Spin-label ESR studies on the interaction of bovine spinal cord myelin basic protein with dimyristoylphosphatidylglycerol dispersions

Electron spin resonance (ESR) spectroscopy and chemical binding assays were used to study the interaction of bovine spinal cord myelin basic protein (MBP) with dimyristoylphosphatidylglycerol (DMPG) membranes. Increasing binding of MBP to DMPG bilayers resulted in an increasing motional restriction of PG spin-labeled at the C-5 atom position in the acyl chain, up to a maximum degree of association of 1 MBP molecule per 36 lipid molecules. ESR spectra of PG spin-labels labeled at other positions in the sn-2 chain showed a similar motional restriction, while still preserving the chain flexibility gradient characteristic of fluid lipid bilayers. In addition, labels at the C-12 and C-14 atom positions gave two-component spectra, suggesting a partial hydrophobic penetration of the MBP into the bilayer. Spectral subtractions were used to quantitate the membrane penetration in terms of the stoichiometry of the lipid-protein complexes. Approximately 50% of the spin-labeled lipid chains were directly affected at saturation protein binding. The salt and pH dependence of the ESR spectra and of the protein binding demonstrated that electrostatic interaction of the basic residues of the MBP with the PG headgroups is necessary for an effective association of the MBP with phospholipid bilayers. Binding of the protein, and concomitant perturbation of the lipid chain mobility, was reduced as the ionic strength increased, until at salt concentrations above 1 M NaCl the protein was no longer bound. The binding and ESR spectral perturbation also decreased as the protein charge was reduced by pH titration to above the pI of the protein at approximately pH 10.(ABSTRACT TRUNCATED AT 250 WORDS)     

Propterol: A 1,3-diarylpropan-2-ol from Pterocarpus marsupium

The structure of propterol, an extractive of the heartwood of Pterocarpus marsupium, has been established to be 1,3-bis (4-hydroxyphenyl)propan-2-ol, on the basis of its spectral data and Jones oxidation of its dimethyl ether to known 1,3-bis(4-methoxyphenyl)propan-2-one. Propterol appears to be among the simplest of highly reduced flavonoids encountered in nature.     

Conformational and ion-binding properties of cyclolinopeptide A isolated from linseed

The conformation of the cyclic nonaPePtide from linseed, cyclolinoPePtide A in methanol and in acetonitrile has been elucidated by one-and two-dimensional nuclear magnetic resonance. The molecule is folded in a β-turn conformation. CyclolinoPePtide A interacts and weakly comPlexes with Tb³⁺ (a Ca²⁺ mimic ion) with the metal ion Positioned Proximally to the Phe residue, but with no substantial structural alteration uPon metal binding. CyclolinoPePtide A is also seen to aid the translocation of Pr³⁺ (another Ca²⁺ mimic) across unilamellar liPosomes. However, cyclolinoPePtide A does not Phase transfer or act as an ionoPhore of calcium ion myself. ExPeriments using lanthanide ions thus do not necessarily indicate any ionoPhoretic ability of the comPlexone towards calcium ions.     

Crystal structures of MAP kinase p38 complexed to the docking sites on its nuclear substrate MEF2A and activator MKK3b

The structures of the MAP kinase p38 in complex with docking site peptides containing a phi(A)-X-phi(B) motif, derived from substrate MEF2A and activating enzyme MKK3b, have been solved. The peptides bind to the same site in the C-terminal domain of the kinase, which is both outside the active site and distinct from the "CD" domain previously implicated in docking site interactions. Mutational analysis on the interaction of p38 with the docking sites supports the crystallographic models and has uncovered two novel residues on the docking groove that are critical for binding. The two peptides induce similar large conformational changes local to the peptide binding groove. The peptides also induce unexpected and different conformational changes in the active site, as well as structural disorder in the phosphorylation lip.     

Mechanisms of transmembrane cation transport studied by nuclear magnetic resonance spectroscopy

Several molecules like ionophores, vitamins, ion-binding cyclic peptides, acidic phospholipids, surfactants are known to expose the inner side of vesicles, to the externally added cations. Whereas ionophores and certain other systems bring about these changes by a selective transport (influx) of the cation by specialized mechanisms known as the carrier and channel mechanism, other systems cause lysis and vesicle fusion. These systems have been successfully studied using¹H,³¹ P and¹³C nuclear magnetic resonance spectroscopy after the demonstration, fifteen years ago, of the ability of paramagnetic lanthanide ions to distinguish the inside of the vesicle from the outside. The results of these ’nuclear magnetic resonance kinetics’ experiments are reviewed.     

Interaction of two complementary fragments of the bovine spinal cord myelin basic protein with phospholipid bilayers. An ESR spin-label study

The myelin basic protein (MBP) from bovine spinal cord was cleaved at the single tryptophan residue to produce an N-terminal fragment (F1) of molecular weight 12.6K and a C-terminal fragment (F2) of molecular weight 5.8K. The interactions of the two fragments with bilayers of the acidic lipid dimyristoylphosphatidylglycerol (DMPG) were compared with those of the intact protein, by using both chemical binding assays and spin-label electron spin resonance spectroscopy. The saturation binding stoichiometries of the two fragments were found to sum to that of the MBP, having values of 11, 24, and 36 mol of DMPG/mol of protein for F2, F1, and the MBP, respectively. The strength of binding was found to increase in the order F2 less than F1 less than MBP, which follows that of the net charges on the different fragments. The ionic strength dependence of the protein binding indicated that the interaction is primarily of electrostatic origin. The efficiency of displacement of the proteins by salt was in the order F2 greater than F1 greater than MBP, which correlates with both the strength of binding and the net charge on the different protein fragments. Nitroxide derivatives of phosphatidylglycerol (PG) labeled on the sn-2 chain were used to probe the protein-induced changes in the acyl chain dynamics. Both the fragments and the MBP decreased the lipid chain mobility as recorded by the C-5 atom and C-12 atom position nitroxide-PG spin-labels, in a manner which followed the protein binding curves.(ABSTRACT TRUNCATED AT 250 WORDS)     

CD and nmr studies on the interaction of lithium ion with valinomycin and gramicidin-S

The conformation of the valinomycin–lithium complex has been studied using CD and nmr techniques. The lithium ion induced significant changes in the chemical shifts of the NH and C^αH protons, as well as in the CD spectra of valinomycin. From the analysis of the lithium ion titration data, it is concluded that valinomycin forms a 1:1 type weak complex with lithium, having a stability constant of 48 L mol^?1 at 25°C. This conformation is different from the familiar valinomycin–potassium complex. The nature of the interaction at low and high concentrations of lithium ions with valinomycin (ionophore) and gramicidin-S (nonionophore) has been compared. At high salt concentrations, there was a further change in the CD and nmr spectra of valinomycin, giving a second plateau region at > 3M of the salt. In the case of gramicidin-S, no significant changes in the nmr or CD spectra were observed in the lower concentration range corresponding to where changes were observed in the case of valinomycin. However, the addition of lithium salt at concentrations greater than 3M induced changes in both the CD and nmr spectra of gramicidin-S, and the titration graph of molar ellipticity versus concentration of lithium perchlorate gave a plateau region at concentrations greater than this. These results indicate that the effects of lithium at low and high concentrations are independent of each other. The conformational transitions at very high salt concentrations (denaturation) are more likely due to solvent structural perturbations rather than to the consequences of ion binding.