Aldehydes from Weinreb amide reduction

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). 

The reduction of Weinreb amide derivatives by LiAIH4 is not suitable for the synthesis of aspartyl or glutamyl aldehydes. Recently, Paris et a I.129 described the synthesis of various bland side-chain protected aspartyl or glutamyl aldehydes from the corresponding Weinreb amides by using bulky hydrides such as lithium tri-/ert-butoxyaluminum hydride. 

Enantiomerically pure a-amino aldehydes containing nonpolar side chains such as Boc-Ala-H, Boc-Leu-H, and Boc-Phe-H are synthesized by lithium aluminum hydride reduction of the corresponding Weinreb amides, Boc-Ala-N(Me)OMe, Boc-Leu-N(Me)OMe, and Boc-Phe-N(Me)OMe, respectively (Table 4). The lithium aluminum hydride does not affect the Boc group due to the low temperature and short 15-minute reaction time. Successful synthesis of side-chain Bzl-protected Boc-Thr(Bzl)-H gives a 95% yield of crude product, however, reduction of N-protected aspartyl and glutamyl aldehydes from their corresponding A-methoxy-A-methylamides leads to overreduction and unreacted hydroxamateJ1920 ... 

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 intramolecular allylboration of an aldehyde function leads selectively to cir-disubstituted cyclic ethers. It has been shown that both the reactive aldehyde and the allylboronate moiety can be initially generated in situ in a masked form and then liberated simultaneously by hydrolysis of the precursor functions <1997JA7499>. This methodology was successfully applied to the one-pot synthesis of the oxocene 82, a precursor of (-l-)-laurencin (Scheme 13). A DIBAL reduction of the Weinreb amide 80, metalation with r f-butyllithium, borylation with the pinacol borate ester, and, finally, liberation of both the aldehyde and the allylboronate function by aqueous pH 7 buffer solution generated the reactive 81, which cyclized in 38% overall yield to the oxocene 82. Only the all-cis-diastereomer is formed, which means that the cyclization proceeds under high asymmetric induction from the resident stereogenic center present in 80. 

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. 

There are several ways to cleave the auxiliary from the product 7. Typical reactions include reduction with complex hydrides such as LiBH4 to obtain the alcohol 18 or transamination to the Weinreb amide and subsequent reduction with DIBAL to give the aldehyde 19 that would have been obtained from direct aldol reaction. ... 

More recently an alternative synthesis has been proposed (91) in which the fragments C1-C5 and C6-C10 were joint together under Stille conditions (92). Starting from the suitably protected P-methyl-aspartic acid (1) its reduction to the aldehyde and conversion to the trans vinyl iodide followed by staimylation with hexamethyldistannane in the presence of freshly prepared Pd(PPh3)4 led to the trans vinylstannane 2 (Fig. 6). The commercially available (S)-phenyllactic acid (3) was converted to the Weinreb amide which was methylated at the secondary alcohol function and then converted to the propargylic ketone (4). Syn-stereoselective... 

An alternative route allowed the generation of the C5 chiral center by hetero-Michael addition on cx,p-unsaturated Weinreb amide 54, which in turn could derived from aldehyde 52 through crotyltitanation and homologation (Scheme 12). Thus, crotyltitanation reaction of aldehyde 52 with (/f)-4 cleanly led to the syn-anti homoallylic alcohol 53. a, i-Unsaturated Weinreb amide 54 was obtained through a classical two-step sequence involving a Homer-Wads worth-Emmons olefination. Then, reaction of 54 with benzaldehyde mediated by potassium bis(trimethylsilyl)amide (KHMDS) afforded benzyli-dene 55 in 79% yield with an excellent diastereoselectivity (dr >95 5). After reduction to aldehyde 56, the last C1-C7 subunit was obtained in 32.7% overall yield for eight steps. 

We have focused our attention on the solid phase synthesis of such compounds and described our results here. Alternative routes for the preparation of peptide aldehydes and side-chain protected peptide aldehydes in solid phase synthesis are described. Three new linkers that are stable tmder classical Fmoc or Boc strategies have been developed to obtain the peptide aldehyde from the solid support. One of these linkers was conceptualized on the basis of the Weinreb amide (49) and the other on the basis of phenolic esters (50). Both strategies required the reduction with hydrides of the peptide-linker-resin to release the peptidic aldehydic function. The use of these two different approaches was demonstrated by the synthesis of N-protected a-amino-aldehydes and peptide aldehydes, llie third approach used the ozonolysis reaction for the generation of the desired aldehyde. This concept requires a linker incorporating a double bond in the a-position of the asymmetric carbon of the C-terminal residue that will be cleaved by ozone to produce the carbonyl function. 

Aside from the outstanding and reliable diastereoselectivity, two more advantageous features helped the method to success the easy, one-step preparation of various N-acylated derivatives from the parent oxazolidinones and the cleavage of the auxiliary by hydrolysis, transamidation to the Weinreb amide, esterification, and reduction, as outlined in Section 4.1. A typical Evans aldol procedure with phenylalanine-derived oxazolidinone (S)-47, including the preparation of propionic imide 73 and cleavage of the auxiliary, is shown in Scheme 4.47. Typically, the boron aldolate resulting from the addition to the aldehyde has to be cleaved by an oxidative work-up. The hydrolysis of the aldol adduct 211 occurs without detectable epimerization that liberates diastereomerically and enantiomerically pure carboxylic acid 212 besides the auxiliary (S)-47 [110]. 

The plan was to assemble the first carbocyclic ring of 3 by intramolecular aldol condensation of the keto aldehyde 15. The enantiomericaUy-pure secondary methyl substituent of 15 derived from the commercial monoester 10. Activation as the acid fluoride followed by selective reduction led to the volatile lactone 11. Opening of the lactone with HjCONHCHj HCl gave, after protection, the Weinreb amide 12. Alkylation of the derived hydrazone 13, selectively on the methyl group, led, after deprotection, to 15. The intramolecular aldol condensation of 15 did dehver the imstable cyclohexenone 1. Under the acidic conditions of the aldol condensation, the enol derived from the piperidone added in a Michael sense, from the axial direction on the newly-formed ring, to give the frans-fused bicyclic diketone 2. 

Conversion of solid-supported hydroxamates to aldehydes is a useful tool for the generation of C-terminal peptide-aldehydes. Martinez et aL firstly used LiAlH4-reduction for the cleavage of hydroxamates from solid supports and succeeded in synthesizing tripeptide aldehydes that could be obtained in about 40% yield after purification [83]. Reduction of Weinreb amides on... 

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