Conformational features of bradykinin. A circular dichroism study of the aromatic side-chains

The circular dichroism (CD) of the peptide hormone bradykinin and its analogues, [Phe(H4)5]-bradykinin, [Phe(H4)8]bradykinin, [Phe(H4)5,8]bradykinin, [TyrOMe5]bradykinin, [TyrOMe8]bradykinin and [TyrOMe5.8]bradykinin, is described. The comparison of the CD spectra of these analogues with each other, recorded under a variety of conditions (pH, solvent, temperature), allows the monitoring of the behaviour of the aromatic side-chains (phenylalanine, tyrosine) and an estimation of their respective spectral contributions in both spectral regions (320-250 nm, 250-190 nm) with good precision. Conformational non-equivalence of the residues Phe-5 and Phe-8 together with some overall conformational features of bradykinin are thus established.     

Theoretical conformational analysis of Asn1, Val5 angiotensin II

A theoretical analysis of the conformation of the octapeptide hormone Asn¹, Val⁵ angiotensin II has been carried out by semiempirical potential energy calculations. A preliminary study of the Ala₆-Pro-Ala molecule, which mimics the angiotensin backbone, provided us with likely backbone structures on which the effect of the full side chains of the hormone could be assessed. For angiotensin II, the calculations show that only a small number of folded, compact conformations have a high probability of existence. This is the consequence of favorable packing and of the presence of proline in position 7. These results are consistent with various experimental data, both structural and biological. This method is readily applicable to the study of analogs of the hormone or to other peptides of comparable size.     

Circular dichroism studies of some arginine-vasopressin analogues

CD spectra of arginine-vasopressin (AVP) and of its analogues substituted in position 1 and/or 7 were measured in aqueous solution at different pH values. The shapes of the CD spectra of AVP analogues substituted in position 1 are strongly influenced by the type of group attached to the beta-carbon of residue 1. The substitution of the proline residues in position 7 by N-methylalanine also leads to a change in conformation of the peptide. The differences in the CD spectra are interpreted in terms of conformational changes, which are due to the interaction of the tyrosine side chain with neighbouring residues (for 1-substituted analogues of AVP), or to that between the hexapeptide ring and acyclic tripeptide chain (for 7-substituted analogues).     

Enkephalin analogues containing beta-naphthylalanine at the fourth position

To examine the importance of the aromatic side chains of enkephalin on opiate activity, we report the synthesis and conformational analysis of a series of analogues related to enkephalin with beta-naphthylalanine in place of phenylalanine at the fourth position. Three linear analogues (Tyr-D-Ala-Gly-(L and D)-beta Nal(1)-Leu-NH2 and Tyr-D-Ala-Gly-beta Nal(2)-Leu-NH2) were initially synthesized to examine the effect of the substitution on biological activity. The increased activity of these peptides at the mu-opiate receptor, compared to native Leu-enkephalin, prompted us to examine the more conformational constrained analogues, Tyr-c[D-A2bu-Gly-(L and D)-beta Nal(1)-Leu], incorporating a alpha, gamma-diaminobutyric acid at the second position and cyclization to the carboxylic end of the leucine. These two cyclic analogues provide insight into the necessity for the L chirality of the aromatic residue at position 4. The Tyr-c[D-A2bu-Gly-L-beta Nal(1)-Leu] analogue is highly potent and displays a slight preference for the mu receptor. The conformational analysis indicates that despite the high flexibility of the tyrosine side chain, the aromatic rings of the tyrosine and naphthylalanine are relatively distant from each other. The presence of two intramolecular hydrogen bonds help maintain the conformation of the 14-membered backbone ring that keeps the side chains directed away from each other. These findings are in agreement with our model of an extended structure required for mu selectivity and a folded form with close aromatic ring placement for delta selectivity.     

