Membrane protein phosphorylation in intact normal and sickle cell erythrocytes

Characterization of Phosphorylated Proteins Using Mass Spectrometry

Phosphorylation is arguably the most important post-translational modification that occurs within proteins. Phosphorylation is used as a signal to control numerous physiological activities ranging from gene expression to metabolism. Identifying phosphorylation sites within proteins was historically a challenge as it required either radioisotope labeling or the use of phospho-specific antibodies. The advent of mass spectrometry (MS) has had a major impact on the ability to qualitatively and quantitatively characterize phosphorylated proteins. In this article, we describe MS methods for characterizing phosphorylation sites within individual proteins as well as entire proteome samples. The utility of these methods is illustrated in examples that show the information that can be gained using these MS techniques.

Anisotropic light scattering of individual sickle red blood cells

We present the anisotropic light scattering of individual red blood cells (RBCs) from a patient with sickle cell disease (SCD). To measure light scattering spectra along two independent axes of elongated-shaped sickle RBCs with arbitrary orientation, we introduce the anisotropic Fourier transform light scattering (aFTLS) technique and measured both the static and dynamic anisotropic light scattering. We observed strong anisotropy in light scattering patterns of elongated-shaped sickle RBCs along its major axes using static aFTLS. Dynamic aFTLS analysis reveals the significantly altered biophysical properties in individual sickle RBCs. These results provide evidence that effective viscosity and elasticity of sickle RBCs are significantly different from those of the healthy RBCs.

Altered phosphorylation of cytoskeleton proteins in sickle red blood cells: the role of protein kinase C, Rac GTPases, and reactive oxygen species

The small Rho GTPases Rac1 and Rac2 regulate actin structures and mediate reactive oxygen species (ROS) production via NADPH oxidase in a variety of cells. We have demonstrated that deficiency of Rac1 and Rac2 GTPases in mice disrupts the normal hexagonal organization of the RBC cytoskeleton and reduces erythrocyte deformability. This is associated with increased phosphorylation of adducin at Ser-724, (corresponding to Ser-726 in human erythrocytes), a domain target of protein kinase C (PKC). PKC phosphorylates adducin and leads to decreased F-actin capping and dissociation of spectrin from actin, implicating a significant role of such phosphorylation in cytoskeletal remodeling. We evaluated adducin phosphorylation in erythrocytes from patients with sickle cell disease and found it consistently increased at Ser-726. In addition, ROS concentration is elevated in sickle erythrocytes by 150-250% compared to erythrocytes from normal control individuals. Here, we review previous studies demonstrating that altered phosphorylation of erythrocyte cytoskeletal proteins and increased ROS production result in disruption of cytoskeleton stability in healthy and sickle cell erythrocytes. We discuss in particular the known and potential roles of protein kinase C and the Rac GTPases in these two processes.

Increased tyrosine phosphorylation of band 3 in hemoglobinopathies

In order to investigate the tyrosine phosphorylation of band 3, we performed immunoblotting of intact red cells using anti-phosphotyrosine antibody of 21 patients with sickle cell disorders (11 SS, 5 Sbeta, 5 SC), 7 patients with beta thalassemias (5 beta thal intermedia, 2 deltabeta thal), 10 normal controls, and 1 patient with hereditary spherocytosis. They had not received transfusion for the last 4 months and all were clinically stable. Our results showed an increased tyrosine phosphorylation of two proteins, in the 100 and 80 kD regions, in sickle cell and beta-thalassemic red cells when compared to the normal controls and to the patient with hereditary spherocytosis. Immunoprecipitation of the lysed red cells with anti-band 3 antibody and immunoblotting with anti-phosphotyrosine antibody confirmed that the 100 kD tyrosine phosphorylated protein was band 3. In the sickle cell disease group, the band 3 tyrosine phosphorylation varied from 2- to 10-fold increase compared to control (x +/- SD; SS = 7.8- +/- 2.7-fold; SC = 3.8- +/- 1.3-fold; Sbeta = 5.2- +/- 2.0-fold). It was also higher in the beta-thalassemic group (beta-thal = 4.3- +/- 3.7-fold). There was no significant difference in tyrosine phosphorylation among the various groups tested, except when we compared the phosphorylation in intact red cells of patients with sickle cell anemia and hemoglobinopathy SC (U = 6, P < 0.02). The tyrosine phosphorylation of band 3 was increased in hemoglobinopathies even in the absence of high reticulocyte count. At least two mechanisms might be involved in the increased tyrosine phosphorylation of band 3 in these hemoglobin disorders, probably related to the endogenous reactive oxygen intermediates generated by the abnormal erythrocyte: an inhibition of protein tyrosine phosphatase activity or an activation of the protein tyrosine kinase p72syk.

