Structure-function organization of neurokinin A and neurokinin B molecules. I. Theoretical conformational analysis of neurokinin A

The spatial structure of the neurokinin A molecule was studied by the method of theoretical conformational analysis. On the basis of fragmental analysis, stable structures of the neurokinin A molecule under polar conditions were determined. The structures can be described by four families of low-energy conformations having a relatively labile tripeptide at the C-end and a conformationally rigid heptapeptide at the N-end. It was shown that two of these conformations are virtually isoenergetic structures. One of these is an alpha-helical structure and the other forms two beta-turns at the N-terminus, which change to the turn of the alpha-helix at the C-end.     

Structure-function organization of neurokinin A and neurokinin B molecules. III. A conformational study of glycine-monosubstituted analogues of neurokinins A and B

The conformational features of some glycine-monosubstituted analogues of neurokinins A and B were investigated by the method of theoretical conformational analysis. The calculated geometry and energy parameters permitted one to determine the structural role of each of these substituted amino acids in the mechanism of folding of the low-energy conformational states of neuropeptides. On the basis of the calculated data and the results of biological tests of these analogues, the structure-function relationships of neurokinins A and B were discussed.     

Structural organization of [met]enkephalin and endorphin molecules. II. Theoretical conformation analysis of alpha-, gamma- and delta-endorphins]

Conformational energy calculations were carried out for neuropeptides alpha-, gamma- and delta-endorphins, which are 1-16, 1-17 and 1-19 fragments respectively, of beta-endorphin. The proposed computational scheme yielded all possible low-energy conformational sets for these hormones. Specific features of spatial organization of each compound and similarities of their structures are discussed.     

Theoretical conformational analysis of oxytocin molecule.

The total semi-empirical conformational analysis of the oxytocin molecule has been carried out. It has been revealed the two main types of stable structures of cyclic moiety backbone and the great lability of the tail. The optimal spacing of cyclic moiety side chains has been found for every backbone structure. The calculation results are in good agreement with the data of physico-chemical investigations. Among the set of stable molecule structures reported in the present study are structures with beta-turn conformation of the cyclic moiety backbone and without closer spacing of the cyclic moiety and the tail, as well as structures with closely spaced N- and C-terminal parts which, however, lack beta-turn in the cyclic moiety.     

The neurokinin A receptor activates calcium and cAMP responses through distinct conformational states.

G protein-coupled receptors are thought to mediate agonist-evoked signal transduction by interconverting between discrete conformational states endowed with different pharmacological and functional properties. In order to address the question of multiple receptor states, we monitored rapid kinetics of fluorescent neurokinin A (NKA) binding to tachykinin NK2 receptors, in parallel with intracellular calcium, using rapid mixing equipment connected to real time fluorescence detection. Cyclic AMP accumulation responses were also monitored. The naturally truncated version of neurokinin A (NKA-(4-10)) binds to the receptor with a single rapid phase and evokes only calcium responses. In contrast, full-length NKA binding exhibits both a rapid phase that correlates with calcium responses and a slow phase that correlates with cAMP accumulation. Furthermore, activators (phorbol esters and forskolin) and inhibitors (Ro 31-8220 and H89) of protein kinase C or A, respectively, exhibit differential effects on NKA binding and associated responses; activated protein kinase C facilitates a switch between calcium and cAMP responses, whereas activation of protein kinase A diminishes cAMP responses. NK2 receptors thus adopt multiple activatable, active, and desensitized conformations with low, intermediate, or high affinities and with distinct signaling specificities.     

Structural organization of [met]enkephalin and endorphin molecules. III. Theoretical conformation analysis of beta-endorphin

Conformational energy calculations were carried out for beta-endorphin. Its spatial structure can be described by nine low-energy conformations. The calculations yielded the values of all dihedral angles of the backbone and side chains of these forms as well as intra- and inter-residue interaction energies.     

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.     

Theoretical conformational analysis of brain peptides. beta-Melanocyte-stimulating hormone

Using a semi-empirical method, an a priori conformational analysis of the octadecapeptide beta-melanocyte-stimulating hormone (beta-MSH) was carried out. The spatial structure of beta-MSH can be described by eight low-energy conformations, yielded by combinations of the most stable states of the respective free fragments. Calculations produced the values of all dihedral angles of the backbones and side chains of these forms as well as intra- and inter-residue interaction energies.     

Theoretical conformational analysis of tripeptides. N-acetyl-L-alanyl-L-alanyl-L-alanyl methylamide]

The minimization procedure has been used for calculation of the local minimum conformations of threepeptide--Ac-(L-Ala)3-NHMe without intramolecular H-bonds. The significant energy deviations from additivity found, arising with increase backbone length to three links, can be considered as the evidence for mutual dependence of conformational states of the neighbouring and terminal amino acid residues. It have been shown that stability of alpha-helix form for alanine threepeptide in contrary to corresponding dipeptide is noticeably higher due to stabilizing effect of dispersion interactions. The results of calculations are compared with the data on conformational distrubution of the threepeptide fragments in proteins with known three dimensional structure. The important role of the backbone interaction in protein chain have been marked.     