Conformation of the central sequence of angiotensin II and analogs

We describe the synthesis and the conformational analysis by ir, CD, and proton-nmr spectroscopy of four model peptides of the type N-Ac-Tyr-X-His-NH₂ with X = Val, Leu, Ala, Gly. These peptides represent the central sequence of the hormone angiotensin II and its position-5 analogs. We studied their conformational behavior in aqueous solution during pH titration and in organic solvents. For specific purposes of spectral analysis (ir band assignment, proton-nmr signal assignment, heteronuclear vicinal coupling constants), we synthesized three isotopically enriched homologs of the mother sequence, i.e., N-Ac-(¹⁵N-Tyr)-Val-His-NH₂, N-Ac-(¹³C, ²H, Tyr)-Val-His-NH₂, and N-Ac-Tyr-(¹³C, ²H, Val)-His-NH₂. Results are summarized as follows: the tyrosine and the histidine side chains influence each other through space; this mutual influence is modulated by the nature of the side chain in position X and decreases in going from X?Val to X?Gly as a consequence of two simultaneous events, changes in the side-chain rotamer distribution and changes in the φ and ψ angles of residue X. The decrease in the bulkiness of the side-chain X (Val → Gly) leads to increased flexibility of the peptide backbone at this site, which is also reflected in the apparent ratio of C₅, C₇, and intermediate conformations present in equilibrium. The three spectroscopic techniques, in addition to the results of chymotryptic degradation experiments, show a high level of agreement, and all reflect the dynamic conformation of these peptides in a different manner.     

Circular-dichroism spectra of truncated and other analogs of angiotensin II.

Circular dichroism spectra on angiotensin II and analogs, and its truncated N-terminal and C-terminal peptides were determined in fluroinated alcohols under several conditions in the peptide or aromatic spectral regions. The following conclusions were suggested: (a) evidence for a beta structure for angiotensin II; (b) evidence for a folding at the N-terminal and C-terminal part of the molecule; (c) an interaction involving the C-terminal residue which decreases progressively when phenylalanine is replaced by isoleucine and then by alanine; (d) the N-terminal amino acid seems to play an important role in the overall conformation of the molecule possibly by interacting with the C-terminus, its absence in the 2 -- 8 heptapeptide giving rise to a more pronounced signal than angiotensin II; (e) in trifluoroethanol the conformation of these peptides is well defined and fits well with observed structure-activity relationships and observed binding data. There is a loss of this relationship when these solvents are diluted with water.     

Peptide conformations--49(1): synthesis and structure-activity relationships of side chain modified peptides of cyclo(-D-Pro-Phe-Thr-Lys-Trp-Phe.)

Cyclic hexapeptide analogues representing the modified retro sequence of the amino acid residues 7-11 of natural somatostatin are known to protect liver cells from phalloidin poisoning. To determine the influence of steric, lipophilic, and charge effects on (a) the conformation of the backbone and the aromatic side chains and (b) the biological response, the side chains of Phe2, Lys4, and Phe6 of cyclo(-D-Pro1-Phe2-Thr3-Lys(Z)4-Trp5-Phe6-), 1a, one of the most active peptides found so far, were modified by various residues. The discussion of conformationally relevant parameters proves that neither backbone conformations nor populations of aromatic side chain rotamers were altered by these substitutions. The potency of these derivatives in a cytoprotection assay varies by at most one order of magnitude (more or less active than the parent peptide 1a). A qualitative evaluation of lipophilic, steric, and charge effects reveals the dominance of lipophilic effects of aromatic residues; the most potent compounds contain aromatic substructures in the side chain of Lys4.     

Aromatic side-chain contributions to the far ultraviolet circular dichroism of peptides and proteins

The rotational strength of the L_a transition in phenylalanine and tyrosine side chains has been calculated for dipeptides with various backbone and side-chain conformations. Similar calculations have also been performed for tripeptides in the β-turn conformation with aromatic residues at the corners of the turn. The interaction of the aromatic ring with neighboring peptides generates rotational strengths in the L_a transition of the order of 0.1 Debye-Bohr magneton. When the preferred backbone and side-chain conformations are considered, it is found that the most probable conformations have positive L_a bonds. This result accounts for the observation that the N-acyl amino acid amides of L -Tyr and L Phe have positive L_a bands. It also suggests that, although other interactions may affect the numerical value and even the sign, there will be a significant positive contribution to the rotational strength of aromatic residues in globular proteins from nearest-neighbor interactions. Calculations on proteins of known conformation at the nearest-neighbor level confirm the tendency toward positive L_a contributions for Phe and Tyr residues. This contribution can be of the order of 10% of the observed CD even in proteins with rather strong amide contributions. In some proteins, such as the gene 5 protein from bacteriophage fd and many snake-venom toxins, side-chain contributions from Tyr and Trp residues manifest themselves as positive CD bands in the 225–250-nm region. The magnitude of the nearest-neighbor contributions and the trend toward positive contributions are consistent with the observation of such CD bands in globular proteins. No special stacking interaction among aromatic side chains needs to be invoked.     

Conformational studies of corticotropin1-32 and constitutive peptides by circular dichroism.

