Raman studies on bradykinin and a cyclic bradykinin

Laser Raman spectra of bradykinin in water, deuterium oxide, and the solid phase were recorded. From the spectra it was concluded that bradykinin conformation is comprised of ordered and unordered structure. The ordered structure appears to be some form of reverse turn. Furthermore, it seems that there is an enhancement of the turn structure in the solid phase. A cyclic cystine containing analog of bradykinin was also examined with Raman spectroscopy. The cyclic bradykinin analog gives a Raman spectrum very similar to that of the linear bradykinin and therefore must share similar conformational forms with bradykinin. The restrictive Cys-Cys disulfide in the cyclic bradykinin must serve to maintain a conformation acceptable to bradykinin receptors since the cyclic peptide exhibits biological activity.     

Mass-weighted molecular dynamics simulation of cyclic polypeptides.

A modified molecular dynamics (MD) method in which atomic masses are weighted was developed previously for studying the conformational flexibility of neuroregulating tetrapeptide Phe-Met-Arg-Phe-amide (FMRF-amide). The method has now been applied to longer and constrained molecules, namely a disulfide-linked cyclic hexapeptide, c[CYFQNC], and its linear and "pseudo-cyclic" analogues. The sampling of dehedral conformational space of teh linear hexapeptide in mass-weighted MD simulations was found to be improved significantly over conventional MD simulations, as in the case of the shorter FMRF-amide molecule studied previously. In the cyclic hexapeptide, the internal constraint of the molecule due to the intramolecular disulfide bond (hence the absence of free terminals in the molecule) does not adversely affect the significant improvement of conformational sampling in mass-weighted MD simulations over normal MD simulations. The pseudo-cyclic polypeptide is identical to the linear CYFQNC molecule in amino acid sequence (i.e., side chains of the cysteine residues are reduced), but the positions of its two terminal heavy atoms were held fixed in space such that the molecule has a nearly cyclic conformation. For this molecule, the mass-weighted MD simulation generated a wide range of polypeptide backbone conformations covering the internal dihedral degrees of freedom; moreover, the physical space of the pseudo-cyclic structure was also sampled in a complete revolution of the entire molecular fragment about the two fixed termini during the simulation. These characteristics suggest that mass-weighted MD can also be an extremely useful method for conformational analyses of constrained molecules and, in particular, for modeling loops on protein surfaces.     

1H NMR study on the conformation of bacitracin A in aqueous solution.

The conformation of bacitracin A, a widely used cyclic dodecapeptide antibiotic in aqueous solution, has been investigated using 500 MHz 1H NMR and molecular modeling. Findings revealed that a region (residues 1-6) is folded over the cyclic ring, resulting in metal coordination sites, a thiazoline ring, and Glu4 and His10 being proximate to each other.     

Circular-dichroic spectra of vasopressin analogues and their cyclic fragments.

The circular dichroic spectra of [Arg8]vasopressin, [Mpr1, Arg8]vasopressin, [Mpr1, D-Arg8]-vasopressin, pressinamide, deaminopressinamide, tocinamide, deaminotocinamide, [Leu4, D-Arg8]-vasotocin, [Mpr1, Leu4, D-Arg8]vasotocin and [Phe2, Lys8]vasopressin have been studied. All these substances showed a characteristic positive dichroic band at about 225 nm due to the presence of tyrosine in sequence position 2. The intensity of this band was affected by interactions between the tyrosine side-chain and other structural elements in the molecule, such as the Na-amino group, the side-chain of phenylalanine in position 3 and the linear C-terminal peptide. Analysis of the response of this band to structural modifications of the molecule and change in the solvent (particularly comparing neutral aqueous solutions with hexafluoroacetone solutions) allowed some conformational conclusions. The linear C-terminal tripeptide is probably situated over the cyclic portion of the molecule both in vasopressin and oxytocin substances. Its steric interaction with the tyrosine side-chain seems to be particularly efficient in molecules containing D-arginine in position 8. In the vasopressin series the stacking interaction of neighbouring aromatic amino acid residues furthermore limits the conformational freedom of the tyrosine side-chain and also probably distorts the dihedral angles of residues 1-3 in comparison with oxytocin. The interactions of phenylalanine and arginine with tyrosine relatively decrease the conformational effects of the primary amino group. Consequently the local conformation of vasopressin in the region of the tyrosine residue is more rigid and less sensitive to changes in medium than that of oxytocin. The circular dichroic spectra did not show any basic conformational differences in the backbone peptide chain of oxytocin and vasopressin substances. A weak negative disulphide band at about 290 nm could be observed in the spectra of both series of substances.     