The state of association of Band 3 of the human erythrocyte membrane: evidence of a hexamer

Band 3 of the human erythrocyte membrane was isolated from 32P-labelled erythrocytes in non-ethyleneglycol n-dodecyl ether (C12E9), Triton X-100, and Brij 58 solutions, and its states of association were studied by sucrose gradient sedimentation and by Sepharose 4B column chromatography. The sedimentation and elution profiles indicated that Band 3 exists under two stable forms in each detergent solution, a slow form and a fast form. The fraction of the fast form in a Brij 58 solution was 2-3-times higher than those of the fast forms in C12E9 and Triton X-100 solutions. Moreover, depending of the conditions of isolation, only the slow form or the fast form was present in a Brij 58 solution. The apparent values of sedimentation coefficients, Stokes radii, and effective masses of the slow and fast forms in C12E9, Triton X-100, and Brij 58 solutions were determined. On the basis of these values, we have concluded that the slow and fast forms of Band 3 were dimer and tetramer in C12E9 and Triton X-100 solutions but were dimer and hexamer in a Brij 58 solution.

Altered erythrocyte protein kinase C activity and membrane protein phosphorylation in chronic myelogenous leukemia

The membrane protein kinase C (PKC) content was found to be higher in erythrocytes form patients suffering from chronic myelogenous leukemia (CML) compared to normal erythrocytes. PKC activity was also higher in the cytosol and after translocation to the membrane, as assessed by histone phosphorylation. The increased PKC activity in CML erythrocytes was associated with abnormal phosphorylation of protein 4.1. Since phosphorylation-dephosphorylation mechanisms are likely candidates for controlling membrane protein associations, the altered PKC activity may be one of the factors responsible for altered thermal sensitivity and mechanical stability of CML erythrocytes.

Alteration in protein kinase C activity and subcellular distribution in sickle erythrocytes

In agreement with previous data, membrane protein phosphorylation was found to be altered in intact sickle cells (SS) relative to intact normal erythrocytes (AA). Similar changes were observed in their isolated membranes. The involvement of protein kinase C (PKC) in this process was investigated. The membrane PKC content in SS cells, measured by [3H]phorbol ester binding, was about 6-times higher than in AA cells. In addition, the activity of the enzyme, measured by histone phosphorylation was also found to be increased in SS cell membranes but decreased in their cytosol compared to the activity in AA cell membranes and cytosol. The increase in membrane PKC activity was observed mostly in the light fraction of SS cells, fractionated by density gradient, whereas the decrease in cytosolic activity was only observed in the dense fraction. PKC activity, measured in cells from the blood of reticulocyte-rich patients, exhibited an increase in both membranes and cytosol, thus explaining some of the effects observed in the SS cell light fraction, which is enriched in reticulocytes. The increase in PKC activity in the membranes of SS cells is partly explained by their young age but the loss of PKC activity in their cytosol, particularly in that of the dense fraction, seems to be specific to SS erythrocytes. The relative decrease in membrane PKC activity between the dense and the light fractions of SS cells might be related to oxidative inactivation of the enzyme.

