Phototoxicity of phenothiazine derivatives. II. Photosensitized cross-linking of erythrocyte membrane proteins

Irradiation in the presence of O₂, with near-UV light of five promazine (PZ) derivatives added to erythrocyte ghost membranes, causes covalent cross-linking between proteins as revealed by a progressive decrease in the amounts of proteins separable by electrophoresis after denaturation. The induction of cross-links in the two spectrin subunits is a single-hit process as a function of the irradiation time; relatively the rate constants (in min^?1) of the photoreactions were 0.060 with chlorpromazine (CPZ), 0.039 with methoxypromazine (MTPZ), 0.031 with PZ, 0.029 with triflupromazine (TFPZ) and 0.006 with acepromazine (ACPZ).A main photochemical intermediate implicated in the spectrin aggregation seems to be the cation radical of the PZ derivatives. Indeed, (i) the chemically generated cation radicals can induce the reaction in the dark; (ii) the photoaggregation is regularly reduced upon addition of increasing concentrations of NaN₃; (iii) NaN₃ similarly affects the amount of cross-links induced by the isolated cation radicals. Hydroxyl radicals are also involved in the photocross-linking when the reaction is initiated only by MTPZ and not by the other sensitizers.In the absence of oxygen during irradiation, PZ, MTPZ and ACPZ completely loose their cross-linking activities whereas CPZ and TFPZ remain as efficient as in the presence of oxygen.     

Two-dimensional separation of erythrocyte membrane proteins.

The details of a two-dimensional separation procedure specially designed for the study of erythrocyte membranes are presented. In this highly reproducible method, the membrane proteins are dissolved in sodium dodecyl sulfate and separated first on the basis of charge by isoelectric focusing. The samples are loaded either at the cathode (CIF) or anode (AIF). The CIF samples gave better separation of the acidic proteins, while the AIF was better for the separation of the high molecular weight polypeptides of the erythrocyte. Over 90 discrete polypeptides could be detected with this method in the pH range of 5 to 8. Special attention was given to the higher molecular weight components. For example, six components could be detected within the 90,000 to 100,000 molecular weight range of protein 3, the major membrane protein. A component with the same or very nearly the same molecular weight as spectrin band 2 was detected. It is more basic than spectrin band 2, and both spectrin band 2 and the basic component are readily phosphorylated in the intact cell. However, the phosphorylation of band 2 is cAMP independent while the phosphorylation of the basic component is enhanced by cAMP. In contrast to spectrin, the basic component is not extracted from the membrane with 0.1 mm EDTA, although dilute NaOH will remove it from the membrane. The Ca²⁺-activated transferase of the erythrocyte cytoplasm will not crosslink this component. Calcium does, however, activate the conversion of this component to a lower molecular weight. This high molecular weight basic component has properties attributed to the component labeled 2.1 in Fairbanks' system of nomenclature.     

Separation and some properties of the major proteins of the human erythrocyte membrane

A fractionation procedure is described which allows the isolation of three major human erythrocyte membrane proteins. Their isolation involves three sequential extraction procedures followed by gel filtration in 1% sodium dodecyl sulphate and preparative gel electrophoresis. All three proteins can be isolated from a single preparation. One of the proteins is the erythrocyte sialoglycoprotein, for which no C- or N-terminal residues were found. The other two proteins, which have not previously been isolated, have subunit molecular weights of 74000 and 93000 and contain 9 and 7% carbohydrate respectively. These glycoproteins have blocked N-terminal residues and show similarities in their chemical properties. Preparations derived from blood-group O erythrocytes contain no N-acetylgalactosamine, but similar preparations from blood-group A erythrocytes do contain this sugar. These three proteins cannot easily be solubilized by gentle aqueous procedures and represent about half of the erythrocyte ;ghost' protein. They carry a large proportion of the cell-surface carbohydrate.     

Photoactivated cross-linking of proteins within the erythrocyte membrane core.

We describe the reactions of three lipophilic, photoactivated cross-linking reagents, 1,5-diazidonapthalene, 4,4'-diazidobiphenyl, and the reversible 4,4'-dithiobisphenylazide, with erythrocyte membranes. Cross-linking occurs only upon photoactivation. At pH 7 to 8, only spectrin components are cross-linked by these reagents. At pH 5.0 to 5.5 several additional membrane proteins including the major "integral" membrane proteins are also cross-linked, despite equivalent binding of the cross-linkers at neutral and acid pH. The cross-linking rates of various membrane proteins at pH 5.0 to 5.5 depend distinctly upon duration of photoactivation. Bidimensional electrophoresis of membrane proteins after cross-linking with the reversible cross-linker, 4,4'-dithiobisphenylazide, has allowed for the identification of homopolymeric products of cross-linking (e.g. dimers and tetramers of Band 3) and heterocomplexes (spectrin plus other membrane proteins). The data suggest that at reduced pH, cross-linking can proceed not only at the membrane surface but also in the membrane core.     

