Effect Of Gd3 Research Articles

Direct interaction of GD3 ganglioside with mitochondria generates reactive oxygen species followed by mitochondrial permeability transition, cytochrome c release, and caspase activation.

Glycosphingolipids, including gangliosides, are emerging as signaling intermediates of extracellular stimuli. Because mitochondria play a key role in the orchestration of death signals, we assessed the interaction of GD3 ganglioside (GD3) with mitochondria and the subsequent cascade of events that culminate in cell death. In vitro studies with isolated mitochondria from rat liver demonstrate that GD3 elicited a burst of peroxide production within 15-30 min, which preceded the opening of the mitochondrial permeability transition, followed by cytochrome c (cyt c) release. These effects were mimicked by lactosylceramide and N-acetyl-sphingosine but not by sphinganine or sphingosine and were prevented by cyclosporin A and butylated hydroxytoluene (BHT). Reconstitution of mitochondria pre-exposed to GD3 with cytosol from rat liver in a cell-free system resulted in the proteolytic processing of procaspase 3 and subsequent caspase 3 activation. Intact hepatocytes or U937 cells selectively depleted of glutathione in mitochondria by 3-hydroxyl-4-pentenoate (HP) with the sparing of cytosol reduced glutathione (GSH) were sensitized to GD3, manifested as an apoptotic death. Inhibition of caspase 3 prevented the apoptotic phenotype of HP-treated cells caused by GD3 without affecting cell survival; in contrast, BHT fully protected HP-treated cells to GD3 treatment. Treatment of cells with tumor necrosis factor increased the level of GD3, whereas blockers of mitochondrial respiration at complex I and II protected sensitized cells to GD3 treatment. Thus, the effect of GD3 as a lipid death effector is determined by its interaction with mitochondria leading to oxidant-dependent caspase activation. Mitochondrial glutathione plays a key role in controlling cell survival through modulation of the oxidative stress induced by glycosphingolipids.

Hypotonicity activates a lanthanide-sensitive pathway for K+ release in A6 epithelia.

The nature of the pathway for K+ release activated during regulatory volume decrease (RVD) in A6 epithelia was investigated by measuring cell thickness (Tc) as an index of cell volume and by probing K+ efflux with 86Rb as tracer for K+ (RRb). Cell swelling was induced by sudden reduction of basolateral osmolality (from 260 to 140 mosmol/kgH2O). Experiments were performed in the absence of Na+ transport. Apical RRb was negligible in iso- and hyposmotic conditions. On the other hand, osmotic shock increased basolateral RRb (RblRb) rapidly, reaching a maximum 7 min after the peak in Tc. Quinine (0.5 mM) completely inhibited RVD and RblRb. Also verapamil (0.2 mM) impeded volume recovery considerably; lidocaine (0.2 mM) did not exert a noticeable effect. The K+ channel blocker Ba2+ (30 mM) delayed RVD but could not prevent complete volume recovery. Cs+ inhibited RVD noticeably at concentrations <40 mM. With large Cs+ concentrations (>40 mM), the initial osmometric swelling was followed by a gradual increase of Tc, suggesting activation of Cs+ influx. Chronic exposure of the basolateral surface to 0.5 mM La3+ or Gd3+ completely abolished RVD and RblRb. Acute administration of lanthanides at the time of osmolality decrease did not affect the initial phase of RVD and reduced RblRb only slightly. Apical Gd3+ exerted an inhibitory effect on RVD and RblRb. The effect of Gd3+ should therefore be localized at an intracellular site. The role of Ca2+ entry could be excluded by failure of extracellular Ca2+ removal to inhibit volume recovery. In contrast to lanthanides, chronically and acutely administered Mg2+ (0.5 mM) inhibited RVD and RblRb by approximately 50%. These data suggest that K+ excretion during RVD occurs through a rather poorly selective pathway that does not seem to be directly activated by membrane stretch.

Gadolinium blocks the delayed rectifier potassium current in isolated guinea-pig ventricular myocytes.