Methanol production by Mycobacterium smegmatis

Mycobacterium smegmatis cells produce [3H]methanol when incubated with [methyl-3H]methionine. The methanol is derived from S-adenosylmethionine rather than methyltetrahydrofolate. M. smegmatis cells carboxymethylate several proteins, and some of the methanol probably results from their demethylation, but most of the methanol may come from an unidentified component with a high gel mobility. Although methanol in the medium reached 19 microM, it was not incorporated into the methylated mannose polysaccharide, a lipid carrier in this organism.

Membrane protein phosphorylation during stomatocyte-echinocyte transformation of human erythrocytes

The normal, discoid shape of red blood cells represents an equilibrium between two opposing factors, i.e., stomatocytic and echinocytic transformations. Most stomatocytic agents were found to be inhibitors of calmodulin, a regulator of the phosphorylation of membrane proteins. We determined whether red cell shape transformations could be caused by changes in phosphorylation of membrane proteins, specifically the cAMP-dependent phosphorylation of ankyrin and band 4.1. Red blood cells were incubated with 32P and 100 microM chlorpromazine (stomatocytic transformation) or 30 mM sodium salicylate (echinocytic transformation) for various time intervals. Ghost membrane proteins were examined by polyacrylamide gel electrophoresis and autoradiography. Spectrin (beta-chain), ankyrin, band 3, band 4.1 and 4.9 were phosphorylated. No change was found in the degree and pattern of phosphorylation after stomatocytic transformation. Salicylate caused a reversible inhibition of transmembranous phosphate transport in both directions. The results indicate that the stomatocytic transformation induced by chlorpromazine and the echinocytic transformation induced by salicylate do not involve a change in phosphorylation, but that the echinocytic transformation induced by salicylate is associated with an inhibition of transmembranous transport of phosphate. Studies with salicylate suggest that the phosphorylation sites of band 3 are found mainly on the endofacial side of the membrane.

The phosphoproteins of the sickle erythrocyte membrane

The uptake of 32P from exogenous 32Pi into membrane proteins of sickle erythrocytes has been analyzed. The phosphorylation of spectrin is normal in sickle cells. There is, however, a substantial increase in 32P in the sialoproteins of the membrane, which can be demonstrated after fractionation or selective proteolysis. Normal and sickle erythrocytes were separated on Stractan gradients and average cell age was determined using the remaining pyruvate kinase activity as a marker. The altered phosphorylation of sickle cells was not seen in young normal cells, suggesting that it was not related to cell age. The altered phosphorylation was also not correlated with the level of reticulocytes in these fractions. This result is further evidence for abnormalities in the sialoproteins of sickle erythrocytes and is the first demonstration of altered sialoprotein phosphorylation in the red cell.

Altered spectrin association and membrane fragility without abnormal spectrin heat sensitivity in a case of congenital hemolytic anemia

In hereditary pyropoikilocytosis (HPP) and one type of hereditary elliptocytosis (HE), spectrin self-association is abnormal [5,7]. Spectrin extracted from normal erythrocyte membranes at 0 degree C is nearly all tetrameric, while in HPP and HE (type 1) a substantial amount of the extracted spectrin is dimeric. Abnormal reassociation of spectrin dimers to tetramers can also be demonstrated. We here report the case of a family in which the child has moderately severe hemolysis, with extreme microcytosis and poikilocytosis. The spectrin extracted at 0 degree C was predominately dimer. Parents had levels of dimer intermediate between patient and control values. The temperature dependence was normal for erythrocyte fragmentation; spectrin extractability; and circular dichroism of purified spectrin. Neither the patient nor either parent had elliptocytic red cells as judged from smears and scanning electron microscopy. The presence of substantial amounts of dimeric spectrin in the parents is consistent with a model in which each parent is heterozygous for a different nonassociating mutant spectrin, while the child has inherited a nonassociating molecule from each parent. In each individual, the degree of mechanical stability of the erythrocyte membrane, determined by ektacytometry, was proportional to the amount of tetramer found in the membrane. The description of this case is consistent with either HPP or a form of homozygous HE which is asymptomatic in the carrier state.

