The crystal structure of oxylipin-conjugated barley LTP1 highlights the unique plasticity of the hydrophobic cavity of these plant lipid-binding proteins.

The barley lipid transfer protein (LTP1) adducted by an alpha-ketol, (9-hydroxy-10-oxo-12(Z)-octadecenoic acid) exhibits an unexpected high lipid transfer activity. The crystal structure of this oxylipin-adducted LTP1, (LTP1b) was determined at 1.8A resolution. The covalently bound oxylipin was partly exposed at the surface of the protein and partly buried within the hydrophobic cavity. The structure of the oxylipidated LTP1 emphasizes the unique plasticity of the hydrophobic cavity of these plant lipid-binding proteins when compared to the other members of the family. The plasticity of the hydrophobic cavity and increase of its surface hydrophobicity induced by the oxylipin account for the improvement of the lipid transfer activity of LTP1b. These observations open new perspectives to explore the different biological functions of LTPs, including their allergenic properties.

Solution conformation of an RNA--DNA hybrid duplex containing a pyrimidine RNA strand and a purine DNA strand.

RNA--DNA hybrid duplexes are involved in transcription, replication and reverse transcription of nucleic acids. Information on such duplexes may shed some light on the mechanism of these processes. For this purpose, the influence of base composition on the structure of a polypyrimidine--polypurine RNA--DNA duplex r(cucuccuucucuu). d(GAGAGGAAGAGAA) has been studied using 1H, 31P and 13C NMR experiments, molecular modeling (JUMNA program) and NOE back-calculation methods. The resulting structure of the 13-mer hybrid duplex shows that the RNA strand is in the expected A-type conformation while the DNA strand is in a very flexible conformation. In the DNA strand, the desoxyribose sugars retain the C2'-endo B-type conformation. The duplex helical parameters (such as inclination, twist and displacement of the bases) are close to the A-type conformation. No bending was observed for the global axis curvature. The major groove width is close to the B-form value and the minor groove width is intermediate between standard values for A and B-forms. These results are in favour of the independence of minor groove size (where RNase H interacts) and the base composition of the hybrid duplexes.

Magnetic resonance spectroscopy of cellular lipid extracts from sensitive, resistant and reverting K562 cells and flow cytometry for investigating the P-glycoprotein function in resistance reversion.

The proton NMR spectra of K562 cells contain resonances of lipids. When these cells acquire multidrug resistance phenotype, the NMR lipid signals are modified and partially recovered when the resistance is reversed. The goals of the present study are to elucidate the mechanism of the resistance phenotype reversion and to investigate the possible origin of lipid signals detected in whole cells with proton NMR spectroscopy. Therefore, the K562 drug-sensitive cell line, its adriamycin resistant counterpart and two reverting derivates, obtained by verapamil treatment and long term culture in drug-free medium, were used in this study. The P-glycoprotein (P-gp) pump function was measured by flow cytometry and lipids were extracted to be analysed by proton and phosphorus spectroscopy. The phenotype reversion is due to the decrease of the P-gp function and an increased entrance of anthracycline drug when compared with the resistant cells. The spectra obtained on extracts showed no modification of the fatty acid composition and of the ratio of total cholesterol to fatty acid content. A different phospholipid composition in sensitive and resistant cells was found, but the reversion of resistance did not produce a recovery of these lipids. Thus, the lipid NMR spectra of extracts could not explain the spectral modifications observed on whole cells, in relation to acquiring and reverting drug resistance. These results are in favour of a different lipid organization or of localization within the cell.

Current Awareness.

In order to keep subscribers up-to-date with the latest developments in their field, John Wiley & Sons are providing a current awareness service in each issue of the journal. The bibliography contains newly published material in the field of NMR in biomedicine. Each bibliography is divided into 9 sections: 1 Books, Reviews ' Symposia; 2 General; 3 Technology; 4 Brain and Nerves; 5 Neuropathology; 6 Cancer; 7 Cardiac, Vascular and Respiratory Systems; 8 Liver, Kidney and Other Organs; 9 Muscle and Orthopaedic. Within each section, articles are listed in alphabetical order with respect to author. If, in the preceding period, no publications are located relevant to any one of these headings, that section will be omitted.

