Monoclonal antibodies to red cell cytoskeletal proteins

Monoclonal antibodies to human red cell cytoskeletal proteins were produced following immunization of mice with Triton shells produced from intact red cells. Two lines producing antibodies binding to spectrin and actin, respectively, were subcloned and further characterized. Clones producing the anti-spectrin antibody were stable. The antibody was monoclonal and specific for spectrin band 2. The anti-actin clones were unstable.     

Biogenesis of the red cell membrane and cytoskeletal proteins during erythropoiesis in vitro

Purified erythroid progenitor cells (CFU-E) were used to study in vitro the production of the proteins present in the plasma membrane and the membrane skeleton. At different stages of erythropoiesis incorporation of [35S]methionine was measured and membranes were isolated. Whereas incorporation in the total protein mass of the cells increased during erythropoiesis, the labeling of the membrane protein fraction decreased. The major erythrocyte membrane proteins were synthesized already in the CFU-E and continued to be made till the orthochromatic erythroblast stage. Band 3 protein, however, was made at a much lower rate. The incorporation in the late stages was only 5% of that in the CFU-E. The major changes in the protein composition of the membrane and its adherent skeleton occurred at the enucleation step.     

Hemin-promoted peroxidation of red cell cytoskeletal proteins

Hemin-induced crosslinking of the erythrocyte membrane proteins was analyzed at three levels: (i) whole membranes, (ii) integrated or dissociated cytoskeletons, and (iii) isolated forms of the three main cytoskeletal proteins, spectrin, actin, and protein 4.1. Addition of H2O2 and hemoglobin to resealed membranes from without did not affect any of the membrane proteins. Hemin that can transport across the membrane induced, in the presence of H2O2, crosslinking of protein 4.1 and spectrin. Both free hemin and hemoglobin added with H2O2 induced crosslinking of integer cytoskeletons and mixtures of isolated cytoskeletal proteins, but hemin was always more active. Of the three major cytoskeletal proteins, spectrin and protein 4.1 were most active while the participation of actin was only minor. The yield of crosslinked products was increased in all reaction mixtures with pH, with an apparent pK above 9.0. Replacement of H2O2 by phenylhydrazine and tert-butyl hydroperoxide resulted in crosslinking of the same proteins, but with lower activity than H2O2. Bityrosines, which were identified by their specific fluorescence emission characteristics, were formed in reaction mixtures containing hemin and hydrogen peroxide and either spectrin or protein 4.1, but not actin. On the basis of fact that bityrosines were revealed only in reaction mixtures that produced protein adducts, formation of intermolecular bityrosines was analyzed to be involved in crosslinking of the cytoskeletal proteins. Since the levels of membrane-intercalated hemin are correlated with aggregation of membrane proteins, it is suggested that the peroxidative properties of hemin are responsible for its toxicity.     

Alterations of red cell membrane proteins and hemoglobin under natural and experimental oxidant stress

We compared on red cell membrane proteins and hemoglobin (Hb) the effects of (i) natural oxidant stress that has been suggested to occur in a variety of oxidative hemolytic anemias, and (ii) experimental stress induced by hydrogen peroxide. SDS-polyacrylamide gel electrophoresis was used for protein analysis. Under natural conditions (thalassemias, hemoglobinopathies with Hb unstability), a high molecular weight polymer (HMWP) and variable amounts of globin mono- and dimers became apparent. Furthermore, a major 12 kDa polypeptide, its dimer, and conspicuous spectrin degradation products in the band 2.2–2.6 region occurred in a patient carrying the highly unstable Hb Hammersmith. Under experimental conditions, incubation of erythrocyte ghosts with H₂O₂ in the presence of minimal concentration (25 μM) of Hb generated a HMWP at the expense of membrane proteins, mainly spectrin. Incubation of a diluted (200 μM) membrane-free hemolysate with H₂O₂ induced a HMWP, an array of globin oligomers and a 12 kDa polypeptide similar to that mentionned above. Therefore, the damage to the red cell membrane present in various oxidative hemolytic anemias, including polypeptide polymerisation and breakdown, can be produced by experimental oxidant stress. These observations support the view that the alterations described in the patients result directly from oxidative reactions. However, we did not observe in the patient the sharp breakdown of polyunsaturated fatty acids that was triggered in vitro by H₂O₂ in the presence of Hb acting as a catalyst. In most cases, oligo- and polymers were resistant to β-mercaptoethanol, and the chemical nature of the underlying cross-links is discussed. To our knowledge, the 12 kDa polypeptide, that we consider as arising from globin proteolysis, has never been reported under pathological conditions.     

