Giancarlo Zanotti

Solid State and Solution Conformation of [Ala7]‐Phalloidin: A Synthetic Phallotoxin Analogue

Phallotoxins are toxic compounds produced by poisonous mushroom Amanita phalloides and belong to the class of bicyclic peptides with a transannular thioether bridge. Their intoxication mechanism in the liver involves a specific binding of the toxins to F-actin that, consequently, prevents the depolymerization equilibrium with G-actin. Even though the conformational features of phallotoxins have been worked out in solution, the exact mechanism of interaction with F-actin is still unknown. In this study a toxic phalloidin synthetic derivative, bicyclo(Ala1-D-Thr2-Cys3-cis-4-hydroxy-Pro4-Ala5-2-mercapto-Trp6-Ala7)(S-3-->6) has been synthesized. A substitution at position 7. with an Ala residue replaces the 4,5-dihydroxy-Leu present in the natural phalloidin. This analogue has formed crystals suitable for X-ray analysis, and represents the first case for such a class of compounds. The solid-state structure as well as the solution conformation have been evaluated. NMR techniques have been used to extract interproton distances as restraints in subsequent molecular dynamics calculations. Finally, a direct comparison between structures in solution and in the solid state is presented.

Synthesis and x-ray crystal structure of a tripeptidic cyclol

Abstract Properties, spectral data and X-ray crystallographic analysis of a tetracyclic tripeptidic aza-cyclol, obtained by cyclization of CF3COOH·Pro-Phe-Pro-CNp in aqueous medium, are reported.

SOLUTION AND SOLID STATE STRUCTURE OF AN AIB-CONTAINING CYCLODECAPEPTIDE INHIBITING THE CHOLATE UPTAKE IN HEPATOCYTES

The conformational analysis of synthetic cyclodecapeptide c(Pro‐Phe‐Phe‐Aib‐Leu)2 related to the cyclolinopeptide A, in the solid state and solution, has been carried out by x‐ray diffraction and nmr spectroscopy. The structure of the monoclinic form obtained from methanol [a = 11.351(5) Å, b = 27.455(2) Å, c = 12.716(8) Å, β = 99.65(3)°; space group P21; Z = 2] shows the presence of six intramolecular NH˙˙˙CO hydrogen bonds, with formation of four turns (three of type I and one of type III) and two C16 ring structures. All peptide units are trans. The solution structure, as found by nmr, indicates that, at room temperature, the peptide is conformationally homogeneous; the structure determined is perfectly symmetrical and topologically similar to that found in the solid state. The cyclodecapeptide exhibits similar biological activity to cyclolinopeptide A.

Cyclol formation from tripeptides containing β-alanine

Attempts to synthesize stable tetrahedral intermediates (cyclols) from β-alanine containing precursors are described. Cyclization of N-(N-benzyloxycarbonyl-β-alanyl)-Phe-Pro-ONp gave N-(N-benzyloxycarbonyl-β-alanyl)cyclo-(Phe-D-Pro). Cyclization of N-(N-benzyloxycarbonyl-Ala)-βAla-Pro-ONp and of N[N-(R)-(α-hydroxyisovaleryl)-βAla]-Pro-ONp afforded the corresponding anhydrocyclols. The first example of an oxa-cyclol related to a ten-membered cyclodepsitripeptide was synthesized by acylating cyclo-(βAla-Pro) with α-benzyloxypropionyl chloride followed by hydrogenolytic removal of the O-benzyl protecting group.