Cystic fibrosis: II. Altered microviscosity of erythrocyte membrane

Erythrocyte membrane fluidity alterations in cystic fibrosis are described. The relative flexibility of the membrane was studied using lipid spin label, i.e. methyl-5-doxylpalmitate (M5DP), and pyrene as a fluorescence probe. It was found that there was a decrease of membrane fluidity in the hydrophobic midzone of the membrane, probed by pyrene, as well as at the hydrophilic surface region, probed by M5DP.     

Selective phosphorylation of erythrocyte membrane proteins by the solubilized membrane protein kinases.

This report describes the substrate and phosphoryl donor specificities of solubilized erythrocyte membrane cyclic adenosine 3',5'-monophosphate (cAMP)-independent protein kinases toward human and rabbit erythrocyte membrane proteins. Three types of substrate preparations have been utilized: heat-inactivated ghosts, isolated spectrin, and 2,3-dimethylmaleic anhydride (DMMA)-extracted membranes. A 30 000-dalton protein kinase, extracted from either human or rabbit erythrocyte membranes, catalyzes the phosphorylation of heat-inactivated membranes in the presence of ATP. The resulting phosphorylation profile is analogous to that of the autophosphorylation of membranes with ATP (in the absence of cAMP). These kinases also phosphorylate band 2 of isolated spectrin and band 3, but not glycophorin, in the DMMA-extracted ghosts. The ability of the 30 000-dalton kinases to use GTP as a phosphoryl donor appears to be related to the substrate or some other membrane factor. A second kinase, which is 100 000 daltons and derived from rabbit erythrocyte membranes, uses ATP or GTP to phosphorylate membrane proteins 2, 2.1, 2.9-3 in heat-inactivated ghosts, band 2 in isolated spectrin, glycophorin, and to a lesser extent, band 3 in the DMMA-extracted ghosts.     

Resolution of erythrocyte membrane proteins by two-dimensional electrophoresis.

A two-dimensional electrophoresis method has been developed which solubilizes erythrocyte membrane proteins, and which resolves the components of the band that migrates in detergent gels as if its molecular mass were 95,000 daltons. This method uses gel electrophoresis with sodium dodecyl sulfate in the first dimension and phenol, aqueous urea, and acetic acid in the second dimension. The 95,000 dalton band is known to contain several different membrane proteins, including those associated with anion transport, glucose transport, and (Na+,K+) transport. Two-dimensional electrophoresis resolved this band into one major spot and several minor ones. Pronase digestion of whole erythrocytes, followed by preparation of ghosts and two-dimensional electrophoresis, showed that only the major component of this band was digested by pronase.     

Modulation of erythrocyte membrane proteins by membrane cholesterol and lipid fluidity.

Human erythrocyte membranes were enriched or depleted of cholesterol and effects on membrane proteins assessed with a membrane-impermeant sulfhydryl reagent, [35S]glutathione-maleimide. Reaction of the probe with intact cells quantifies exofacial sulfhydryl groups and reaction with leaky ghost membranes permits quantification of endofacial sulfhydryl groups. The mean endofacial sulfhydryl titer of cholesterol-enriched membranes exceeded that of cholesterol-depleted membrane by approximately 45 nmol/mg of protein or 64%. The corresponding exofacial titer of cholesterol-enriched cells was less than that of cholesterol-depleted cells by approximately 0.4 nmol/mg of protein, or 14%. Labeled membranes were examined by autoradiography of sodium dodecyl sulfate-polyacrylamide gel electropherograms to determine the labeling patterns of individual protein bands. Cholesterol enrichment enhanced the surface labeling of Coomassie brilliant blue stained bands 1,2,3, and 5, decreased the labeling of band 6, and did not change significantly that of band 4. The results demonstrate that changes in membrane cholesterol which influence lipid fluidity can alter the surface labeling of both intrinsic and extrinsic membrane proteins.     

The phosphorylation of the major proteins of the human erythrocyte membrane.