Phosphorylation of glycophorin A in membranes of intact human erythrocytes

The qualitative and quantitative contribution of glycophorin A phosphorylation to the general and specific pattern of membrane protein phosphorylation in intact erythrocytes pre-incubated with 32Pi was examined. Intense 32P-labeled bands at 88,000 and 38,000 Mr were identified as phosphorylated glycophorin A dimer and monomer respectively on the basis of several criteria. Quantitatively, phosphorylated glycophorin A dimer accounted for about 70% of 32P in the band 3 region. This value is at least three times that previously reported. The results of ancillary experiments involving selective extraction of ghosts in acidified chloroform/methanol solvents and electrophoresis in the presence of detergents make it unlikely that the 32P associated with glycophorin A was due to bound polyphosphoinositides.

Membrane protein phosphorylation in the intact erythrocytes of genetically dystrophic hamsters

Membrane protein phosphorylation has been measured in both normal and dystrophic (BIO 53.58) hamsters. After radiolabeling intact erythrocytes with exogenous 32Pi, band 3 polypeptides from dystrophic hamsters had increased incorporation of 32P, compared to age-matched controls. This was verified by membrane protein fractionation. The use of intact cell phosphorylation avoids many of the sources of experimental variability noted in experiments with isolated membranes. This work, using an animal model for the disease, supports the hypothesis of a generalized membrane defect in the muscular dystrophies.

Abnormal membrane protein methylation and merocyanine 540 fluorescence in sickle erythrocyte membranes

Sickle cell erythrocytes exhibit reduced carboxyl methylation of membrane proteins compared to normal erythrocytes. This altered methylation in sickle membrane proteins is also observable when extracted membranes, both intact and alkali treated, were used as substrates for the homologous protein methylase II (S-adenosylmethionine:protein-carboxyl O-methyltransferase, EC. 2.1.1.24). However, when glycophorin A, one of the major methyl acceptors in both membranes, was extracted by lithium diiodosalicylate and used as the methyl acceptor, the proteins from both membranes were methylated equally, suggesting an involvement of membrane structure in membrane-bound protein methylation. Merocyanine 540 (MC-540), a fluorescent probe, was used to determine if the membranes differed in organization. Incubation of both normal and sickle erythrocytes membranes with MC-540 produced a marked increase in extrinsic fluorescence, reflecting a relatively nonpolar environment for the dye bound to the membranes. The fluorescence from sickle cell ghosts was only 87% as intense as that from normal ghosts, while the actual amount of MC-540 associated with sickle cell membranes was only 62% of normal. These data suggest that differences exist in the distribution of surface charges on these plasma membranes. These results are consistent with the hypothesis that abnormal levels of membrane protein methylation observed in sickle erythrocytes may be a result of abnormal membrane organization characteristic to sickle cell anemia.

Identification and function of transmembrane glycoproteins--the red cell model

Transmembrane glycoproteins in the red cell membrane traverse the plasma membrane, have their carbohydrate moieties on the extracellular surface, are sialyated (except for band 3) and are tethered to the membrane cytoskeleton proteins on the cytoplasmic surface. This linkage between the transmembrane proteins and the skeletal membrane proteins provides a two-way communication between the extracellular surface and the interior of the red cell; i.e., a transmembrane effect can be initiated from either side. These interactions are discussed in this review, including the example of sickle cell anemia in which the membrane bound hemoglobin may exert a transmembrane effect to change the conformation or distribution of transmembrane glycoproteins and and hence the extracellular surface receptors. This, in turn, may explain why sickle cells adhere to endothelium in vitro. Although the RBC transmembrane sialoglycoproteins may function in communication, regulation of cell shape, and adhesion, uncertainties exist regarding many of their functions. To study these sialoglycoproteins, we have developed a double staining technique (Dzandu et al., 1984) that differentially stains human RBC membrane sialoglycoproteins and asialoproteins in SDS-polyacrylamide gels. This should aid in elucidating the conformational structure and function of transmembrane glycoproteins.