Binding proteins for cyclic and linear oligopeptides in plasma membranes and the cytosol of rat hepatocytes

Using a cyclolinopeptide A analogue, the hydrophobic cyclic peptide c(-Ala-Lys-Pro-Phe-Phe-Ala-Lys-Pro-Phe-Phe-), termed CDP (cyclodecapeptide), as ligand in affinity chromatography, hepatocellular peptide binding proteins were isolated from the integral part of plasma membranes and the cytosol. The sequence of the isolated protein with MW of 50 kDa from the integral part of the plasma membrane fraction was identical to cytochrome P450 II C13 and cytochrome P450 II C22, whereas the sequence of the 54 kDa protein was identical to 3-hydroxyandrogen-UDP-glucuronosyltransferase. These proteins have also been described as binding proteins for bile acids. As shown in earlier studies, bile acids and CDP also compete for uptake into hepatocytes. In the cytosol, a further known bile acid binding protein, the glutathione-S-transferase (G-S-T) subunit Yb1, was isolated and sequenced as binding protein for CDP and also for a further cyclopeptide, the somatostatin analogue OO8, and a linear peptide with renin-inhibiting activity, EMD 55068. As shown in uptake studies using isolated basolateral plasma membrane vesicles, G-S-T was able to increase the uptake of EMD 51921, a linear peptide with renin-inhibiting potency, into the vesicles when the latter were preloaded with G-S-T. The binding of the substrate to the outside of the preloaded vesicles was not different than binding to unloaded vesicles. The maximal transport rate of the carrier-mediated/facilitated diffusion and the rate of permeation, however, were doubled in the presence of G-S-T, pointing to the involvement of intracellular binding proteins such as G-S-T in the unloading of the carrier protein and in the reduction of the free substrate concentration.

Structural Consequences of Metal Complexation of cyclo[Pro‐Phe‐Phe‐Ala‐Xaa]2 Decapeptides

The conformational features of both free and Ca2+-complexed cyclo[Pro-Phe-Phe-Ala-Xaa]2 (with Xaa= Glu(OtBu), Lys(CIZ), Leu, and Ala) in solution have been determined by NMR spectroscopy and extensive distance-geometry calculations. The decapeptides are conformationally homogeneous in solution and show common structural features in their free and complexed forms. The structures of the free form contain only trans peptide bonds and are topologically similar to the structure of gramicidin-S, folded up in two antiparallel extended structures, stabilized by interstrand hydrogen bonds, and closed at both ends by two beta-turns. In contrast, the Ca2+-complexed peptides present two cis peptide bonds and are generally similar to those observed for the metal-complexed forms of antamanide and related analogues, folded into a saddle shape with two beta-turns. The Glu(OtBu)-, Leu-, and Lys(ClZ)-containing peptides examined here maintain the biological activity of the cyclolinopeptide A in their ability to competitively inhibit cholate uptake. The natural antamanide and cyclolinopeptide A are both able to inhibit the uptake of bile salts into hepatocytes. They share the same postulated active sequence Pro-Phe-Phe. Based on our structural results, we conclude that the ability to adopt a global conformation, characterized by a clear amphipathic separation of hydrophobic and hydrophilic surfaces, is an important feature for the functioning of this class of peptides.

Phalloidin Synthetic Analogues: Structural Requirements in the Interaction with F-Actin

Synthetic derivatives of phalloidin have been investigated in solution by circular dichroism (CD) and NMR spectroscopy. They differ from natural phalloidin (PHD). bicyclo(Ala1-D-Thr2-Cys3-cis-4-hydroxy-Pro4-Ala5-2-mercapto-Trp6-(OH)2Leu7)(S-3 --> 6), in that they are modified at positions 2, 3, and 7. Among these synthetic analogues, structural differences and varying degrees of atropisomerism are found. By comparing the respective molecular models obtained by restrained molecular dynamics (RMD) simulations based on experimental NMR data, structural features that may be responsible for the different biological behavior become apparent. Our results indicate that the structural changes that result from an inversion of chirality of residue 3 lead to a complete loss of toxicity. Conversely, toxicity is less affected by the structural changes that stem from an inversion of chirality of residue 2. Moreover, unlike the other phallotoxins, when the thioether unit bridges to the opposite face of the main peptide ring, in contrast to the situation in other phallotoxins, large structural changes are observed as well as a total loss of activity. Molecular models of the synthetic phalloidin analogues have been used to investigate the necessary structural requirements for the interaction with F-actin. To this end, the F-actin/PHD model of M. Lorenz et al. was employed; docking experiments of our molecular models in the PHD binding site are presented.

