ESR spectral changes induced by chlorpromazine in spin-labeled erythrocyte ghost membranes

Chlorpromazine interacted preferentially with membrane proteins rather than membrane lipids in the initial incorporation into human erythrocyte ghosts, as demonstrated by means of the fluorescence quenching and a maleimide spin label. In this state the membrane fluidity increased. At higher concentrations of chlorpromazine, the membrane fluidity decreased and a motionally restricted signal from fatty acid spin labels appeared predominantly. However, no such signal appeared in protein-free vesicles. The temperature and pH dependences of the outer hyperfine splitting of this restricted signal were very similar to those of bovine serum albumin. On the basis of sodium dodecyl sulfate-polyacrylamide gel electrophoresis of chlorpromazine-treated and -untreated ghosts, it was found that there was no significant difference in membrane proteins between both samples except for the changes of a few bands which were not directly concerned with the occurrence of this restricted signal. These results suggest that the fatty acid spin labels bind preferably to membrane proteins as the lipid domain becomes packed with chlorpromazine.     

ESR spectral changes induced by chlorpromazine in spin-labeled erythrocyte ghost membranes

chlorpromazine interacted preferentially with membrane proteins rather than membrane lipids in the initial incorporation into human erythrocyte ghosts, as demonstrated by means of the fluorescence quenching and a maleimide spin label. In this state the membrane fluidity increased. At higher concentrations of chlorpromazine, the membrane fluidity decreased and a motionally restricted signal from fatty acid spin labels appeared predominantly. However, no such signal appeared in protein-free vesicles. The temperature and pH dependences of the outer hyperfine splitting of this restricted signal were very similar to those of bovine serum albumin. On the basis of sodium dodecyl sulfate-polyacrylamide gel electrophoresis of chlorpromazine-treated and -untreated ghosts, it was found that there was no significant difference in membrane proteins between both samples except for the changes of a few bands which were not directly concerned with the occurrence of this restricted signal. These results suggest that the fatty acid spin labels bind preferably to membrane proteins as the lipid domain becomes packed with chlorpromazine.     

Changes of erythrocyte deformability induced by calcium accumulation and calmodulin inhibitors

The deformability of human erythrocytes was investigated with a rheoscope to study the role of intracellular calcium in the dynamic cytoskeletal structure. Calcium was loaded to or depleted from erythrocytes with a calcium ionophore (A 23187) in a Na- or a K-HEPES buffer. (1) After calcium loading in the Na-HEPES buffer, the cell volume of erythrocytes was greatly reduced due to dehydration. On the contrary, upon calcium-loading or -depletion in the K-HEPES buffer, the intracellular calcium content could be varied in the range of 1/4 to 3 times as much as that of control cells without the reduction of mean cell volume. Further incubation without A 23187 and calcium in the K-HEPES buffer enabled the calcium-loaded erythrocytes to restore the cell shape and the ATP concentration. (2) When intracellular calcium content was increased to above 1.5 times of the normal value, the deformability was distinctly decreased. On the other hand, the deformability was unchanged when the intracellular calcium content was reduced below the normal level. (3) The deformability, once decreased due to the calcium accumulation, was recovered by the treatment with a calmodulin inhibitor, W-7 or trifluoperazine, while these drugs were not effective on the deformability of control or calcium-depleted erythrocytes. We conclude that the membrane stiffness which influence the deformability of erythrocytes, is modulated by the intracellular calcium content through the interaction between the calcium-calmodulin complex and the cytoskeletal proteins.     

Regulation of erythrocyte ghost membrane mechanical stability by chlorpromazine

Chlorpromazine (CPZ), a widely used tranquilizer, is known to induce stomatocytic shape changes in human erythrocytes. However, the effect of CPZ on membrane mechanical properties of erythrocyte membranes has not been documented. In the present study we show that CPZ induces a dose-dependent increase in mechanical stability of erythrocyte ghost membrane. Furthermore, we document that spectrin specifically binds to CPZ intercalated into inside-out vesicles depleted of all peripheral proteins. These findings imply that CPZ-induced mechanical stabilization of the erythrocyte ghost membranes may be mediated by direct binding of spectrin to the bilayer. Membrane active drugs that partition into lipid bilayer can thus induce cytoskeletal protein interactions with the membrane and modulate membrane material properties.     