Circular dichroism spectra on corticotropin1-32 and its constitutive N-, and C-terminal peptides are determined in water and trifluoroethanol under several conditions in the aromatic and peptide spectral regions. Furthermore, the effects of pH and varied mixtures of water-trifluoroethanol are examined on the corticotropin1-32 molecule. The results show that the N- and C-terminal series have a different behaviour in both aqueous and organic media. Corticotropin and the former peptides display "random" spectra in water, and alpha-helix type spectra in trifluoroethanol, while the latter have "random" spectra in both solvents. In the holopeptide corticotropin, the side chain-side chain effects, as reflected by the titration curves obtained from variations in the aromatic region, support the idea of an helical organization of part of the backbone even in aqueous solution. When going from water to trifluoroethanol corticotropin1-32 undergoes a conformational change which leads to an alpha-helix, following a linear pathway. These results, together with other observations, indicate the possible role of the conformation of corticotropin molecules in their biological life.     

Conformational preferences of Leu-enkephalin in reverse micelles as membrane-mimicking environment

Enkephalin represents one of the bioactive peptide molecules most extensively investigated both in solution and in the crystal state. Depending upon the environment chosen for such studies, three main conformational states were identified for this flexible, linear pentapeptide—i.e., an extended conformation, a single-bend, and a double-bend structure. Since CD and Fourier transform ir (FTIR) spectra of Leu-enkephalin solubilized in negatively charged reverse micelles of bis (2-ethylhexyl)sulfosuccinate sodium salt/isooctane/water were supportive of a restricted conformational space of the aromatic side chains and of a bended type fold, we have analyzed by nmr the conformational preferences of Leu-enkephalin in reverse micelles using a synthetic [¹³C, ¹⁵N]-backbone-labeled sample. The overall conformation derived from nuclear Overhauser effect spectroscopy (NOESY) and ¹⁵N-filtered rotating frame NOESY (ROESY) spectra and by distance geometry calculations is a double-bend fold of the backbone that is comparable to one of the known x-ray structures. Thereby the tyrosine side chain is inserted into the hydrophobic core of the reverse micelles in a restrained conformational space as well evidenced by NOEs between the aromatic ring protons and the surfactant. The proximity of the aromatic rings of tyrosine and phenylalanine indicate a preferred structure consistent with the postulated conformation of the opioid peptide in the δ-receptor-bound state. These results confirm the interesting and promising properties of reverse micelles as membrane mimetica. © 1997 John Wiley & Sons, Inc. Biopoly 41: 591–606, 1997     

Mechanisms and sites of action of newer angiotensin agonists and antagonists in terms of activity and receptor.

From the myotropic and vasopressor activities of the numerous analogs of angiotensin II, it has been determined that the phenyl group of position 8 possesses the information for biologic response while the aromatic side groups in positions 4 and 6, the guanido group in position 2 and the C-terminal carboxyl are involved in binding to the receptor site. Removal of a side group of the C-terminal phenyalanine yields peptides that bind to the receptor. While many of these have low agonist properties, all have antagonist properties. Modifications in the aromatic side groups affect conformation of the octapeptide. This change may relate to receptor binding but sufficient data are not yet available to determine a correlation pattern. A proposed conformation for angiotensin is given as well as an artist's concept of angiotensin II binding to its membrane receptor utilizing the groups known to be involved in binding. Both angiotensin II and III [des-Asp] angiotensin II stimulate the biosynthesis and release of aldosterone from adrenal glomerulosa cells. Sufficient data are not yet available to determine whether the conversion of angiotensin II to angiotensin III is neccessary for the steroidogenesis activity.     

Conformational features of bradykinin. A circular dichroism study of some peptide fragments and structural analogues of bradykinin.

The vasoactive hormone bradykinin, its N-and C-terminal fragments and some structural analogues were studied by Circular Dichroism. Conformational features of the peptide can be detected by comparative analysis of the various CD spectra recorded as a function of aqueous pH, solvent and temperature. It is shown that the two biologically essential arginine residues (Arg1 and Arg9) are important for the specific folded bradykinin conformation. Differences between bradykinin, its fragments and analogues become clearly established in conformational terms, and are discussed in relation to the biological activity of these peptides.     