The effect of Gd3+ on the delayed rectifier potassium current (IK) in single guinea-pig ventricular myocytes was tested using whole-cell patch-clamp techniques. It was found that Gd3+ blocked 70% of the IK tail current at a concentration of 100 microM. The EC50 was 24 microM. Action potential durations were, however, reduced, consistent with a predominant effect on depolarizing L-type Ca2+ current (Ica.L). In the presence of 5 microM nifedipine Gd3+ prolonged the action potential. Using carbon fibres to stretch cells we observed that 10 microM Gd3+ was not effective in reducing a large stretch-activated increase in resting calcium. Modelling studies using the OXSOFT HEART program suggest that this lack of response is influenced by blockade of repolarizing current but is best reproduced by additional blockade of Ca2+ extrusion via the Na(+)-Ca2+ exchanger. When Gd3+ is used as a blocker of stretch-activated channels its actions upon both Ica.L and IK must therefore be accounted for.

Location of cholesterol in model membranes by magic-angle-sample-spinning NMR.

High-resolution magic-angle-sample-spinning 13C-NMR was applied to determine the specific location of cholesterol in non-perturbed multilamellar model membranes formed by egg yolk phosphatidylcholine. 13C spin-lattice relaxation times of both the phospholipid and cholesterol molecules were measured in the absence and in the presence of Gd3+, a paramagnetic agent, in order to obtain information on molecular distances. The effect of Gd3+ on the spin-lattice relaxation times of the lipid resonances has an explicit distance dependence, allowing it to be used to evaluate relative distances on a molecular scale. It has been found that cholesterol is placed in such a position that it is not readily exposed to the solvent: the hydrophobic steroid ring is oriented parallel to the membrane phospholipids, the hydroxyl group is in close vicinity to the phospholipid ester carbonyl groups and the isooctyl side chain is deeply buried in the center of the membrane. These data are consistent with an organization such that mixtures of cholesterol and phospholipids present a packing similar to that found in interdigitated lipid bilayer systems.

Regulation of Na + ,K + -ATPase α-Subunit Expression by Mechanical Strain in Aortic Smooth Muscle Cells

We have previously demonstrated that vascular sodium pump activity is stimulated in several rat models of hypertension. In addition, others have reported an upregulation of mRNA for the Na+,K+-ATPase alpha1-subunit in hypertension. To test the effect of sustained, cyclic, stretch-relaxation stimuli on the expression of alpha1- and alpha2-subunits of Na+,K+-ATPase in vascular smooth muscle cells, we used the Flexercell strain unit to stretch rat aortic smooth muscle cells for several days on a collagen-coated silicone elastomer substratum. Six-second cycles of stretch-relaxation were applied to obtain 10% average surface elongation (22% maximum) for 4 days. Control cells were not stretched but were grown on a similar surface. The effect of Gd3+, a blocker of stretch-activated channels, was also investigated. At the end of 4 days, protein expression of alpha1- and alpha2-subunits was determined by Western blot analysis. Intensity of the bands for alpha1- and alpha2-subunits was quantified with the use of a computerized image analyzer. In the stretched cells, both the alpha1- and the alpha2-subunit protein-band intensities were significantly increased compared with those of the non-stretched cells. Treatment with 50 micromol/L Gd3+ during the application of stretch prevented the upregulation of alpha2-expression but not that of alpha1-expression. Sodium pump activity, the functional counterpart of Na+,K+-ATPase, was inhibited as a result of stretch; Gd3+ had no effect on this variable. Our results suggest that in vascular smooth muscle, stretch may be a signal for the upregulation of both the alpha1- and alpha2-isoforms. However, a differential response of the two isoforms to the blocker of stretch-activated channels implies involvement of different mechanisms. This alteration in protein expression is not reflected in the function of the enzyme.

Gadolinium inhibits mechanoelectrical transduction in rabbit carotid baroreceptors. Implication of stretch-activated channels.

Gadolinium (Gd3+) has been shown to prevent mechanoelectrical transduction believed to be mediated through stretch-activated channels. We investigated the possible role of Gd(3+)-sensitive channels in mediating baroreceptor activity in the carotid sinus of rabbits. Baroreceptor activity induced by a ramp increase of carotid sinus pressure was reduced significantly during exposure to Gd3+. The inhibition was dose-related and reversible, and was not associated with alteration of carotid sinus wall mechanics as the pressure-strain relationship was unaffected. Veratrine triggered action potentials from single- and multiple-baroreceptor fibers when their response to pressure was inhibited by Gd3+. This suggests that the effect of Gd3+ on baroreceptors in the isolated carotid sinus was specific to their mechanical activation. The results suggest that stretch-activated ion channels sensitive to Gd3+ may be the mechanoelectrical transducers of rabbit carotid sinus baroreceptors.

