Partial [alphaMe]Aun scan of [l-Leu11-OMe]-trichogin GA IV, a membrane active synthetic precursor of the natural lipopeptaibol.

We synthesized using solution-phase methods three analogs of [l-Leu11-OMe] trichogin GA IV, a membrane active synthetic precursor of the lipopeptaibol antibiotic in which the N-terminal n-octanoyl group and each of the three Aib residues in positions 1, 4 and 8 are replaced by an acetyl group and the lipophilic Calpha,alpha-disubstituted glycine l-(alphaMe)Aun, respectively [partial (alphaMe)Aun scan]. FT-IR absorption and CD analyses unequivocally show that the main three-dimensional structural features of [l-Leu11-OMe] trichogin GA IV are preserved in the analogs. Also, [l-Leu11-OMe] trichogin GA IV and the three Nalpha-acetylated l-(alphaMe)Aun analogs exhibit strictly comparable membrane-modifying properties. Taken together, these results strongly favor the conclusion that a shift of the long hydrocarbon moiety from the Nalpha-blocking group to the side-chain of the 1, 4 or 8 residue does not have any significant effect on the conformational properties or the membrane activity of [l-Leu11-OMe] trichogin GA IV and, by extension, of the natural lipopeptaibol.     

First homo-peptides undergoing a reversible 3(10)-helix/alpha-helix transition: critical main-chain length

The difference in length between the more elongated peptide 3(10)-helix and the more compact alpha-helix is about 0.4 A/residue. This property makes the 3(10)-/alpha-helix reversible conversion very promising as a molecular switching tool between the N- and C-terminal functions of a peptide backbone. In this work, using homo-peptides of various main-chain length, all based on the strongly helicogenic, Calpha-tetrasubstituted alpha-amino acid Calpha-methyl-L-valine, we show that a well defined, solvent controlled, reversible 3(10)-/alpha-helix transition takes place even in a homo-oligomer as short as a terminally blocked hexapeptide. Homo-peptide sequences blocked as a urethane or an acetamide at the N-terminus and as a methyl ester or an N-alkyl amide at the C-terminus are all appropriate. The nature of the occurring helical species in the various solvents tested was assessed by electronic or vibrational circular dichroism.     

Chiral, fully extended helical peptides

The synthesis of the N-protected (blocked) homo-peptide esters from the chiral C(α)-ethyl, C(α)-n-pentylglycine was performed in solution to the hexapeptide level. The conformational propensity exhibited by these oligomers in chloroform solution and in the crystal state was assessed by use of FTIR absorption, NMR, and X-ray diffraction. The results indicated that fully extended helical structures (2.0(5)-helices) are overwhelmingly adopted irrespective of the peptide main-chain length. This oligomeric series is of great interest as it is characterized by the longest C ( i )(α) ,…, C ( i+1 )(α) (per residue) separation achievable in the class of chiral, rigid, helical peptide spacers based on α-amino acids.     

Factors governing 3(10)-helix vs alpha-helix formation in peptides: percentage of C(alpha)-tetrasubstituted alpha-amino acid residues and sequence dependence

As an additional step toward the dissection of the factors responsible for the onset of 3(10)-helix vs alpha-helix in peptides, in this paper we describe the results of a three-dimensional (3D) structural analysis by x-ray diffraction of the N(alpha)-acylated heptapeptide alkylamide mBrBz-L-Iva-L-(alphaMe)Val-L-Abu-L-(alphaMe)Val-L-(alphaMe)Phe-L-(alphaMe)Val-L-Iva-NHMe characterized by a single (L-Abu3) C(alpha)-trisubstituted and six C(alpha)-tetrasubstituted alpha-amino acids. We find that in the crystal state this peptide is folded in a mixed helical structure with short elements of 3(10)-helix at either terminus and a central region of alpha-helix. This finding, taken together with the published NMR and x-ray diffraction data on the all C(alpha)-methylated parent sequence and its L-Val2 analog (also the latter heptapeptide has a single C(alpha)-trisubstituted alpha-amino acid) strongly supports the view that one C(alpha)-trisubstituted alpha-amino acid inserted near the N-terminus of an N(alpha)-acylated heptapeptide alkylamide sequence may be enough to switch a regular 3(10)-helix into an essentially alpha-helical conformation. As a corollary of this work, the x-ray diffraction structure of the N(alpha)-protected, C-terminal tetrapeptide alkylamide Z-L-(alphaMe)Val-L-(alphaMe)Phe-L-(alphaMe)Val-L-Iva-NHMe, also reported here, is clearly indicative of the preference of this fully C(alpha)-methylated, short peptide for the 3(10)-helix. As the same terminally blocked sequence is mixed 3(10)/alpha-helical in the L-Abu3 heptapeptide amide but regular 3(10)-helical in the tetrapeptide amide and in the parent heptapeptide amide, these results point to an evident plasticity even of a fully C(alpha)-methylated short peptide.     

