Carlos Javier Saavedra

Catalytic, One-Pot Synthesis of β-Amino Acids from α-Amino Acids. Preparation of (α,β-Peptide Derivatives

The one-pot conversion of readily available alpha-amino acid into beta-amino acid derivatives was carried out in good yields. The method is a sequential process initiated by a tandem radical decarboxylation-oxidation reaction; the resulting acyliminium ion was trapped by silyl ketenes. Stoichiometric and catalytic versions of this reaction were developed and then applied to prepare modified di- and tripeptides. Interestingly, some tripeptides formed expanded beta-turns in the solid state.

Conformation and Chiral Effects in α,β,α-Tripeptides

Short α,β,α-tripeptides comprising a central chiral trisubstituted β(2,2,3)*-amino acid residue form unusual γ-turns and δ-turns in CDCl(3) and DMSO-d(6) solutions but do not form β-turns. Thermal coefficients of backbone amide protons, 2D-NMR spectra, and molecular modeling revealed that these motifs were strongly dependent on the configuration (chiral effect) of the central β-amino acid residue within the triad. Accordingly, SSS tripeptides adopted an intraresidual γ-turn like (C6) arrangement in the central β-amino acid, whereas SRS diastereomers preferred an extended δ-turn (C9) conformation. A different SRS-stabilizing bias was observed in the crystal structures of the same compounds, which shared the extended δ-turn (C9) found in solution, but incorporated an additional extended β-turn (C11) to form an overlapped double turn motif.

Customizable units in di- and tripeptides: selective conversion into substituted dehydroamino acids.

The selective conversion of serine or threonine units of di- and tripeptides into substituted dehydroamino acids is reported. Thus, these common α-amino acids undergo a scission-phosphorylation process to give α-amino phosphonate residues. A Horner-Wadsworth-Emmons reaction with aldehydes or ketones follows to afford the final products with excellent Z-stereoselectivity (Z:E > 98:2). In this way, a single peptide precursor can selectively be transformed into a variety of derivatives.

Synthesis of α,γ-peptide hybrids by selective conversion of glutamic acid units.

The site-selective modification of small peptides at a glutamate residue allows the ready preparation of α,γ-hybrids. In this way, a single peptide can be transformed into a variety of hybrid derivatives. The process takes place under very mild conditions, and good global yields are obtained.

Frontispiece: Metal‐Free, Site‐Selective Peptide Modification by Conversion of “Customizable” Units into β‐Substituted Dehydroamino Acids

Our site-selective modification of serine or threonine units in peptides allows the generation of β-substituted dehydroamino acids, which increase peptide resistance to hydrolysis and may improve their biological properties. Both the terminal and internal positions can be modified, and different customizable units can be activated separately. Remarkably, high Z selectivity is achieved, even at internal positions. The conversion involves a one-pot oxidative radical scission/phosphorylation process by using the low-toxicity (diacetoxyiodo)benzene/iodine system as the scission reagent. The resulting α-amino phosphonates undergo a Horner-Wadsworth-Emmons reaction to produce the dehydroamino acid derivatives (in a Z/E ratio of usually >98:2) under mild and metal-free conditions.