Volume-activated, gadolinium-sensitive whole-cell currents in single proximal cells of frog kidney.

Stretch-activated channels (SACs) have been implicated in the control of epithelial cell volume. Such channels are generally sensitive to the trivalent lanthanide, gadolinium (Gd3+). In this study, using Gd3+ sensitivity and volume activation as indices, we have looked for ionic currents attributable to SACs using the whole-cell-patch clamp technique in freshly isolated proximal tubule cells of the frog. Hypotonic shock caused a reversible increase in whole-cell conductance, which was inhibited by Gd3+. In conjunction with this increase in conductance, cell length (measured using an optical technique) also increased. We observed two types of volume- and Gd(3+)-sensitive currents: voltage-dependent IVD and voltage-independent IVI. IVD was found in all cells, activated by depolarisation and hypotonic shock, and was inhibited reversibly by 10 microM Gd3+. The conductance did not discriminate between Na+ and K+ but was slightly anion-selective and was Ca(2+)-permeable. IVI was observed in only 50% of cells and was also inhibited by Gd3+. Although the inhibition was irreversible, it was dose-dependent, suggesting a specific effect of Gd3+ on IVI. Cells that showed IVI had a significantly higher conductance than those that did not (38.7 +/- 4.4, n = 20, and 20.5 +/- 0.7, n = 15, microS.cm-2 respectively). In contrast to IVD, IVI was mildly cation-selective, Ca(2+)-permeable, and also selective for Na+ over K+. As with IVD, volume-induced increases in IVI were inhibited by Gd3+. Both of these currents are activated during hypotonic shock and may be involved in volume-regulatory processes in frog proximal cells.

Effect of Gd3+ substitution for Y3+ in YLiF4, KLiYF5, and YVO4

The effect on Nd3+ Stark levels of substituting Gd for Y in YLiF4, KLiYF5, and YVO4 laser crystals is slight, as demonstrated in our spectra and in our best-fit crystal-field parameters. Gd-based crystals maintain the spectral properties of Y-based crystals while allowing for larger Nd concentrations.

Calcium-dependent chloride current activated by hyposmotic stress in rat lacrimal acinar cells.

We have identified a whole-cell Cl- current activated by hyposmotic stress in rat lacrimal acinar cells using the patch-clamp technique. Superfusion of isolated single cells with hyposmotic solution (80% of control osmolarity) caused a gradual increase of the current, which was reversed on return to the control solution. The current-voltage relationship showed outward rectification, and the current showed time and voltage dependence: slowly activated by depolarizing voltages and rapidly inactivated by hyperpolarizing voltages. The increase in current was not observed when intracellular Ca2+ was chelated with EGTA. It was also inhibited by the absence of extracellular Ca2+, or the presence of gadolinium ions (20 microM Gd3+). We conclude that in rat lacrimal acinar cells hyposmotic stress activates Ca(2+)-dependent Cl- channels as a result of Ca2+ influx through a Gd(3+)-sensitive pathway. The Cl- channels involved appear to be indistinguishable from those activated by muscarinic stimulation. The inhibitory effect of Gd3+ suggests that stretch-activated nonselective cation channels may be responsible for the Ca2+ influx.

Location of the Ca(2+)-transport site of Ca(2+)-transporting ATPase of the sarcoplasmic reticulum as determined by analysis of paramagnetic interaction between Gd3+ ions bound at the transport site and membrane-embedded nitroxide spin probes.

Gd3+ ions were bound to the Ca(2+)-transport site of Ca(2+)-transporting ATPase of the sarcoplasmic reticulum (SR-ATPase) and their effect on the ESR spectrum of spin-probes, which were attached to specific sites on SR-ATPase and embedded in the membranous lipid at various depths from the surface of the membrane, was studied. Spin-labeled reagents, 1-oxyl-2,2-dimethyl-oxazolidine derivatives of maleimidoethyl-keto stearate, collectively abbreviated as MSL(m,n) were mainly used for labeling SR-ATPase. They have Cm- and Cn-hydrocarbon chains, respectively, on both sides of the spin label, of which the Cm-hydrocarbon chain is located distal to the carboxyl group of the keto stearate moiety. Paramagnetic interaction between Gd3+ and a spin probe was detected by measuring the decrease in the intensity of the ESR signal of the probe. Displacement of Gd3+ from the Ca(2+)-transport site by Ca2+, which had been confirmed previously by using fluorescently labeled SR-ATPase (described in the preceding article), led to a significant reversal of the paramagnetic effect of Gd3+ on MSL(12,3) and MSL(10,5) attached to SR-ATPase. On the other hand, the effect of Gd3+ was not reversed by Ca2+ when SR-ATPase labeled with MSL(1,14) or a spin-label specific for the cytoplasmic domain was used. These results led us to conclude that the Ca(2+)-transport site of SR-ATPase is located in the membranous region of the molecule, but that the site is not very far from the surface of the membrane of the sarcoplasmic reticulum.