Progressive oxidation of cytoskeletal proteins and accumulation of denatured hemoglobin in stored red cells

Red blood cell (RBC) membrane proteins undergo progressive pathological alterations during storage. In conditions of increased cellular stress, the cytoskeleton also sustains certain modifications. The hemoglobin (Hb) content and oxidative status of the RBC cytoskeletons as a function of the storage period remain unclear. The possible Hb content and oxidative alterations occurring in the cytoskeletons in the course of storage were monitored in six units, by means of electrophoresis, immunoblotting and protein carbonylation assays. A proportion of the ghost-bound Hb consists of non-reducible crosslinkings of probably oxidized(denatured Hb or hemichromes.The defective Hb-membrane association was strongly affected by the prolonged storage. A progressive accumulation of Hb monomers, multimers and high molecular weight aggregates to corresponding cytoskeletons were also evident. The oxidative index of the cytoskeletal proteins was found increased, signalizing oxidative modifications in spectrin and possibly other cytoskeletal proteins. The reported data corroborate the evidence for oxidative damage in membrane proteins with emphasis to the cytoskeletal components. They partially address the pathophysiological mechanisms underlying the RBC storage lesion, add some new insight in the field of RBC storage as a hemoglobin- and cytoskeleton-associated pathology and suggest the possible use of antioxidants in the units intended for transfusion.     

Association of hemoglobin chains with the cell membrane as a cause of red cell distortion in thalassemia

Hemoglobin chains were separated and their interaction with membrane ghosts was studied using their ability to quench the fluorescence intensity of a membrane embedded probe. It was observed that alpha chains bind faster and with higher affinity to the membrane sites than do beta chains. The fast reversible interaction of both chains with the membrane was followed by a time-dependent partial loss of reversibility. Band 3 cytoplasmic fragments (B3F) were isolated and their reaction with separated Hb chains was studied using fluorescence quenching techniques as well. The data demonstrate that the relative affinity of the chains for B3F and loss of reversibility of the reaction followed patterns similar to the corresponding interaction of the chains with whole membranes. Band 3 cytoplasmic poles are therefore suggested as the high-affinity sites on the membrane for hemoglobin chains. When globin was reacted with B3F, it was observed that this protein binds strongly to the same membrane sites, but practically irreversibly. Exchange of the HbA content of normal cells by separated alpha or beta chains resulted in membrane distortions in both cases, but alpha chains caused greater morphological changes than did beta chains. The results of this study may provide one explanation for the differences in the thalassemia syndromes when excess of either alpha or beta chains is involved.     

Water-soluble proteins of the human red cell membrane

Summary Procedures were developed for preparation of red cell membranes almost free of hemoglobin but with minimal loss of membrane proteins. Two water-soluble protein fractions are described, each constituting about 25% of the ghost protein. The first is ionically bonded and can be solubilized in water rapidly at pH 7.0 and more slowly at higher ionic strength solutions, with a minimal rate at 20mm. This fraction contains four major components with molecular weights ranging from 30,000 to 48,000. The second fraction can only be solubilized at an appreciable rate if Ca⁺⁺ is absent and at higher pH (9.0). It is predominantly a single molecular weight component (150,000). It tends to aggregate at higher ionic strength and in the presence of Ca⁺⁺. Evidence is presented suggesting that the water-soluble proteins are present at the inner face of the membrane. The lipids remain in a water-insoluble residue that contains four major protein components ranging in molecular weight from 30,000 to 100,000. The latter is the predominant component. Only the residue contains the Na⁺–K⁺-activated ATPase, the cholinesterase, antigenic activity and most of the sialic acid and carbohydrate. The first water-soluble fraction contains a Mg⁺⁺-activated ATPase. The extraction of the water-soluble proteins is accompanied by anatomical changes resulting finally in the formation of small membranous vesicles.     