Vinculin phosphorylation by the src kinase: inhibition by chlorpromazine, imipramine and local anesthetics

The phosphorylation of vinculin by a highly purified $\text{src}$ kinase was stimulated by anionic phospholipids and inhibited to varying degrees, by chlorpromazine, imipramine, dibucaine and tetracaine. The drug effects are ascribed to a competitive inhibition of the activation process by their ability to interact with phospholipid.     

Distribution of chlorpromazine and imipramine in adipose and other tissues of rats

Adipose tissue kinetics of chlorpromazine and imipramine, two drugs which are more lipophilic than thiopental, were studied in the rat. After single i.v. doses, the time-course of drug distribution was followed in adipose and various other tissues, until their concentrations in adipose tissues declined. Under these conditions the two drugs behaved almost identically. Among the tissues analyzed, the lowest concentrations were found in adipose tissue, with the exception of plasma. At its maximum concentration after about 30 minutes, total adipose tissue contained only 3 % of the dose of administered drugs. Adipose/plasma and adipose/lung concentration ratios were 2–5 and 0.05, respectively.After maximum tolerated oral doses of imipramine for 3 weeks, similar steady state concentration ratios (plasma:adipose:brain:lung 1:3:12:96) were observed. In adipose tissue the imipramine/desmethylimipramine ratio was about 1, and the desmethylimipramine steady state levels did not increase with time. Literature data indicate that many basic lipophilic drugs are not stored in adipose tissue. This is now clearly shown for chlorpromazine and imipramine, even under extreme, subchronic conditions in the case of imipramine.     

Changes in morphology and cell cycle traverse induced in CHO cells by methyl isobutyl xanthine

Methyl isobutyl xanthine (MIX) added to the medium of CHO cells induced a transient elevation of intracellular cAMP concentration. Values which were maximal after 30 min incubation in MIX subsequently declined until after 4–5 h incubation cAMP levels in MIX-treated cells were the same as those of controls. Following addition of MIX to the medium, several perturbations of cell cycle traverse were observed, including a block early in G1 which delayed progress of the cell through subsequent phases of the cell cycle by approx. 1 h, inhibition of transport of exogenous thymidine, arrest of cells in G2 and early M and more rapid completion of mitosis when MIX was added to metaphase cells. None of these changes persisted during prolonged incubation in MIX and cell cycle parameters of cells growing continuously in 0.2 mM MIX were identical with those of their control counterparts. In contrast, conversion from epithelial to fibroblast morphology induced by MIX persisted as long as MIX was maintained in the medium and thus appeared to be independent of elevation of cAMP levels. Morphological conversion was not related to any of the modifications of cell cycle traverse induced by short exposure to MIX.     

Changes in phosoholipid susceptibility toward phospholipases induced by ATP depletion in avian and amphibian erythrocyte membranes.

About half of the sphingomyelin content of fresh and ATP-depleted chicken erythrocytes is hydrolysed by sphingomyelinase. Removal of spingomyelin exposes the rest of the membrane phospholipids to hydrolysis by phospholipase C only in ATP-depleted but not in fresh cells. Addition of both sphinogomyelinase and phospholipase C to ATP-depleted cells causes about 60-70 percent hydrolysis of the total phospholipids accompanied by extensive (90 percent) hemolysis. The phospholipids of toad erythrocytes are partially available to phospholipase C activity in fresh cells (17-25 percent hydrolysis) without prior sphingomyelinase treatment. However, in ATP-depleted toad cells phospholipase C hydrolyses 66 percent of phospholipids and causes extensive lysis. Treatment of either fresh or ATP-depleted toad erythrocytes by sphingomyelinase together with phospholipase C induces hydrolysis of most of the phospholipds with complete lysis. Restoration of ATP to ATP-depleted cells endows them with resistance to the attack of phospholipase C. The correlation between changes in ATP level and membrane organization as revealed by increased susceptibility toward phospholipases is discussed.     

