Helices and other secondary structures of beta- and gamma-peptides.

The principal secondary structural motifs adopted by peptides assembled from beta-amino acid units are discussed: the 14-, 12-, 10-, 12/10-, and 8-helices, as well as the hairpin turn, extended structures, stacks, and sheets. Features that promote a particular folding propensity are outlined and illustrated by structures determined in solution (NMR) and in the solid-state (x-ray). The N-C(beta)-C(alpha)-CO dihedral angles from molecular dynamics simulations, which are indicative of a particular secondary structure, are presented. A brief description of a helix and a turn of gamma-peptides is also given.

N-linked glycosylated beta-peptides are resistant to degradation by glycoamidase A.

Beta-peptides are resistant to degradation by a variety of proteolytic enzymes that rapidly degrade natural alpha-peptides. This is one of many characteristics that make beta-peptides an attractive class of compounds for drug discovery efforts. To further understand the molecular recognition properties of beta-peptides and the ability of enzymes to degrade them, we have synthesized a series of N-linked glycosylated beta- and alpha-peptides, and tested their stability towards a glycosidase. We found that glyco-beta-peptides that contain N-acetylglucosamine (1) or N,N-diacetylchitobiose (2) are completely stable to degradation by glycoamidase A. In comparison, the glyco-alpha-peptides 3 and 4 containing N-acetylglucosamine or N,N-diacetylchitobiose are degraded. Inhibition experiments using increasing concentrations of a glyco-beta-peptide fail to inhibit degradation of the corresponding glyco-alpha-peptide, even when the glyco-beta-peptide is at a 128-fold higher concentration than the glyco-alpha-peptide. Evidently, the glyco-beta-peptides have a much weaker affinity for the active site of the glycosidase than the corresponding glyco-alpha-peptide. These and the results with proteolytic enzymes suggest that the additional CH(2) group introduced into the alpha-amino acid residues causes beta-peptides not to be recognized by hydrolytic enzymes. The results described herein suggest the potential of beta-peptides that are functionalized with carbohydrates for biological and biomedical investigations, without having to be concerned about the carbohydrate being removed.

Exploring the antibacterial and hemolytic activity of shorter- and longer-chain beta-, alpha,beta-, and gamma-peptides, and of beta-peptides from beta2-3-aza- and beta3-2-methylidene-amino acids bearing proteinogenic side chains--a survey.

The antibacterial activities of 31 different beta-, mixed alpha/beta-, and gamma-peptides, as well as of beta-peptides derived from beta2-3-aza- and beta3-2-methylidene-amino acids were assayed against six pathogens (Enterococcus faecalis, Staphylococcus aureus, Streptococcus pneumoniae, Escherichia coli, Klebsiella pneumoniae, and Pseudomonas aeruginosa), and the results were compared with literature data. The interaction of these peptides with mammalian cells, as modeled by measuring the hemolysis of human erythrocytes, was also investigated. In addition to those peptides designed to fold into amphiphilic helical conformations with positive charges on one face of the helix, one new peptide with hemolytic activity was detected within the sample set. Moreover, it was demonstrated that neither cationic peptides used for membrane translocation (beta3-oligoarginines), nor mixed alpha/beta- or gamma-peptides with somatostatin-mimicking activities display unwanted hemolytic activity.

The proteolytic stability of 'designed' beta-peptides containing alpha-peptide-bond mimics and of mixed alpha,beta-peptides: application to the construction of MHC-binding peptides.

Whereas alpha-peptides are rapidly degraded in vivo and in vitro by a multitude of peptidases, substrates constructed entirely of or incorporating homologated alpha-amino acid (i.e., beta-amino acid) units exhibit a superior stability profile. Efforts made so far to proteolytically hydrolyze a beta-beta peptide bond have not proved fruitful; a study aimed at breaching this proteolytic stability is discussed here. A series of such bonds have been designed with side-chain groups similar in relative positions (constitution) and three-dimensional arrangements (configuration) as found about alpha-peptidic amide bonds. Increasing the prospect for degradation would permit the tuning of beta-peptide stability; here, however, no cleavage was observed (1, 2, 4-6, Table 1). Peptides comprised of alpha- and beta-amino acids (mixed alpha,beta-peptides, 8-11) are expected to benefit from both recognition by a natural receptor and a high level of proteolytic stability, ideal characteristics of pharmacologically active compounds. Beta3-peptides containing alpha-amino acid moieties at the N-terminus are degraded, albeit slowly, by several peptidases. Of particular interest is the ability of pronase to cleave an alpha-beta peptide bond, namely that of alphaAla-beta3 hAla. Significantly, successful hydrolysis is independent of the configuration of the beta-amino acid. Some of the alpha,beta-peptides discussed here are being investigated for their binding affinities to class I MHC proteins. The computer-programming steps required to prepare alpha,beta-peptides on an automated peptide synthesizer are presented.

Probing the proteolytic stability of beta-peptides containing alpha-fluoro- and alpha-hydroxy-beta-amino acids.

One of the benefits of beta-peptides as potential candidates for biological applications is their stability against common peptidases. Attempts have been made to rationalize this stability by altering the electron availability of a given amide carbonyl bond through the introduction of polar substituents at the alpha-position of a single beta-amino acid. Such beta-amino acids (beta-homoglycine, beta-homoalanine), containing one or two fluorine atoms or a hydroxy group in the alpha-position, were prepared in enantiopure form. A versatile method for preparing these alpha-fluoro-beta-amino acids by the homologation of appropriate alpha-amino acids and C-OH->C-F or C=O-->CF(2) substitution with DAST, is described. Consequently, a series of beta-peptides possessing an electronically modified residue at the N terminus or embedded within the chain was synthesized, and their proteolytic stability was investigated against a selection of enzymes. All ten beta-peptides tested were resilient to proteolysis. Introducing a polar, sterically undemanding group, into the alpha-position of beta-amino acids in a beta-peptide chain does not appear to facilitate localized or general enzymatic degradation.

A practical and efficient synthesis of the C-16-C-28 spiroketal fragment (CD) of the spongistatins.

A practical and efficient route to the CD spiroketal (C-16-C-28) of the spongistatins is reported. Two stereocenters are introduced from chiral building blocks with the remainder introduced by substrate-controlled transformations. The key beta-keto-1,3-dithiane intermediate is generated by a dithiol conjugate addition to an ynone and the 1,3-dithiane unit in the C-ring plays a key role in the spiroketalization and subsequent epimerization. The synthesis requires 24 steps, with a longest linear sequence of 19 steps in an overall yield of 14.5% (for the longest linear sequence). [reaction: see text]

Synthesis of the C-1-C-28 ABCD unit of spongistatin 1.

The synthesis of the C-1-C-28 ABCD fragment of spongistatin is described. Anti-selective boron-mediated aldol coupling of a CD spiroketal ketone fragment to an AB spiroketal aldehyde unit forms the desired C1-C28 advanced intermediate. Other features include the double conjugate addition of a dithiol to an ynone to generate the key beta-keto-dithiane unit required for the synthesis of the AB spiroketal fragment. [reaction: see text]

Development of beta-keto 1,3-dithianes as versatile intermediates for organic synthesis.

beta-Keto 1,3-dithianes can be generated by the double conjugate addition of dithiols to propargylic ketones, esters and aldehydes in excellent yields. As masked 1,3-dicarbonyl systems these substrates can be converted to a range of functionalised oxygen-containing heterocycles that can be used in natural product synthesis.