Molecular dynamics study of disulfide bond influence on properties of an RGD peptide.

Three 1 ns length molecular dynamics simulations of an RGD peptide (Ac-Pen-Arg-Gly-Asp-Cys-NH2, with Pen denoting penicillamine) have been performed in aqueous solution, one for the disulfide bridged, and two for the unbridged form. The trajectories were analyzed to identify conformations explored by the two forms and to calculate several properties: NMR vicinal coupling constants, order parameters, dipole moments and diffusion coefficients, in an effort to describe the physical role of the disulfide bond. The cyclic peptide was able to explore several distinct backbone conformations centered around a turn-extended-turn structure. However, its flexibility was limited and it appeared to be 'locked in' into a a family of structures characterized by a high dipole moment and a well-defined conformation of the pharmacophore, which has been previously identified as biologically active. Excellent agreement between the simulated and observed NMR vicinal coupling constants indicates that realistic structures were sampled in the cyclic peptide simulation. The linear form of the peptide was much more flexible than the cyclic one. In the two independent 1 ns simulations of the linear form the explored conformations could be roughly grouped into two classes, of cyclic-like and extended type. Within each simulation the peptide switched between the two classes of structures several times. Exact matches between conformations in the two linear peptide simulations were not found; several conformational regions with backbone rms deviations below 1A were identified, suggesting that representative structures of the linear form have also been identified. In the linear peptide simulations the RGD pharmacophore is able to adopt a wide range of conformations, including the one preferred by the cyclic form. The lower biological activity of the linear peptide compared to the cyclic one may be correlated with the lower population of this structure in the absence of the disulfide bond.     

Bacitracin and gramicidin S as biospecific ligands for affinity chromatography of human thrombin

It was shown that the cyclic polypeptide antibiotic bacitracin is a competitive inhibitor of fibrinogen clotting by thrombin. Biospecific adsorbents for isolation of thrombin by gramicidin S and bacitracin attachment to silochrome S-80 modified by gamma-glycido-oxypropyl groups were synthesized. The thrombin yield at pH 7.2 and 8.0 was 76.5-96%, purification--6.2-11.6-fold, specific coagulating activity--940-1750 NIH u./mg protein. At pH 6.1 the enzyme does not practically bind to the adsorbents. In all probability, the differences in thrombin binding are due to conformational changes in the enzyme molecule, when pH changes from 6.1 to 7.2. Possible application of the synthesized adsorbents for obtaining laboratory and commercial preparations of thrombin and their perspective use for purification of other blood plasma serine proteinases possessing a narrow specificity are discussed.     

Cyclic enkephalin and dermorphin analogues containing a carbonyl bridge.

Four cyclic enkephalin analogues and four cyclic dermorphin analogues have been synthesized. Cyclization of linear peptides containing basic amino acid residues of various side chain length in position 2 and 5 (enkephalin analogues) or 2 and 4 (dermorphin analogues) was achieved by treatment with bis-(4-nitrophenyl) carbonate to form a urea unit. The peptides were tested in the guinea-pig ileum (GPI) and mouse vas deferens (MVD) assays. Diverse activity was observed, depending on the size of the ring and the location of the urea unit. The conformation of two dermorphin analogues has been studied: one of high activity (IC(50) = 4.15 nM in the GPI assay) and a second of low activity (IC(50) = 6700 nM in the GPI assay). The conformational space of these peptides was examined using the EDMC method. Using data from the NMR spectra, each peptide was described as an ensemble of conformers. Biological activity was discussed in light of the structural data.     

