Peptide esters, reduction

Scheme 1 Reduction of Peptide Esters to Peptide Aldehydes with Diisobutylaluminum Hydride...

Amino acid and peptide aldehydes with one to three residues have been prepared successfully using diisobutylaluminum hydride. Z-Protected amino aldehydes such as Z-Leu-H, Z-Phe-H, Z-Cys(Bzl)-H, Z-Pro-H have been synthesized with little or no racemization (Table l). 5 The diisobutylaluminum hydride reduction can be used with both peptide esters and Z amino acid esters. However, the Boc protecting group is less stable when refluxed with diisobutylaluminum hydride, thus resulting in its loss while reducing Boc-Ala-OMe or Boc-Ser(OBzl)-OMe. 13 ... 

Peptide aldehydes 1 can be synthesized effectively by the oxidation of peptide alcohols 15, which are readily available without racemization by reduction of peptide esters 9 with sodium borohydride-lithium chloride (Scheme 5). The peptide alcohols 15 can be readily oxidized to afford enantiomerically pure aldehydes using Parikh-Doering or Dess-Martin reagents. This route is less popular than the previously described reductive methods due to (1) the sensitivity of the aldehydes to further oxidation, (2) racemization under the reaction conditions, and (3) instability of the products under the reaction conditions. 

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 ... 

Carboxy terminal amino acid or peptide thiols are prepared from various p-amino alcohols by conversion into a thioacetate (R2NHCHR1CH2SAc) via a tosylate followed by saponification.Several methods have been used to prepare N-terminal peptide thiols, the most common procedure is the coupling of (acetylsulfanyl)- or (benzoylsulfanyl)alkanoic acids or add chlorides with a-amino esters or peptide esters, followed by deprotection of the sulfanyl and carboxy groups. 8 16 Other synthetic methods include deprotection of (trit-ylsulfanyl)alkanoyl peptides, 1718 alkaline treatment of the thiolactones from protected a-sulfanyl acids, 19 and preparation of P-sulfanylamides (HSCH2CHR1NHCOR2, retro-thior-phan derivatives) from N-protected amino acids by reaction of P-amine disulfides with carboxylic acid derivatives, followed by reduction. 20,21 In many cases, the amino acid or peptide thiols are synthesized as the disulfides and reduced to the corresponding thiols by the addition of dithiothreitol prior to use. 

Analogues of 70 have been prepared by various methods including nucleophilic displacement of triflate esters attached directly to the oxetane ring (see Section 2.05.7.2) <2001TL4247>, from xylose, 145, via the benzyl-idene-protected oxetane, 146 (Scheme 24) <2004TA2667>, or from L-rhamnose, 147, via a l,4-lactone-2-O-triflate, 148 (and key oxetane 149 (Scheme 25)) <2004TA2681>. The /3-azidoester monomers formed by these methods were converted to the /3-amino acids and subsequently to /3-peptides by reduction of the azide and ester hydrolysis. 

Reduction can be achieved selectively under mild conditions by using esters more electronegative than methyl esters such as trifluoroethyl esters. E. s. S. Taka-hashi and L. A. Cohen, J. Org. Chem. 55, 1505 (1970) reduction of peptide esters in aq. medium s. O. Yonemitsu, T. Hamada, and Y. Kanaoka, Chem. Pharm. Bull. I7y 2075 (1969). 

With the dicyclohexylcarbodiimide (DCQ reagent racemization is more pronounced in polar solvents such as DMF than in CHjCl2, for example. An efficient method for reduction of racemization in coupling with DCC is to use additives such as N-hydroxysuccinimide or l-hydroxybenzotriazole. A possible explanation for this effect of nucleophilic additives is that they compete with the amino component for the acyl group to form active esters, which in turn reaa without racemization. There are some other condensation agents (e.g. 2-ethyl-7-hydroxybenz[d]isoxazolium and l-ethoxycarbonyl-2-ethoxy-l,2-dihydroquinoline) that have been found not to lead to significant racemization. They have, however, not been widely tested in peptide synthesis. 

A benzyl carbonate was prepared in 83% yield from the sodium alkoxide of glycerol and benzyl chloroformate (20°, 24 h). It was also prepared by a lipase-catalyzed ester exchange with allyl benzyl carbonate. It is cleaved by hydrogenolysis (H2/Pd-C, EtOH, 20°, 2 h, 2 atm, 76% yield) and electrolytic reduction (—2.7 V, R4N X, DMF, 70% yield). A benzyl carbonate was used to protect the hydroxyl group in lactic acid during a peptide synthesis." ... 

This ester, developed for peptide synthesis, is prepared by the standard DCC coupling protocol and is cleaved reductively with SnCl2 (MeOH, 25°, 5 h) followed by treatment with mild base to effect quinonemethide formation with release of the acid in 75-95% yield. ... 

Santagada and coworkers have disclosed a reductive amination method for the generation of a reduced peptide bond by reaction of a protected amino acid aldehyde with an N-deprotected amino ester using sodium cyanoborohydride as reducing agent [296]. 

HC1 (18°C), recovery by rotary evaporation, and electrolytic reduction. Once isolated, the free dipetide ester (or acid) is available for chain lengthening (cf. Scheme 1) and Table VII gives examples of peptides prepared using this approach. 

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