pH-dependent effects of chlorpromazine on liposomes and erythrocyte membranes

Chlorpromazine (CPZ) is an amphipathic antipsychotic drug that binds to erythrocytes reaching in this way the central nervous system. CPZ is a basic molecule with pK=8.6. This paper reports on CPZ-induced lysis of red blood cells and liposomes. Haemolysis was tested under hypotonic conditions, in the pH range 5.0-10.0. Cell sensitivity towards CPZ increased with increasing pH. Increasing pH caused also a decrease in the critical micellar concentrations of CPZ. These results are interpreted in terms of a competition between repulsive electrostatic forces and attractive hydrophobic forces, that would act both in pure CPZ and in mixed CPZ-phospholipid micelles. In order to eliminate possible pH effects mediated by red blood cell proteins, experiments were carried out in which CPZ induced release of a fluorescent dye from liposomes (large unilamellar vesicles). The latter observations confirmed that membrane sensitivity towards CPZ was increased at higher pH.     

Changes in the erythrocyte membrane-cytoskeleton complex induced by dimethyl sulfoxide, polyethylene glycol, and low temperature

The effect of the cryoprotectants DMSO and PEG-1500 as well as freezing-thawing on the proteins of the canine erythrocyte membrane-cytoskeleton complex was studied using the cross-linking agent diamide. It was shown that the intensity of disturbances in the protein network structure correlated with the increased SH-group accessibility for oxidative bridging by this compound and accordingly, enhanced formation of high-molecular-weight protein aggregates. The maximum level of diamide-induced aggregability was revealed upon freezing of erythrocytes in liquid nitrogen without cryoprotectant. Electrophoretic analysis of the ghosts of erythrocytes incubated with cryoprotectants showed a significant increase in the aggregation level only for the cells in the polymer solution. After the freezing-thawing cycle, the diamide-induced protein aggregability in erythrocytes cryopreserved with PEG-1500 strongly increased; when DMSO was used for cell protection, the aggregation was much less pronounced than in the unprotected cells. One can suppose that the exocellular cryoprotectant PEG-1500, as distinct from the endocellular cryoprotectant DMSO, is unable to provide for preservation of the structure of the membrane-cytoskeleton protein complex at a level necessary for the maintenance of cell integrity after the return to physiological conditions.     

Interaction of chlorpromazine with the human erythrocyte membrane

The interaction of the amphipath chlorpromazine (CPZ) with the human erythrocyte membrane was evaluated. The partition coefficient of CPZ between the membrane bilayer and the aqueous compartment, measured spectrophotometrically, ranged between 1 and 3 X 10(3). An independent estimate, 4.6 X 10(3), was obtained by a novel method which avoided the measurement of binding and determined instead the variation of the hemolytic potency of the amphipath with the ratio of buffer volume to membrane volume. The maximal uptake of CPZ exceeded 2 X 10(9) molecules/red cell, corresponding to a volume greater than that of the bilayer itself. Such heavily loaded membranes were increased in thickness more than 2-fold, suggesting the formation of a CPZ-rich zone at the center of the bilayer. Ghosts loaded with massive levels of CPZ condensed approximately 20-fold in surface area and increased proportionately in thickness, suggesting the formation of a novel CPZ-lipid solution. CPZ caused hemolysis by a colloid-osmotic mechanism. By measuring the simultaneous uptake of mannitol and sucrose, we determined that CPZ induced holes of constant size but variable number. If circular, the holes would have had a diameter of approximately 14 A. The time-averaged number of holes ranged from 0.09 per cell (signifying intermittency) to 16. Freeze-fracture electron microscopy of CPZ-treated red cells revealed multiple round patches of nearly particle-free bilayer up to 0.3 micron in diameter with crowding of the intramembrane particles into the surrounding membrane. We interpret these images to signify lateral phase separation within the CPZ-treated bilayer. Hemolysis could, therefore, result from the intermittent opening of weak seams at phase boundaries; these could then be fluctuating slits approximately 14 A in width and of variable length, rather than simple circular holes.     

On erythrocyte morphology.

The significance of the distinctive morphological difference between mammalian and non-mammalian vertebrate erythrocytes (disc versus ellipse) is discussed in the light of mammalian erythrocyte rheology.