Structural features and conformational equilibria of 310-helical peptides in solution by spectroscopic and molecular mechanics studies

The structural features and conformational equilibria of a series of short, linear Calpha-methylvaline [(alphaMe)Val]-based peptides in methanol were investigated by combining fluorescence resonance energy transfer measurements and molecular mechanics data. IR spectra were employed to determine their secondary structure, which exhibits an intramolecularly H-bonded, 3(10)-helix conformation that is affected by backbone distortions that are enhanced by the shortness of the main chain.     

Molecular spacers for physicochemical investigations based on novel helical and extended peptide structures

A proper understanding of the detailed nature and mechanism of physicochemical interactions depends heavily upon our ability to design and synthesize conformationally constrained 3D structures whose intercomponent geometry (either rigorously rigid or able to undergo destructuration, if required, but in all cases precisely tunable) would be well defined. To this end we have recently reported a few initial studies and we are currently working on the exploitation of stable, short, helical peptide spacers based on achiral and/or chiral Calpha-tetrasubstituted alpha-amino acids. These building blocks are known to force the peptides either to predominantly fold into a 3(10)-helical structure or to adopt a fully extended, planar 2.0(5)-helix. The systems under investigation involve a donor and an acceptor moiety linked to the N- and C-termini of the oligopeptide spacer main chain. By increasing the number of intervening residues the donor.acceptor separation can be easily modulated. This review highlights details of these two novel peptide secondary structures and their use as molecular spacers in physicochemical investigations.     

Turn stabilization in short peptides by C(alpha)-methylated alpha-amino acids

The crystal-state conformations of three protected tripeptides, four tetrapeptides, and one pentapeptide, heavily based on the chiral C(alpha)-methylated alpha-amino acids Iva, (alpha Me)Nva, and (Me)Val, were assessed by X-ray diffraction analyses. The eight peptide sequences are as follows: Z-(D-Iva)2-D-Val-OMe, Z-D-Iva-L-Iva-Gly-OtBu, Z-L-Pro-D-Iva-L-Iva-Gly-OtBu, Z-L-Pro-L-Iva-D-Iva-Gly-OtBu, Z-Aib-[L-(alpha Me)Nva]2-OtBu, Ac-[L-(alpha Me)Val]3-D-(alpha Me)Val-OtBu, Z-[L-(alpha Me)Val]4-OH, and Z-L-Ala-[L-(alpha Me)Nva]4-OtBu. Two independent molecules were observed in the asymmetric units of Z-D-Iva-L-Iva-Gly-OtBu and Z-Aib-[L-(alpha Me)Nva]2-OtBu, while three independent molecules were seen in Z-L-Ala-[L-(alpha Me)Nva]4-OtBu. All peptides are folded in a single or multiple beta-turn conformations. Interestingly: (i) a water bridge within the N-terminal beta-turn is seen in Z-L-Pro-L-Iva-D-Iva-Gly-OtBu (dihydrate), and (ii) the hydroxyl group of the C-terminal carboxyl functionality of Z-[L-(alpha Me)Val]4-OH generates an oxy-analogue of a beta-turn. The N-terminal beta-turn is missing in molecules A and B, but it does occur, although poorly stabilized, in molecule C, of Z-L-Ala-[L-(alpha Me)Nva]4-OtBu.     

Recent contributions of electronic circular dichroism to the investigation of oligopeptide conformations

Recent applications in our laboratories of electronic circular dichroism to the study of peptide secondary structures and their changes under external stimuli are briefly reviewed. More specifically, this article deals with: 1). characterization of a novel peptide conformation; 2). origin of amino acid homo-chirality on Earth; 3). bend and helical peptides as spacers; and 4). transfer and propagation of chirality in peptides.