reduction of peptide esters technique laid the initial foundation for solid-phase synthesis. Overall, Weinreb reduction is an ideal choice due to its high yields, optical purity, and its adaptability to a solid-phase platform)47 ... 

Horner-Emmons reaction of N-terminal blocked aldehyde 1 with sulfonylphosphonates in the presence of sodium hydride gives the amino acid vinyl sulfone 2, which is deprotected with acid and converted into its chloride or tosylate salt 3 and coupled by the mixed anhydride method with an N-terminal protected peptide or amino acid to give the desired peptide vinyl sulfones 4 (Scheme 2). 4 5 N-Terminal protected aldehydes 1 are obtained from reduction of Boc amino acid V-methoxy-A-methylamides (Weinreb amides, see Section 15.1.1) by lithium aluminum hydride. 9 The V-methoxy-V-methylamide derivatives are prepared by reaction of Boc amino acids with N,O-dimethylhydroxylamine hydrochloride in... 

The best way to prepare peptide aldehydes from the corresponding N -protected amino acids is by using a handle based on the Weinreb amide.f This commercial handle allows classical solid-phase elongation of peptides using protected Boc or Fmoc amino adds and, at the end of the synthesis, the peptide aldehyde is formed by reduction and concomitant cleavage from the resin with lithium aluminum hydride. Although the 4-hydro-xybenzoic acid handle also allows the preparation of peptide aldehydes by reduction of the resin-bound phenyl ester with lithium tri-tert-butoxyaluminum hydride, a noixture of the aldehyde and the alcohol is always formed. 

Polymer-bound reagents have also been used. The synthetically important Weinreb amides [RCON(Me)OMe, see 16-82] can be prepared from the carboxylic acid and MeO(Me)NH HCl in the presence of tributylphosphine and 2-pyridine-A -oxide disulfide. Di(2-pyridyl)carbonate has been used in a related reaction that generates amides directly. The reaction of a carboxylic acid and imidazole under microwave irradiation gives the amide. Microwave irradiation of a secondary amine, formic acid, 2-chloro-4,6-dimethoxy[l,3,5]tria-zine, and a catalytic amount of DMAP (4-dimethylaminopyridine) leads to the formamide. ° Ammonium bicarbonate and formamide converts acids to amides with microwave irradiation. Lactams are readily produced from y- or 8-amino acids, for example. 

The monomers are prepared by the homologation of N-protected amino acid aldehydes. Boc-protected amino aldehyde was synthesized in solution via Weinreb amide reduction with LiAlH4.Then, using a Wittig reaction, it was transformed into an olefin bearing an ethyl ester group, which was subsequently saponified. 

Acyl fluorides. Carboxylic acids are readily transformed into acid fluorides by this reagent in the presence of i-Pr2NEt. Weinreb amides can be prepared henceforth. W-Protected chiral a-amino acids are derivatized without racemization. 

The Swem oxidation of A-Fmoc-protected -amino alcohols 8 (Scheme 4) and the reduction of Weinreb amides prepared from Fmoc-a-amino acids with LiAlH4 at — 78°C were compared [83]. Both approaches afforded comparable synthetic yields, typically between 70 and 90% of the... 

Modern alternatives for the assembly of the a-aminocarbonyl component include the reaction of a 2-bromoketone with sodium diformamide producing an a-formamido-ketone, " and the reaction of a Weinreb amide of an A-protected a-amino acid with a Grignard reagent, then release of the A-protection in the presence... 

Scheme 19 Synthesis of unnatural amino acids via supported Weinreb amides...

Acyl oxazolidinones 50-52 are easily prepared from commercially available chiral starting materials. As shown in Scheme 4.6, treatment of the amino-acid-derived amino alcohols with diethyl carbonate, followed by N-acylation, affords 54 [6, 46], The removal of the auxiliary following the aldol addition reactions proceeds smoothly under a variety of mild conditions to afford carboxylic acids 56 (UO2H) [47, 50], primary alcohols 57 (LiBH,) [51], esters 58 (Ti(OBn)4) [52], or Weinreb amides 59 [51]. 

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