Synthesis and biological activity of cyclic and linear analogs of C-terminal fragments of neurotensin

Using solid-phase approach, new cyclic and linear analogues of C-terminal neurotensin (NT) fragments were synthesized and their vasodepressor and miotropic activities were assayed. The cyclic structures were fixed by a peptide bond linking the lysine epsilon-amino group with the C-terminal carboxyl. Cyclization was performed by using pentafluorophenyl esters or diphenylphosphorylazide. [Phe5]-cyclo(13----6 epsilon)NT-(5-13) was found to possess high depressor activity showing certain selectivity with respect to smooth vasal muscles. Circular dichroism spectra of aqueous solutions of linear and cyclic penta- and octapeptide analogues of neurotensin indicate that the linear pentapeptide in solution adopts a folded structure, while the neurotensin fragment NT-(6-13) has an unordered structure. Cyclization of the latter fragment leads to dramatic restriction of its conformational mobility resulting in a relatively rigid structure.     

Conformational modifications of cyclic hexapeptide somatostatin analogs

A model for the bioactive conformation of the highly active cyclic hexapeptide somatostatin analog cyclo-(Pro-Phe-D-Trp-Lys-Thr-Phe) has been proposed. As a test of this model, several compounds containing lactam and N-Me amino acid conformational modifications in the Thr-Phe-Pro-Phe beta turn were synthesized. The N-Me alanine and sarcosine substitutions for proline gave highly active analogs, while lactam dipeptides in place of Phe-Pro decreased potency. 1H n.m.r. and CD spectra of these analogs illustrate the conformational effects in solution of these modifications. The results provide additional support for the proposed conformational model.     

Native-like cyclic peptide models of a viral antigenic site: finding a balance between rigidity and flexibility

Antigenic site A of foot-and-mouth disease virus (serotype C) has been reproduced by means of cyclic versions of peptide A15, YTASARGDLAHLTTT, corresponding to residues 136-150 of envelope protein VP1. A structural basis for the design of the cyclic peptides is provided by crystallographic data from complexes between the Fab fragments of anti-site A monoclonal antibodies and A15, in which the bound peptide is folded into a quasi-cyclic pattern. Head-to-tail cyclizations of A15 do not provide peptides of superior antigenicity. Internal disulfide cyclization, however, leads to analogs which are recognized as one to two orders of magnitude better than linear A15 in both ELISA and biosensor experiments. CD and NMR studies show that the best antigen, CTASARGDLAHLTT-Ahx-C (disulfide), is very insensitive to environment-induced conformational change, suggesting that cyclization helps to stabilize a bioactive-like structure.     

Synthesis of [cyclo(Glu gamma-----epsilon Lys(Gly)]ACTH-(5-14) undecapeptide. Biological and physico-chemical properties of analogs of ACTH-(5-10)- and ACTH-(5-14)-peptides

Modified corticotropin fragment - [Lys11 (Gly)]ACTH-(5-14)- and its cyclic analogue - [cyclo (Glu gamma----epsilon Lys (Gly)] ACTH-(5-14)-undecapeptides have been synthesized by classical approach. The cyclic structure has been fixed by amide bond between gamma-COOH group of glutamic acid and alpha-NH2 group of glycine coupled to the epsilon-NH2 group of lysine. Fragment condensation has been achieved by azide or dicyclohexylcarbodiimide methods. Cyclization has been performed using diphenylphosphorylazide. The melanotropic activity of the cyclicanalogue on isolated frog skin exceeds by two orders of magnitude that of the linear undecapeptide, however the steroidogenic activity in isolated cells of rat adrenal cortex is diminished by an order of magnitude as compared with that of the linear precursor. A similarity of the CD spectra for the cyclic ACTH peptides and their linear counterparts in water and trifluoroethanol points to the similarity and relative rigidity of their structures.     

DNA protection by aminothiols: study of the cysteamine - DNA interaction by vibrational spectroscopy

Infrared linear dichroism measurements and Roman scattering spectra show that the cysteamine molecule binds strongly to the DNA stabilizing the double helix in a B geometry conformation. The B→A conformational transition is not observed for a cysteamine/DNA ratio of one cysteamine molecule per two phosphate sites. No evidence of interaction has been found between the radioprotector and the DNA bases. A model is proposed in which the cysteamine molecule is bound by its two ends through electrostatic interaction to two consecutive phosphate groups along the same DNA strand.     

Combined use of molecular dynamics simulations and NMR to explore peptide bond isomerization and multiple intramolecular hydrogen-bonding possibilities in a cyclic pentapeptide, cyclo(Gly-Pro-D-Phe-Gly-Val).