Gadolinium ions inhibit exocytotic vasopressin release from the rat neurohypophysis.

Single rat neurointermediate lobes (n.i.l.s) were fixed by their stalks to a platinum wire clip electrode and incubated in oxygenated Krebs-HEPES medium. Vasopressin release int the medium was determined by radioimmunoassay. Vasopressin secretion was increased by different stimuli and the effects of gadolinium (Gd3+) were tested. Electrical stimulation (15 Hz, three times 1 min with 1 min intervals) increased vasopressin release in a calcium-dependent manner. Gd3+ (10 microM to 3 mM) inhibited the evoked release of vasopressin in a concentration-dependent fashion; at 3 mM the inhibition was 98%. The inhibitory effect of Gd3+ up to 300 microM was antagonized by increasing the calcium concentration in the medium up to 6 mM. The effects of 1 and 3 mM-Gd3+ were unaffected by increasing the calcium concentration. Exposure of n.i.l.s to depolarizing concentrations of potassium (high K+, 60 mM, 30 min) increased the vasopressin release more than 33-fold. The elevated vasopressin release remained constant during six consecutive 5 min periods. In the initial 5 min period 300 microM-Gd3+ reduced the evoked vasopressin release by 80% but during the last 5 min period only by 30%. At 3 mM-Gd3+ vasopressin release was completely blocked during the whole time of incubation with high K+. Vasopressin release induced by exposure of n.i.l.s to cold (4 degrees C, 20 min) was completely inhibited by 3 mM-Gd3+, but reduced by only 25% in the presence of 300 microM-Gd3+. Vasopressin release induced by incubation of n.i.l.s with the ionophore X-537A (lasalocid) (10 microM, 30 min) was reduced by 90% in the presence of 300 microM-Gd3+ and completely prevented by 3 mM-Gd3+. 300 microM-Gd3+, added to the incubation medium, had no significant effect on the vasopressin release from crude synaptosomal preparations evoked by high K+. However, when 300 microM-Gd3+ was already present during the tissue homogenization, the evoked vasopressin release from the synaptosomes was completely blocked. It is concluded that Gd3+ inhibits exocytotic vasopressin release at two different sites. First, Gd3+ may block voltage-regulated calcium channels. Secondly, Gd3+ may inhibit the exocytotic release mechanism by an intracellular site of action. It is speculated that contractile proteins may be the intracellular target for Gd3+.

The location of the calcium ion binding site in bovine alpha-trypsin and beta-trypsin using lanthanide ion probes.

The effect of Gd3+ on the nuclear magnetic resonance (NMR) relaxation rates, T1m-1 and T2m-1, of inhibitor protons in metal-inhibitor-trypsin ternary complexes has been measured. The Solomon-Bloembergen equations have been used to calculate distances of 10.0 +/- 0.5, 8.8 +/- 0.5, and 9.5 +/- 0.5 A between the metal ion and the methyl and ortho protons of p-toluamidine, and the methyl protons of acetamidine, respectively. Essentially the same results are obtained for both alpha-trypsin and beta-trypsin. Binding constants of 3.3 x 10(3) and 4.1 x 10(3) M-1 for the association of Gd(III) with alpha-trypsin and beta-trypsin, respectively, in the presence of p-toluamidine at pH 6.0 have been obtained by equilibrium dialysis. Calcium binding constants of 260 and 3700 M-1 at pH 6.0 and 8.0, respectively, with beta-trypsin have also been obtained. Calcium ion and gadolinium ion compete for the same site on the protein. Calcium has been shown to protect alpha-trypsin from further autolytic degradation to psi-trypsin. From examination of the crystal structure of the enzyme we propose that the calcium ion binding site of bovine trypsin is comprised of the side chains of Asp-194 and Ser-190 (based on the chymotrypsin sequence numbering system). This seems to be the only site which is comprised of at least one carboxyl group; which fits our distance requirements and which is conisistent with other chemical data.