The effect of conformation on the CD of interacting helices: a theoretical study of tropomyosin

A recent report [M. E. Holtzer, et al. (1988) Biophysics Journal, 53, 96a] of the anomalous CD spectrum of the tropomyosin (TM) fragment 11TM127 motivated us to model the system as two 21-residue alpha-helices distorted to a coiled-coil conformation. We used strong-coupling exciton theory to model the optical properties of the system. Two backbone amide excited states (n pi* and pi pi*) were considered, as well as four excited states (Lb, La, Bb, Ba) for the phenolic side chain. We calculated the effect of superhelix formation on the backbone CD spectrum. The decrease in molar ellipticity of the alpha-helix parallel-polarized transition at 208 nm was found to be a simple function of superhelix tilt angle. We then modeled a coiled coil (radius = 5.5 A, pitch = -140 A) with one aromatic ring per superhelix. Steric interactions between aromatic side chains in a coiled coil were calculated as a function of side-chain conformation and heptet position. Steric interactions between phenolic rings will be significant for heptet positions a and d, but not for positions b, c, e, f, or g. We calculated the phenolic Lb transition rotational strength as a function of position within the heptet repeats, and of all possible side-chain dihedral angles, chi 1 and chi 2. When tyrosines were placed at heptet positions b, c, e, f, or g, the rotational-strength surface was nearly identical to that of a single tyrosine in an undistorted helix. In contrast, the rotational-strength surface for tyrosines in heptet positions a or d showed substantial intertyrosine coupling components. The rotational-strength surfaces for the three types of heptet positions (position a, position d, and the others) allowed an interpretation of the aromatic CD spectra of TM and its fragments. It was predicted that the three types of heptet positions will be spectroscopically distinguishable.     

Synthesis and characterization of six sequential polypeptides containing tyrosine, glutamic acid, alanine, and glycine by circular dichroism and difference spectroscopy

Six sequential polytetrapeptides containing equimolar amounts of tyrosine, glutamic acid, alanine, and glycine were characterized by CD and difference spectroscopy over a wide range of pH. As the pH was lowered from physiological values, each of the polymers underwent pH-sensitive transitions. The CD spectra indicated that two polymers, poly(Tyr-Glu-Ala-Gly) and poly(Tyr-Ala-Glu-Gly), had some α-helical conformation at pH 7.0 and approached maximum helicity around pH 6.0; two others, poly(Ala-Tyr-Glu-Gly) and poly(Glu-Ala-Tyr-Gly), had no α-helical conformation at pH 7.0 and about one-third of the ellipticities of the above two polymers at pH 5.5; and the remaining two, poly(Ala-Glu-Tyr-Gly) and poly(Glu-Tyr-Ala-Gly) had little or no α-helix, even at pH 5.5. Difference spectroscopy at 286 nm yielded results quite different. The molar extinction coefficients for poly(Tyr-Glu-Ala-Gly) and poly(Tyr-Ala-Glu-Gly) continued to change, even below pH 5.5, and the total changes in absorbance between pH 8.0 and 4.5 were of intermediate magnitudes among the six polymers. Poly(Ala-Tyr-Glu-Gly) and poly(Glu-Ala-Tyr-Gly), which had similar CD spectra, had the lowest and highest pH-related changes in the molar extinction coefficients. It thus appears that amino acid composition alone cannot account for the apparent differences in conformation among the polytetrapeptides. Other factors, such as amno acid sequence, must play a major role in the determination of conformation. The intrinsic viscosity of poly(Tyr-Glu-Ala-Gly) increased markedly between pH 6.0 and 5.5, which was below the pH of the CD transition but above the pH at which the largest absorption perturbation change, at 286 nm, took place. The model that can best account for the relatively low pH at which the absorption transition of tyrosine occurred is a progressive immobilization of side chains in the α-helix as the pH decreases.     

Circular dichroism of bradykinin and related peptides

1. The circular dichroism of bradykinin and a number of its analogues and homologues was measured over the spectral range 200-300nm. All of the biologically active peptides showed maxima at 220nm and minima at 235nm. The spectra were independent of solvent and temperature. The vibronic transitions of phenylalanyl residues in the 250-280nm range showed no evidence of intra- or inter-molecular interactions. We take this as evidence that bradykinin and its biologically active analogues and homologues exist in solution as disordered chains. 2. None of the analogues with spectra unlike bradykinin possessed biological activity. However, peptides such as retro-bradykinin, des-6-serine-bradykinin, des-1-arginine-bradykinin and des-9-arginine-bradykinin produced spectra like that of bradykinin but were devoid of biological activity. Although we could not identify spectral features that were clearly correlated with biological activity, it appears unlikely that highly ordered peptides of the same amino acid composition as bradykinin would possess bradykinin-like effects.     