The binding of hemoglobin to red cell membrane lowers its oxygen affinity

The mode of interaction of human hemoglobin (Hb) with the red cell membrane was investigated with special reference to the effect on oxygen binding properties and Hb-membrane binding constants. Compared to free native Hb, the membrane-bound native Hb showed a strikingly lowered oxygen affinity and smaller response to organic phosphates such as 2,3-diphosphoglycerate and inositol hexaphosphate. Similar effects of membrane binding were also observed for intermediately cooperative Hbs such as N-ethylmaleimide-treated Hb (NES-Hb) and iodoacetamide-treated Hb (AA-Hb), but very small effects were observed for non-cooperative Hb, i.e., carboxypeptidase A-treated Hb (des-His-Tyr Hb). The magnitude of the affinity lowering was in the order: NES-Hb greater than native Hb greater than AA-Hb much greater than des-His-Tyr Hb. In the presence of inositol hexaphosphate, the three chemically modified Hbs showed an increased oxygen affinity when bound to the red cell membrane, probably due to partial replacement of bound inositol hexaphosphate by membrane. The binding to membrane caused a slight decrease in cooperativity for native Hb, but no distinct change in cooperativity was observed for the three modified Hbs. These results imply: a) the red cell membrane binds to deoxyHb more strongly than to oxyHb; b) the difference in membrane binding affinity between oxyHb and deoxyHb is closely related to the quaternary structure change in the Hb molecule occurring upon oxygenation. The higher affinity of the membrane for deoxyHb than for oxyHb apparently disagrees with the conclusion drawn by earlier investigators. However, the present binding experiments by means of ultrafiltration proved that the red cell membrane actually binds to deoxyHb much more strongly than to oxyHb, validating the present conclusion based on oxygenation experiments. Our results are consistent with those obtained recently by other investigators using a synthetic peptide or the cytoplasmic fragment of red cell membrane band 3.     

Crosslinking of membrane proteins in red blood cells from vitamin E-deficient lead-poisoned rats

Red blood cells from vitamin E-deficient rats lose their filterability after incubation in vitro and concurrent lead poisoning of the rats accelerates this decline. This decreased red cell filterability is associated with an increased crosslinking of red cell membrane proteins. Previous reports by others suggested an association between red cell glutathione levels and filterability, but we found no such association in red cells treated with N-ethylmaleimide. Increased aggregation of red cell membrane proteins may play a role in the discocyte/ spherocyte shape change that accounts for the impaired filterability of red blood cells from vitamin E-deficient lead-poisoned rats.     

Different susceptibility of red cell membrane proteins to calpain degradation.

The presence of low levels of calpastatin activity in erythrocytes of hypertensive rats affects regulation of calpain activity so it is highly susceptible to activation within physiological fluctuations in [Ca2+]. Under identical conditions, in red cells of normotensive rats, calpain activation is efficiently controlled by the high levels of calpastatin activity, and a progressive increase in proteinase activity can only be observed in parallel with a decrease in the level of calpastatin. In intact erythrocytes from hypertensive rats exposed to small variations in [Ca2+], degradation of anion transport protein (band 3) and Ca(2+)-ATPase appears as a primary event indicating that these two transmembrane proteins are probably early recognized as targets of intracellular calpain activity. Furthermore, band 3 protein seems to be structurally modified in erythrocytes from hypertensive rats, as indicated by its increased susceptibility to degradation in the presence of 10-50 microM Ca2+. In addition, when exposed to progressive and limited increases in [Ca2+], erythrocytes from hypertensive rats, but not those from normotensive rats, show a high degree of fragility that can be restored to normal values by inhibition of calpain. These results indicate that, within fluctuations in [Ca2+] close to physiological values, regulation of calpain activity is efficiently accomplished in normal erythrocytes but is completely lost in cells from hypertensive animals. Regulation is of critical importance in maintaining normal structural and functional properties of selective red cell membrane and cytoskeletal proteins, among which band 3 and Ca(2+)-ATPase appear to be the substrates with highest susceptibility to digestion by calpain.     

Cyclic loading on the red cell membrane in a shear flow: a possible cause of hemolysis

The fluid force acting on single human red cells in a high shear flow was analyzed. A two-dimensional elliptical microcapsule as a model of the deformed red cells was adopted to numerically calculate the distributions of the shear forces on both sides of the cell membrane. It is theoretically shown that the cell membrane undergoes an unsteady cyclic loading under the rotational motion around the interior. The mechanism leading to blood cell trauma is examined by repeatedly loading the continuously moving cell membrane.     

