Perturbation effect of the diheptanoyl phosphatidylcholine on rat brain total lipid liposomes. An electron paramagnetic resonance spectroscopy study.

Diheptanoyl phosphatidylcholine (DHPC) was reported to reduce inward sodium current in squid giant axons (Hendry et al., Biophys. J., 47, (1985) 841) and to decrease the frequency of the nicotinic acetylcholine-activated ion channel (Braun and Haydon, Pfügers Arch., 62, (1991) 418). To understand the DHPC effects, an influence of DHPC to increase dynamics/disorder (perturbation effect) in liposomes prepared from rat brain total lipids was studied at the 5th, 12th and 16th carbon membrane depths using the method of EPR spectroscopy of the spin labelled stearic acids and 1-palmitoyl-2-stearoyl phosphatidylcholines. The perturbation efficiency of DHPC in the liposomes was quantitated with the initial slope value of the order parameter S or inner splitting Amin versus DHPC concentration. DHPC at the DHPC/total lipid molar ratio of 1:10, 1:5, 1:3 and 1:2 increased dynamics/disorder of the liposomes. When the perturbation effect, compared at temperature scale, was normalized to 1 at the 5th carbon depth, the relative perturbation effect of DHPC was 1, 4.2, and 6.9 at the 5th, 12th and the 16th carbon depth, respectively, as detected by spin labelled stearic acids. Using the spin labelled lipids the perturbation effect was 1, 1.9 and 2.3, respectively. The differences of the perturbation effect of DHPC at different membrane depths correspond to the published perturbation effect of the local anesthetics lidocaine, tetracaine, dibucaine, heptacaine, IR-9 and carbisocaine on total lipid liposomes. The comparable perturbation properties of DHPC and of the local anesthetics support the hypothesis that the membrane perturbation caused by DHPC may play an important role in its effect on membrane function.     

Progress of migrating Atlantic salmon (Salmo salar) along an estuary, observed by ultrasonic tracking

Adult Atlantic salmon were captured in the Miramichi esturary, tagged with ultrasonic transmitters, and released. Nine fish were tracked for a total of 425 h, spanning 71 flood and ebb tides. There was drifting with the tidal currents, and holding of position relative to land. Fish that achieved overall upstream progress did so by drifting with flood tidal currents and by stemming the ebb currents. Fish which did not achieve upstream progress also drifted with flood tidal currents, but these fish did not stem the ebb currents and dropped back downstream during ebb tides. No differences in movement patterns were apparent for different times of day or wind conditions.     

A spin probe study of the effects of chlorpromazine and its derivatives on lipid-protein interactions in synaptosomal membranes.

The electron spin resonance spectra of 16-doxyl stearic acid (16-SA) incorporated into synaptosomes mostly showed a fluid lipid component and a minor motionally-restricted component (MRC) of the molar fraction of 10-20%, measured at 0 degree C. At 10 mmol/l concentration, thioridazine (TRZ), chlorpromazine (CPZ), chlorprothixene (CPT), perphenazine (PFZ) and levopromazine (LPZ) raised the MRC molar fraction in the synaptosomes to 100, 92, 65, 41 and 39%, respectively (as detected by the spin probe at 0 degrees C). At 4% concentration, TRZ, CPZ, CPT, PFZ, and LPZ the respective MRC percentages were 100, 75, 41, 24 and 17%. In synaptosomal membranes, AMRC splitting values of MRC, induced by TRZ and CPZ, were similar to those of the probe in human serum albumin. MRC induced by CPZ and TRZ was constant (+/- 15%) within the temperature range from 0 to 30 degrees C. At drug/lipid ratios > or = 2 : 1, TRZ and CPZ formed rigid complexes with total lipids isolated from the rat brain. The complexes melted upon increasing the temperature of the samples over 10-20 degrees C. The drugs decreased the lipid concentrations in synaptosomes in the order of potency TRZ > CPZ > CPT > PFZ > or = LPZ; this was similar to their effect on MRC increase. The drugs tested increased the membrane dynamics/disordering, and their potency fairly correlated with their MRC increasing effects. It is supposed that the drug-induced 16-SA probe MRC increase in synaptosomes was a result of mainly decreased lipid/protein ratio in the synaptosomal membranes, which in turn probably is connected with perturbation of lipid-protein interactions and/or membrane proteins. The perturbation of lipid-protein interactions and/or membrane proteins may be connected with the drug perturbation effect on the bulk lipid membrane part.     

Influence of beta-adrenoceptor blocking drugs on lipid-protein interaction in synaptosomal membranes. An ESR study

The influence of the beta-adrenoceptor blocking drugs atenolol, doberol, propranolol and exaprolol on synaptosomal membranes was studied using ESR spectroscopy of stearic acid spin labeled at the 16th position. The drugs changed the ESR spectra of the label in the membranes, where in addition to changes of a fluid lipid component they increased the proportion of a motionally-restricted component. No motionally-restricted component was found in the samples prepared from brain total lipid liposomes treated with the drugs. The drug propensities at 20 mmol/l concentration to increase the proportion of the motionally-restricted component in the following order, control less than doberol approximately atenolol less than or equal to propranolol less than exaprolol did not correlate with their potency to influence the dynamics of the bulk lipid membrane phase. The motionally-restricted component induced by exaprolol increased with raising temperature and prolongation of time of the sample incubation. The results indicate that the beta-adrenoceptor blocking drugs influence lipid-protein interaction in the synaptosomal membranes, which could be important for elucidation of their mechanism of biological membrane activities.