Synthetic amatoxin analogue. A two-dimensional proton NMR study of S-deoxy-(Ile3)-(D-Ala7)-amaninamide.

The effect of substitution of L and D amino acids in amatoxin analogues is discussed in this paper. The structure of the analog where D-alanine substitutes for glycine in position 7 has been worked out in solution by two-dimensional NMR methods using a 500 MHz instrument. The combined use of COSY and NOESY two-dimensional spectra allows a clear assignment of the resonances. The use of the coupling constants permits the calculation of the phi angles of the backbone. The NOE effects reveal the through-space contacts between protons of different peptide units, thus determining the rigidity of the amatoxin structure. On these grounds it has been possible to elucidate the conformation of the amatoxin analogue that resembles very closely that of beta-amanitin, thus explaining the high inhibitory activity toward RNA polymerase B.

Bicyclic peptides as models of calcium binding sites: Synthesis and conformation of a homodetic undecapeptide

A bicyclic undecapeptide of sequence cyclo-(Ala(1)-Pro(2)-Asp(3)-Glu(4)-Lys(5)-Ala(6)-Pro(7)-Asp(8)-Ser(9) -Glu(10))-cyclo-(10gamma --> 5varepsilon)-Gly(11), designed to mimic the calcium coordination site I of Calmodulin, has been synthesized and its conformation and calcium binding properties have been investigated by means of CD and nmr spectroscopy. The nmr analysis of the free peptide, carried out in DMSO and in TFE/H(2)O at different pH values, shows the presence in solution of one stable conformer, exhibiting trans configuration around both Proline residues. The nmr results in both solvents suggest for the molecule a rectangular shape constituted by two antiparallel beta-strands connected by two beta-turns. Interproton distances, evaluated by NOE contacts, have been used to obtain feasible models by means of Restrained Molecular Dynamic (RMD). The average models from RMD calculations, for both solvents, exhibit good analogies with Calmodulin site I. The model system, when compared with the reference system (Asp(20)-Glu(31) segment in CaM), shows similar dimensions and an effective superimposition of the respective sequence segments Ala(1)-Glu(4) and Thr(28)-Glu(31). The remaining segments of the model peptide exhibit a bending that is intermediate between that of the free and Ca(2+)-coordinated site I. CD spectra, recorded in TFE solutions, point to a 1:1 stoichiometry for the Ca(2+)-peptide complex, with an association constant of at least 1 x 10(5) M(-1).

Intramolecular transfer of excitation energy in short linear peptides carrying naphthalene and protoporphyrin molecules. A molecular model of electron transfer/energy transfer transition

Abstract Sequential oligopeptides carrying naphthalene and protoporphyrin IX as fluorophores, covalently bound to α-amino groups of lysine residues, were investigated in methanol and water/methanol 75/25 (v/v) solutions by steady-state fluorescence, transient absorption spectra and time resolved emission measurements. Quenching of excited naphthalene chiefly takes place by transfer of excitation energy, 1N∗→P, and proceeds on a time scale of 3–8 ns (25 °C), depending on the helical periodicity of the backbone chain. According to earlier IR and CD spectral results, the oligopeptides investigated attain an α-helix conformation, which is responsible for the periodic variation of the interprobe distances. A slower ( ≈45 ns) and minor fluorescence decay was also measured, which is ascribed to exciplex emission. This finding differs from that earlier obtained with the same chromophores bound to α-helical poly( l -lysine) in water, where quenching of naphthalene was mainly due to electron transfer from ground-state porphyrin, P → 1N∗ Molecular mechanics calculations show a different topology of N and P molecules bound to the α-helix in the two systems, which is thought to be primarily responsible for the observed transition between photoinduced electron transfer and energy transfer.