Spin-label detection of sickle hemoglobin--membrane interaction at physiological pH

The spin-label electron paramagnetic resonance technique has been used to compare the interactions of normal and sickle hemoglobin molecules with human erythrocyte membranes. The sickle hemoglobin molecules show an enhanced binding to membranes when compared to normal hemoglobin (HbA) molecules. Using a simple equilibrium model for hemoglobin--membrane interactions, we obtain an equilibrium dissociation constant for sickle hemoglobin of about half that of HbA at pH 7.4 in 5 mM phosphate at 20 degrees C. The interactions are very low affinity in nature and are stronger at lower pH than at pH 7.4 (Fung, 1981a). The difference between normal and sickle hemoglobin persists at both high (pH 7.4) and low (pH 6.7) pH values. The concentrations of hemoglobin at the saturation level are close to physiological concentrations. Removal of spectrin--actin protein molecules from the membranes causes little change in the interactions, indicating that the remaining membrane proteins play the primary role in hemoglobin--membrane interactions. This observation is further supported by data of spectrin--actin-depleted inside-out vesicle samples. The stronger interaction of sickle hemoglobin than normal hemoglobin with membranes is discussed in relation to the formation of irreversibly sickled cells.

Calcium and ionophore A23187 induce the sickle cell membrane phosphorylation pattern in normal erythrocytes

Pre-treatment of normal erythrocytes with micromolar Ca2+ and ionophore A23187 induces abnormal phosphorylation of membrane polypeptides, as determined by labeling with exogenous 32Pi. The Ca2+ -induced effects, which include increased incorporation of 32P into acid-stable linkages and increased labeling in the Band 3 and 4.5-4.9 regions of SDS gels, are similar to those seen in untreated sickle erythrocytes. Part of the abnormal phosphorylation of sickle cells may be caused by their elevated intracellular Ca2+ levels.

Morphology and fatty acid composition of reticulocytes from phenylhydrazine-treated rats

Reticulocytosis was induced in rats by injecting phenylhydrazine, a potent oxidizing agent. Red cell morphology was analyzed by scanning electron microscopy. The majority of red cells from rats given injections of phenylhydrazine were types 2 and 3 echinocytes. Stomatocytes were also observed, but pitted lobular reticulocytes were not detected. Echinocytes have not previously been observed in reticulocyte populations. In the reticulocytes, the relative levels of 16:1 and 18:1 were significantly greater than in erythrocytes. These differences in monoenoic acids may be due to the presence of endoplasmic reticulum, the site of desaturase activity in reticulocytes. Of all the fatty acids, the polyunsaturates are the most susceptible to attack during peroxidation. However, the polyunsaturated fatty acid composition of reticulocytes was similar both to that of erythrocytes and to reported values of young erythrocytes isolated by density. Therefore, it is unlikely that lipid peroxidation caused the formation of echinocytes.

The molecular basis of the defect in phosphorylation of spectrin in human hereditary spherocytosis

The molecular basis for the depressed phosphorylation of the smaller polypeptide of spectrin (band 2) in the erythrocytes of patients suffering from hereditary spherocytosis is investigated. Comparison of healthy and spherocytic spectrin polypeptides by controlled proteolysis reveals no abnormality in the degradation pattern or in the sites of phosphorylation. It is concluded that the lesion is a consequence of a defective control of phosphorylation. The defect can be mimicked in healthy cells by the introduction of calcium into the erythrocyte and the possibility that the primary pathological lesion is a deficient control of the calcium content of the erythrocyte is discussed.

Protein kinase activity of human erythrocyte membranes in Friedreich's ataxia

Proteins of human erythrocyte membranes of Friedrich's ataxia patients and controls were examined by SDS-polyacrylamide gel electrophoresis before and after reduction with beta-mercaptoethanol. No difference could be detected in the composition of their state of aggregation. The protein kinase activity of human erythrocyte membranes of eleven Friedreich's ataxia patients and six controls was determined. No difference in their protein kinase activity could be detected. These results are discussed with respect to an involvement of a generalized membrane defect in Friedreich's ataxia.