Macromolecularization of a tripeptide analogue of the Cu(II) binding site of human serum albumin: 2. Conformational and binding properties towards Cu(II) and Ni(II)ions of Gly-Gly-His derivatives of poly(l-lysine)

The conformational and binding properties towards Cu(II) and Ni(II) ions of Gly-Gly-His derivatives of poly(l-lysine) have been investigated mainly using circular dichroism (c.d.) spectroscopy. These derivatized polymers can be considered macromolecular analogues of the Cu(II) and Ni(II) binding site of human serum albumin. It has been shown that modification up to 53% of the ε-amino groups of lysine side chains by covalent binding of the tripeptide unit Gly-Gly-His does not induce appreciable alteration of the α-helix forming tendency of the polylysine backbone. The derivatized polymers exhibit strong affinity towards Cu(II) and Ni(II) ions. At neutral pH, complexes are formed in which each tripeptide chelating unit is linked to one metal ion. The spectral characteristics in the visible absorption region are consistent with a square planar geometry of the complexes, with deprotonated peptide groups and one imidazole nitrogen in the coordination sphere of the ion. C.d. measurements in the far u.v. indicate that complex formation in the side chains causes an increase of ordered structure of the peptide backbone at neutral pH. This fact is interpreted in terms of a reduced electrostatic repulsion among side chains due to charge neutralization in the tripeptide units linked to metal ions.     

Structural basis for the activity of pp60(c-src) protein tyrosine kinase inhibitors

Conformational searches on three closely related pp60(c-src) protein tyrosine kinase inhibitors of varying potencies were performed to determine a structural basis for their activity. The first was a linear peptide (PDNEYAFFQf), the second its 10-membered cyclic analogue, and the third a cyclic analogue with a para carboxyphenylalanine in place of one the F residues. A common backbone conformation with an antiparallel beta-sheet-like geometry capped by similar beta-turns was found for all three peptides, which may be a binding conformation and gives a candidate pharmacophore for further testing. The interaction between some polar side chains and between some of the aromatic rings may be important for maintaining the correct conformation. The differences in potencies of these inhibitors may be attributed to certain thermodynamic and chemical reasons.     

pH dependence of the circular dichroic bands of phenylmethanesulfonyl-mesentericopeptidase.

The effect of pH on the circular dichroism spectra of phenylmethanesulfonyl-mesentericopeptidase (peptidyl peptide hydrolase, EC 3.4.21) was studied. The ellipticity of the bands below 250 nm, which reflects the backbone conformation of the protein molecule, remains almost unchanged in the pH range 6.2--10.4. However, below pH 6.2 and above pH 10.4 a conformational transition occurs. The pH-dependent changes above 250 nm were also studied. The titration of the CD band at 296 nm reflects the ionization of the "exposed" tyrosines, which phenolic groups are fully accessible to the solvent. An apparent pK of 9.9 is calculated from the titration curve. It is concluded that ionization of the tyrosyl residues with normal pK's is complete before conformational changes in the protein molecule occur.     

Probing the effect of side chains on the conformation and stability of helical peptides via isotope-edited infrared spectroscopy

The mechanism of helix stabilization or destabilization by different amino acids has been the subject of several experimental and theoretical studies; these studies suggest that large or bulky side chains may modulate helix stability by altering the hydration of the helix backbone. In this paper, we report a spectroscopic study to determine the effect of alanine to leucine substitutions on the conformation and solvation of specific segments of a model helical peptide. A 25-residue, alanine-rich, helical peptide [Ac-(AAAAK)(4)-AAAAY-NH(2) (AKA)] and its two leucine variants [Ac-LLLLK-(AAAAK)(3)-AAAAY-NH(2) (LKA) and Ac-(AAAAK)(4)-LLLLY-NH(2) (AKL)] were characterized by infrared (IR) and electronic circular dichroism (ECD) spectroscopies. Introduction of (13)C isotopes into specific, consecutive, backbone carbonyls for certain blocks of each of the peptides mentioned above allows the IR spectra to be interpreted in terms of the conformation and solvation of specific residues within the helix. These isotope-edited IR spectra of the leucine peptides do not show evidence of a decrease in the degree of backbone solvation compared to the alanines, but suggest that the peptide may adopt a distorted conformation to accommodate the larger leucine side chains at the N-terminus. These experiments demonstrate the power of isotope-edited IR in dissecting subtle changes in helix conformation at the residue level.