Magnetic resonance spectroscopy and fluorescence microscopy to investigate mobile lipids in sensitive, resistant and reverting K562 cells and their membranes.

The erythroleukaemic K562 cell line and its adriamycin resistant counterpart were used to study resistance, its reversion and their consequences on the levels and localisation of lipids detected in proton nuclear magnetic resonance (NMR) spectra. On whole cells, the mobile lipids giving rise to a NMR signal were significantly decreased in the resistant cells when compared to the sensitive ones; these lipids recovered partially in the reverting cells. According to the spinlattice relaxation times (T1), the lipids detected appeared to be in a similar environment in sensitive and reverting cells. In membrane-enriched fractions, mobile lipid levels were not significantly different in the sensitive and reverting cell lines but decreased in resistant ones. Moreover, lipid droplets stained with a fluorescent Nile red lipophilic probe showed the presence of highly fluorescent particles in the samples in which NMR detected high levels of mobile lipids. These results suggest the participation of cytosolic lipid droplets in NMR signals in drug sensitive and reverting cells and open the question of the relative roles of these droplets and of the membrane lipids in the lipid metabolic pathways associated with drug resistance in cancer cells.

Predictive study by molecular modeling to promote specific probes of glutamate receptors, using methylated cyclic glutamic acid derivatives (trans- and cis-ACPD). Comparison with specific agonists.

Two classes of glutamate receptors (metabotropic and ionotropic) and their subclasses (groups I-III and N-methyl-D-aspartic acid (NMDA), kainic acid (KA)), respectively, are characterized by the binding of a L-glutamate moiety in a specific conformation. The conformations may be grouped by the two backbone torsion angles, chi1 [alpha-CO2-C(2)-C(3)-C4)] and chi2 [+NC(2)-C(3)-C(4)-gamma-CO2] and by the two characteristic distances between the potentially active functional groups, alpha-N+-gamma-CO2 (d1) and alpha-CO2-gamma-CO2 (d2). The conformational preferences of 2,3,4-methyl(a and b)-cis and trans-1-aminocyclopentane-1,3-dicarboxylate are discussed in the light of the physical features known for specific metabotropic (groups I-II) and specific ionotropic (NMDA, KA) agonists, respectively. The spatial orientation of the perceived functional groups was elucidated in cyclic derivatives which contain an embedded L-glutamate moiety in a particularly restricted conformation (relative to the C(2)-C(3)-C(4) bond) using a combination of NMR experimental results and mechanics and dynamics calculations. One important conclusion of the study is that a single glutamate receptor is privileged for each theoretical model considered by molecular dynamics. This study showed clearly what would be conformational preferences of cyclic glutamate derivatives following the geometrical isomerism of the methyl group.

Solution conformation of alpha, beta or gamma-methylglutamyl-containing derivatives as probes of vitamin K-dependent carboxylase using molecular modelling and nuclear magnetic resonance.

In the present study, the conformational behaviour of methyl substituted N-BOC glutamic acid methyl esters (2M, 3T, 3E, 4T, 4E) has been completely characterized through combined NMR and molecular modeling studies. Hetero- and homonuclear coupling constants were measured in order to assign the remaining diastereotopic methylene protons at C(3) and/or C(4), and used for comparison with theoretical data. In parallel, the complete conformational analysis of these analogues has been achieved using molecular mechanics and molecular dynamics (MD) methods. The conformation of the glutamyl residue is established by the excellent agreement between the experimental and calculated side chain scalar coupling constants. The theoretical NMR data were calculated taking into account all the accessible conformations and using the averaging methods appropriate for internal motions. There is a significant influence of the methyl group on the conformational behaviour and on the biological relevance of these structures. Steric effect or electrostatic interaction may also have a considerable influence in stabilizing a conformational population in D2O solution. The conformational preferences of those different analogues in aqueous and methanol solution are discussed in the light of biological results obtained on the vitamin K-dependent carboxylase system.

Conformational analysis of glutamic acid analogues as probes of glutamate receptors using molecular modelling and NMR methods. Comparison with specific agonists.