Both the major sialoglycoprotein (PAS-1) and the component designated by Fairbanks et al. (G. Fairbanks, T. L. Steck, and D. F. H. Wallach, 1971, Biochemistry10, 2606–2617) as Band 3 are shown to be bonafide phosphoproteins by virtue of the presence of covalently bound serine and threonine phosphate residues. In agreement with the findings of others, PAS-1 does not seem to be phosphorylated when ghosts are incubated with [γ-³²P]ATP, but the phosphorylation is significant (about 0.15 mol/mol) when the cells are incubated in the presence of ³²P_i. Band 3 is phosphorylated to the extent of 0.90 mol/mol, and these sites are apparently distributed in several places along the polypeptide chain. Spectrin is also a phosphoprotein containing approximately four molecules of phosphate per 450,000 daltons of protein. The phosphorylation of these three polypeptides is not stimulated by the presence of cAMP.     

Thermotropic properties of human erythrocyte membrane proteins as affected by hydroxychloroaromatic compounds

The thermal stability of the anion transport protein (band 3) and other proteins of the human erythrocyte membrane, as influenced by hydroxychloroaromatic (HO-Cl2-Ar) compounds, was studied by differential scanning calorimetry. Various hydroxychlorodiphenyl ethers (HO-Clx-DPEs) and hexachlorophene, but not pentachlorophenol, caused a marked decrease in the thermal stability of band 3. Most of the other calorimetric transitions of the erythrocyte membrane were only slightly affected. The activity of HO-Clx-DPEs toward lowering the transition temperature of band 3 generally increased with the degree of chlorination, and was somewhat dependent on the position of hydroxyl substitution. At higher concentrations of HO-Clx-DPEs, there was a decrease in the enthalpy change and a broadening of the endothermic transition of band 3. The order of effectiveness of these compounds, as determined from band 3 denaturation temperatures, was similar to the order of potency previously observed for hemolysis of human erythrocytes.     

Unique profile for erythrocyte membrane acetylcholinesterase in hereditary spherocytosis

Acetylcholinesterase of human erythrocytes from healthy donors and from patients with hematological disorders was analysed in a search for differential membrane parameters. Two substrates were used to estimate the exposure of acetylcholinesterase active site in the membrane: phenylacetate, a hydrophobic substrate, to determine total enzyme activity, and acetylcholine, an ionic substrate, to measure the externally reactive enzyme. The sensitivity of acetylcholinesterase to added stearic acid was also analysed. Three categories of the disorders studied were discerned: (a) The erythrocyte acetylcholinesterase profile was indistinguishable from normal control in beta-thalassemia minor and groups of patients with autoimmune hemolytic anemia or congenital dyserythropoietic anemia type II. (b) A marked decline in acetylcholinesterase with both substrates and reduced sensitivity to stearic acid were exhibited by the erythrocytes of paroxysmal nocturnal hemoglobinuria, beta-thalassemia major and other autoimmune hemolytic anemia and congenital dyserythropoietic anemia type II patients. Normal erythrocytes, either aged or pretreated to 50 degrees C, also showed similar characteristics. (c) Hereditary spherocytosis was singly differentiated by an elevated acetylcholinesterase activity with acetylthiocholine and by a vastly diminished sensitivity to stearic acid, while activity with phenylacetate was equal to control. This distinct profile may reflect the unique organization of the erythrocyte membrane in hereditary spherocytosis.     

Effects of inherited membrane abnormalities on the viscoelastic properties of erythrocyte membrane.

Several workers have identified molecular abnormalities associated with inherited blood disorders. The present work examines how these alterations in molecular structure affect the viscoelastic properties of the red blood cell membrane. Changes in the membrane shear modulus, the membrane viscosity, and the apparent membrane bending stiffness were observed in cells of eight patients having a variety of disorders: Two had reductions in the number of high-affinity ankyrin binding sites, two had abnormalities associated with the protein band 4.1, and six were known to be deficient in spectrin. The data suggest that the membrane shear modulus is proportional to the density of spectrin on the membrane and support the view that spectrin is primarily responsible for membrane shear elasticity. Although membranes having abnormalities associated with the function of ankyrin or band 4.1 exhibited reduced elasticity, the degree of mechanical dysfunction was quantitatively inconsistent with the extent of the molecular abnormality. This indicates that these skeletal components do not play a primary role in determining membrane shear elasticity. The membrane viscosity was reduced in seven of the eight patients studied. The reduction in viscosity was usually greater than the reduction in shear modulus, but the degree of reduction in viscosity was variable and did not correlate well with the degree of molecular abnormality.