The interaction of lymphocyte membrane proteins with the lymphocyte cytoskeletal matrix

Lymphocyte membrane proteins are important in the transduction of signals across the plasma membrane. Visual and biophysical studies have shown that after ligand binding, membrane proteins may become immobile in the plane of the membrane and may cap. In intact cells, binding of cross-linking ligands to surface immunoglobulin converts it to a detergent-insoluble state (77% insoluble). This conversion is positively correlated with the transmission of a mitogenic signal. Class II histocompatibility proteins (Ia) and thy-1 remain predominantly detergent soluble (60 to 97% soluble). Insolubilized membrane proteins may be solubilized by incubating the detergent insoluble cytoskeletons with 0.34 M sucrose, 0.5 mM ATP, 0.5 mM dithiothreitol, 1 mM EDTA, or 3 X 10(-5) M DNAase I, 1 mM EDTA. To determine if the membrane-associated cytoskeleton contains the sufficient components for ligand-induced receptor insolubilization, experiments were done with a crude plasma membrane fraction. The results with whole cells or crude plasma membranes were comparable. These studies support the view that ligand-induced insolubilization of membrane proteins is due to their interaction with cytoskeletal structures.     

Marked changes in red cell membrane proteins in hereditary spherocytosis: a proteomics approach

Hereditary spherocytosis (HS) is the most common red cell membrane defect resulting from protein abnormalities. However, changes in red cell membrane proteins in HS remain under-investigated. We therefore evaluated red cell membrane proteome in non-splenectomized, mild-degree HS patients (n = 9) compared to healthy individuals (n = 5). Proteins derived from the red cell membranes of each subject were resolved in each two-dimensional gel and visualized by Deep Purple fluorescence staining. Spot matching and quantitative intensity analysis revealed 56 differentially expressed protein spots (41 increased and 15 decreased), which were then successfully identified by quadrupole time-of-flight mass spectrometry. Among these, seven isoforms/subunits of spectrin were markedly increased (up to 10.51 folds), whereas two isoforms/subunits of band-3 protein were decreased approximately 50% as compared to normal red cells. However, two isoforms/subunits of protein 4.1 were increased, while another isoform/subunit was decreased. All these significantly altered proteins were subjected to global protein network analysis using Ingenuity Pathways Analysis tool, which revealed three important networks related to HS, including Network I: Cell death, genetic and hematological disorders; Network II: Cell cycle, carbohydrate metabolism and molecular transport; and Network III: Genetic and hematological disorders, cell-to-cell signaling and interactions. These data offer many opportunities and new roadmaps for further functional studies to better understand the biology and pathogenic mechanisms of HS.     

Ultracentrifugal analysis of the junction complexes of the red cell membrane cytoskeletal network: application to hereditary spherocytosis and metabolically depleted cells

A method has been developed for the assessment of the number of spectrin dimer units associated with each actin protofilament junction, in the membrane cytoskeletal network (i.e. the degree of branching) of the red cell. Ghosts are first exposed to elevated temperature at low ionic strength to dissociate some 65% of the spectrin tetramers (that link the network junctions) into dimers, without causing their release from the actin filaments. Non-ionic detergent is then added to solubilize the membrane itself with its intrinsic proteins, so as to liberate the cytoskeletal material, and the mixture is immediately examined in the analytical ultracentrifuge. The predominant components observed are isolated junctions (20 S), free spectrin dimers and the residual undissociated cytoskeletal material, with very minor components, probably corresponding to multiple junctions, linked by spectrin tetramers. The junction boundary is homogeneous within the accuracy of measurement and is taken to correspond to a complex containing six spectrin dimers, known to predominate in situ. About 17% of the total network is liberated in this form and 12% as free spectrin dimers. In hereditary spherocytosis both the size of the junction complex (as reflected by its sedimentation coefficient) and the proportion of the complex and of free spectrin liberated are indistinguishable from normal values. We conclude that the reported deficit of spectrin in hereditary spherocytosis is not reflected by a lower degree of branching of the network, and, if the membrane area is not correspondingly reduced, this must mean that the junctions are more widely spaced and the spectrin tetramers therefore more extended. In metabolically depleted cells, in which the cytoskeletal proteins are known to be extensively dephosphorylated, there is no change in the sedimentation pattern and thus no detectable loss of spectrin from the junctions or weakening in the cohesion of the cytoskeletal network.