The activity of five glutamic acid analogues substituted in position 3 or 4 by a methyl (3T, 3E, 4T, and 4E) or a methylene group (4M) has been examined at one cloned Glu receptor subtype, mGluR1. These analogues interact with glutamate receptors of the central nervous system, especially the ligand 4T [(2S,4S)-4-methylglutamic acid] at the metabotropic glutamate receptor mGluR1. It was observed that only the 4T isomer is as potent an agonist as glutamic acid, whereas other isomers are less active. Furthermore, 4E [(2S,4R)-4-methylglutamic acid] exhibited an exceptional selectivity for the KA ionotropic receptor subtype while 4M [(2S)-4-methyleneglutamic acid] was active at the NMDA receptors. These molecules represent suitable tools among a population of similar glutamate analogues for a classical structure-function relationship study. We have undertaken a conformational analysis by 1H and 13C NMR spectroscopy and molecular modelling of these molecules. Hetero- and homonuclear coupling constants were measured in order to assign the diastereotopic methylene protons at C(3) or C(4), and used for comparison in molecular dynamics (MD) simulations. The hydrogen-bonding possibility, steric effects or electrostatic interactions may be a considerable influence in stabilizing a conformational population in D2O solution. The conformations may be grouped by the two backbone torsion angles, chi 1 [alpha-CO2(-)-C(2)-C(3)-C(4)] and chi 2 [+NC(2)-C(3)-C(4)-gamma CO2-] and by the two characteristic distances between the potentially active functional groups, alpha N(+)-gamma CO2- (d1) and alpha CO2(-)-gamma CO2- (d2). The conformational preferences in solution of 4T, 4E and (3T, 3E, 4M) are discussed in the light of the physical features known for a specific metabotropic agonist (ACPD) and specific ionotropic agonists (KA) and (NMDA), respectively.

Vitamin K-dependent carboxylase. In vitro inhibitory activity of cyclopentane and cyclohexane-derived analogues of glutamic acid and their conformational study by NMR and molecular dynamics in aqueous solution.

The conformational analysis of four glutamic acid analogues containing a cyclopentyl or cyclohexyl ring, substituted in position 1 by a Boc-protected amino group and a methyl ester group and in position 3 by a free carboxylate group (6-9), has been carried out in an aqueous environment, by 1H and 13C NMR spectroscopy, and molecular dynamics (MD). These compounds have been shown to be weak competitive inhibitors (Ki approximately 20-65 mM) of the vitamin K-dependent carboxylation of Boc-Glu-OMe in rat liver microsomes independently of their ring size and stereochemical features. However, the cyclic trans isomers have been found more active than the cis ones, and Boc-trans-C5-OMe (9) is the most potent inhibitor in the series (cis and trans isomers are defined by the relative arrangement of the carboxyl functions). Such cyclic glutamyl derivatives may provide valuable informations on the preferred bioactive conformations of synthetic glutamyl substrates at the active site of the carboxylase. In aqueous solution, the Boc-cis- and trans-C6 esters exhibit chair conformations with exclusively equatorial and axial substituent positions, while the Boc-cis- and -trans-C5 compounds may display envelope E or 'twist' T conformations with the substituents in the following positions, equatorial; axial and isoclinal. For each compound, the conformations resulting from NMR and MD data were analyzed and classified according to the dihedral angles chi 1 and chi 2, the distances of functional groups, and the spatial charge distribution involving the free carboxyl group. A reduced number of conformational families were found to be in qualitative agreement with NMR and MD data. These results are discussed in relation with the carboxylase inhibitory activity of the analogues, and a spatial disposition of the glutamyl side chain that could be recognized by the carboxylase is deduced.

Conformational study in water by NMR and molecular modeling of cyclic glutamic acid analogues as probes of vitamin K dependent carboxylase.

The conformational analysis of four glutamic acid analogues containing a cyclopentyl or cyclohexyl ring, substituted in position 1 by a BOC protected amino group and a methyl ester group and in position 3 by a free carboxylate group, has been carried out in an aqueous environment, by 1H and 13C NMR spectroscopy, and molecular dynamics (MD). Their structural properties were under investigation for a structure-activity relationship analysis to determine the preferred conformation in the carboxylase active site. For each compounds, resulting conformations from NMR and MD data were analyzed and classified according to the dihedral angles chi 1 and chi 2, the distances and the spatial distribution involving charged or substituted C- and N-terminal groups. A reduced number of conformational families were found to be in qualitative agreement with NMR and MD data. A comparison between these different classes of the active and nonactive derivatives was achieved.