Deoxymyoglobin studied by the conformational normal mode analysis. II. The conformational change upon oxygenation

The conformational change taking place in myoglobin concomitantly with the observed geometrical change at the heme-His(F8) linkage upon oxygenation is studied by normal mode analysis, which is based on the quadratic approximation of the conformational energy function. The heme-globin interaction energy increases for this change by 8.114 kcal/mol when both the heme group and the globin molecule are held rigid. When they are permitted flexibility, the interaction energy relaxes by 7.038 kcal/mol, and the difference (1.076 kcal/mol) is distributed as strain energy within the molecule. This increase is the work necessary for the heme group to move against the force exerted by the globin. If the force is assumed to be invariable during this move, the work is small, 0.276 kcal/mol, meaning that the force is strongly variable. Furthermore, this means that the heme group is located near the equilibrium point of the potential energy of the heme-globin interaction. The change in the localized strain energy stored in the force field at the linkage between the heme and the imidazole of HisF8 is estimated to be of the same order of magnitude as the distributed energy. The largest atomic displacements are observed at the region from the F helix to the beginning of the G helix, and secondary large displacements occur at several regions, i.e, the A helix, from the C helix to the CD corner, the E helix, and the C-terminal side of the H helix. All of these regions have strong dynamic interactions with the heme group, either directly or indirectly. Their secondary structures show complex deformations. In other parts, relatively rigid segments undergo rotational and/or bending changes in a way consistent with the large changes described above and close atomic packing within the molecule. The calculated conformational change is decomposed to vibrational normal modes of deoxymyoglobin. The magnitude of the conformational change, measured by the mass-weighted mean-square atomic displacement, is accounted for up to 92.0% by the 151 normal modes with frequencies lower than 40 cm-1. In descending order of contribution, the first six modes, each of which has a frequency lower than 12 cm-1, account for up to 57.4%. This means that the functionally important conformational change can well be expressed in terms of a relatively small number of collective low frequency normal modes.     

Theoretical conformational analysis of phospholipids bilayers

We present a computational approach describing the conformation of lipid molecules (1-2-dipalmitoyl-sn-glycero-3 phosphocholine (DPPC)) organized in bilayers. The classical semi-empirical method used in peptide conformational analysis has been extended successfully to lipids. The excellent agreement between our theoretical predictions and recent experimental data on the molecular organization of lipid bilayers suggests that the method could be a valuable tool in the lipid conformational analysis but also in the prediction of orientation and mode of insertion of amphiphilic molecules into the lipid bilayer.     

Location of proline derivatives in conformational space. II. Theoretical optical activity

The coupling of theoretical optical calculations with experimental data provides a check of the validity of the theory or provides conformational information. The theory was validated by studies in which the approximate conformation was located independently. These studies have shown that a theory restricted to the two lowest energy transitions for each chromophore gives qualitative agreement with experiment. On the other hand, for some of the proline derivatives, the theoretical treatment allows detailed conformational assignments. Both successes and failures in correlating theory with experiment are discussed. The results presented provide a basis for assessing the prospects for relating protein and polypeptide optical activity to their conformations.     

Theoretical conformational analysis of a family of alpha-helical immunocytokines.

According to the results of the theoretical conformation analysis and available experimental data, the known immunocytokines can be divided into two groups: alpha-helical (IFNs-alpha, beta, gamma, omega; IL-2, 3, 4, 5, 6, 7; G-, M-, GM-CSFs; cMGF, PDGF) and beta-pleated proteins (ILs-1 alpha, beta; TNFS-alpha, beta). IFNs-alpha, beta, gamma, omega, IL-6, G-CSF, cMGF were shown to form a family of alpha-helical globular proteins characterized by a statistically significant homology in amino acid sequences and by common features of the secondary structure formation. Comparison of the sequences of 72 IFNs-alpha, beta, omega reveals three clusters of conservative amino acid positions. Their participation in the formation of active sites of IFN-alpha, beta, omega is supposed.     

Structural organization of [Met]enkephalin and endorphin molecules. I. Theoretical conformation analysis of [Met]enkephalin

Using a semi-empirical method, an a priori conformational analysis of the [Met]-enkephalin molecule was carried out. Calculations yielded the values of all dihedral angles of the backbone and side chains of the peptide's forms as well as intra- and inter-residue interaction energies.     

Optical rotatory properties of L-cystine conformational isomers. Theoretical analysis

The near ultraviolet chiroptical properties of L -cystine conformational isomers are examined on a static, “one-electron” model in which the disulfide moiety is the chromophoric group and the atoms of the L -alanyl fragments are treated as perturbers. The zeroth order chromophoric wave functions are calculated on a semiempirical molecular orbital model in which excited states are constructed in the virtual orbital-configuration interaction approximation. The perturbing environment is represented by point charges located at the atomic centers of the L -alanyl fragments. Chromophore–perturber interactions are expressed as charge–multipole moments with only the charge–dipole and charged–quadrupole terms being retained in the calculations. Vicinal contributions to the rotatory strengths of the five lowest energy disulfide transitions are computed for 30 conformational isomers of the L -cystine dizwitterion. The results provide support for the view that vicinal or peripheral effects can account entirely for the observed near ultraviolet (λ > 230 nm) chiroptical properties of L -cystine and its derivatives and that these properties are diagnostic of conformational features external to the disulfide moiety.