The conformational behavior of a model cyclic pentapeptide--cyclo(Gly-L-Pro-D-Phe-Gly-L-Val)--has been explored through the combined use of in vacuo molecular dynamics simulations and a range of nmr experiments (preceding paper). The molecular dynamics analysis suggests that, despite the conformational constraints imposed by formation of the pentapeptide cycle, this pentapeptide undergoes conformational transitions between various hydrogen-bonded conformations, characterized by low energy barriers. An inverse gamma turn with Pro in position i + 1 and a gamma turn with D-Phe in position i + 1 are two alternatives occurring frequently. Like other DLDDL cyclic pentapeptides, cyclo(Gly-Pro-D-Phe-Gly-Val) is also stabilized by an inverse gamma-turn structure with the beta-branched Val residue in position i + 1, and this hydrogen bond is retained in the different conformational families. The gamma-turn around D-Phe3 and the inverse gamma turn around Val5 are consistent with the nmr observations. 3JNH-CH alpha coupling constants of the all-trans forms were calculated from one of the molecular dynamics trajectories and are comparable to nmr experimental data, suggesting that the conformational states visited during the simulation are representative of the conformational distribution in solution. In addition to the equilibrium among various hydrogen-bonded all-trans conformers, the observation in nmr spectra of two sets of resonances for all peptide protons indicated a slow conformational interconversion of the Gly-Pro peptide bond between trans and cis isomers. The activation energy between these two conformers was determined experimentally by magnetization transfer and was calculated by high temperature constrained molecular dynamics simulation. Both methods yield a free energy of activation of ca. 20 kcal/mol. Furthermore, the free energy of activation is dependent on the direction of rotation of the Gly-Pro peptide bond.     

Two-dimensional proton NMR studies on poly(VPGVG) and its cyclic conformational correlate, cyclo(VPGVG)3

Two-dimensional nuclear Overhauser enhancement (2D NOESY) data are reported for the polypentapeptide of elastin, poly(VPGVG), and the cyclopentadecapeptide, cyclo(VPGVG)3. In both, the repeating type II Pro2-Gly3 beta-turn can be derived from the NOE data, providing confirmation of many previous studies. In addition, other through-space connectivities are detailed that also compare favorably with previously determined crystal and solution structures for cyclo(VPGVG)3. Also, near identical data for the cyclopentadecapeptide and the polypentapeptide demonstrate the cyclic conformation-linear (helical) conformational correlate relationship between the two molecules. The 2D NOESY experiment is seen to be an effective means of establishing the presence or absence of a conformational relationship between a cyclic repeating sequence and its higher molecular weight linear counterpart. This is an approach of substantial practical value when developing the conformation of sequential polypeptides and when attempting to identify the presence of the conformation of a repeating peptide sequence within a more complex primary structure. Having established the basic conformational relationship between a cyclic conformation and its linear helical counterpart, cross peaks present in the linear helical structure that are not present in the cyclic conformational correlate can provide information on the interactions between adjacent turns of the helix. In this connection, a Val gamma CH3 in equilibrium Pro beta CH2 interaction is reported that can be the basis for determining the number of pentamers per turn of helix once it is determined whether it is dominantly the Val1 or Val4 gamma CH3 that is interacting with the Pro2 beta CH2.     

Ion-binding and pharmacological properties of Tyr6 and Tyr9 antamanide analogs.

In order to investigate the antiproliferative properties of antamanide, we have synthesized and studied two antamanide analogs where the phenylalanine residue in positions 6 or 9 is substituted by tyrosine, their corresponding linear forms and the cyclic and linear des Phe5,Phe6-Tyr9-analogs. Antamanide and its biologically active synthetic analogs are able to form highly stable complexes with metal ions, particularly Na+, K+ and Ca2+. We studied the ion-binding properties of the Tyr-antamanide analogs by CD and Tb3+ -mediated fluorescence in acetonitrile. In this medium the far-and near-UV CD spectra of the neat Tyr6-antamanide analog are very similar to that of the parent cyclic decapeptide. Substantial differences occur on the contrary in the CD spectra of the neat Tyr9-antamanide, particularly in the regions at 220 nm and 270-290 nm. In acetonitrile, as already found for antamanide, the interaction with the above-mentioned metal ions always produces evident changes in the far- and near-UV CD spectra of both analogs. On the contrary, the CD spectra of the linear deca- and octa- and of the cyclic octa-analogs are affected by the presence of metal ions only in the near-UV region. In the same solvent the Tb3+ -mediated fluorescence spectra of all the synthetic peptides are remarkably affected by the addition of ions. On the basis of the spectral total changes, by using either or both the spectroscopic techniques, it has been possible to determine the ion binding constants for all the linear and cyclic Tyr-antamanide analogs and to compare them with that of the parent peptide. The antitoxic and antiproliferative activities of these antamanide analogs have been tentatively correlated to their ion-binding properties. A preliminary account of this work was given in (1).     

Biosynthesis of bacitracin on a protein thiotemplate.

The dodecapeptide bacitracin A is the major constitutent of a family of antibacterial peptides produced by Bacillus licheniformis. The non-ribosomal biosynthesis of bacitracin has been studied in cell-free extracts. Bacitracin synthetase has been fractionated on Sephadex G 200 column into two fractions; both fractions were required for bacitracin biosynthesis. On the other hand, on a Sepharose affinity chromatography column, using L-leucine as ligand, three fractions were obtained; all three were required for bacitracin biosynthesis. During bacitracin synthesis, the enzyme components contain a number of thioester bound peptides. The nature of the peptides suggested that the synthesis proceeds towards the C-terminal end of the molecule. It is assumed that by sequential addition of thioester-bound amino acids, bacitracin A could be synthesized on the surface of the enzyme containing phosphopantetheine.     

Conformational restrictions of biologically active peptides via amino acid side chain groups

Determining the relationships between conformation and biological activity in peptide hormones and neurotransmitters is an important goal of contemporary biology. A major difficulty in these studies is the conformational flexibility of most peptides and the high dependence of the conformations on environment. The question arises whether conformations determined in solution are relevant to those important to the peptide at the membrane receptor(s). One recent approach to overcome these difficulties has been the use of conformational constraints by covalent bonding of side chain groups of residues in the peptide. In this manner linear peptides are rendered cyclic, and cyclic peptides are further conformationally constrained either by ring contractions or by other conformational constraints. Biologically active peptides specifically designed by this approach have been found to possess several useful properties including: 1) greater conformational integrity; 2) increased agonist or antagonist potency; 3) prolonged biological activity; 4) increased enzymatic stability; and 5) increased specificity for a particular receptor. Careful applications of this approach have provided important new designs features for peptide structure-function studies, and new insights into peptide conformation-activity relationships for oxytocin, somatostatin, enkephalin, bradykinin, vasopressin, and other biologically active peptides.     

Melanin-concentrating hormone: a structural and conformational study based on synthesis, biological activity, high-field NMR, and molecular modeling techniques

A series of Melanin-concentrating hormone (MCH) fragments have been synthesized and their biological activities compared with the parent peptide. The substructural units, 5-14 linear and 5-14 cyclic, have been used as models for MCH-- H-Asp1-Thr-Met-Arg-Cys-Met-Val-Gly-Arg HO-Val17-Glu-Trp-Cys-Pro-Arg-Tyr-Val in 1H-nmr conformational studies. Conformational features predicted by molecular dynamics analyses find support in the nmr experiments.     

The effect of backbone cyclization on PK/PD properties of bioactive peptide-peptoid hybrids: The melanocortin agonist paradigm

A peptide–peptoid hybrid (peptomer) library was designed and synthesized, based on the sequence Phe-d-Phe-Arg-Trp-Gly. This sequence was previously found to specifically activate the melanocortin-4-receptor (MC4R) which participates in regulation of energy homeostasis and appetite. The library of peptomers included a peptoid bond in the Phe and/or d-Phe position and consisted of linear and backbone cyclic analogs, differed in their ring size. While the linear peptides rapidly degraded in serum and in brush border membrane vesicles (BBMV’s), the linear peptomers were more stable. Backbone cyclic peptomers were also stable under the same conditions. Backbone cyclization significantly increased the intestinal permeability of two peptomers compared to their linear counterparts, in the Caco-2 model. Pharmacological evaluation revealed that two linear and one backbone cyclic peptomer, were found active towards MC4R at the nanomolar range. Thus, the conformational constrains imposed by these local and global modifications affect both the pharmacokinetic and pharmacodynamic properties of the parent peptide. This study demonstrates the potential of imposing backbone cyclization on bioactive peptomers as a promising approach in developing an orally available peptidomimetic drug leads.