Regulation of protein 4.1R, p55, and glycophorin C ternary complex in human erythrocyte membrane

Three binary protein-protein interactions, glycophorin C (GPC)-4.1R, GPC-p55, and p55-4.1R, constitute the GPC-4.1R-p55 ternary complex in the erythrocyte membrane. Little is known regarding the molecular basis for the interaction of 4.1R with either GPC or p55 and regarding the role of 4.1R in regulating the various protein-protein interactions that constitute the GPC-4.1R-p55 ternary complex. In the present study, we present evidence that sequences in the 30-kDa domain encoded by exon 8 and exon 10 of 4.1R constitute the binding interfaces for GPC and p55, respectively. We further show that 4.1R increases the affinity of p55 binding to GPC by an order of magnitude, implying that 4.1R modulates the interaction between p55 and GPC. Finally, we document that binding of calmodulin to 4.1R decreases the affinity of 4.1R interactions with both p55 and GPC in a Ca(2+)-dependent manner, implying that the GPC-4.1R-p55 ternary protein complex can undergo dynamic regulation in the erythrocyte membrane. Taken together, these findings have enabled us to identify an important role for 4.1R in regulating the GPC-4.1R-p55 ternary complex in the erythrocyte membrane.     

Increased methyl esterification of altered aspartyl residues in erythrocyte membrane proteins in response to oxidative stress.

Protein-L-isoaspartate (D-aspartate) O-methyltransferase (PCMT; EC 2. 1.1.77) catalyses the methyl esterification of the free alpha-carboxyl group of abnormal L-isoaspartyl residues, which occur spontaneously in protein and peptide substrates as a consequence of molecular ageing. The biological function of this transmethylation reaction is related to the repair or degradation of age-damaged proteins. Methyl ester formation in erythrocyte membrane proteins has also been used as a marker reaction to tag these abnormal residues and to monitor their increase associated with erythrocyte ageing diseases, such as hereditary spherocytosis, or cell stress (thermal or osmotic) conditions. The study shows that levels of L-isoaspartyl residues rise in membrane proteins of human erythrocytes exposed to oxidative stress, induced by t-butyl hydroperoxide or H2O2. The increase in malondialdehyde content confirmed that the cell membrane is a primary target of oxidative alterations. A parallel rise in the methaemoglobin content indicates that proteins are heavily affected by the molecular alterations induced by oxidative treatments in erythrocytes. Antioxidants largely prevented the increase in membrane protein methylation, underscoring the specificity of the effect. Conversely, we found that PCMT activity, consistent with its repair function, remained remarkably stable under oxidative conditions, while damaged membrane protein substrates increased significantly. The latter include ankyrin, band 4.1 and 4.2, and the integral membrane protein band 3 (the anion exchanger). The main target was found to be particularly protein 4.1, a crucial element in the maintenance of membrane-cytoskeleton network stability. We conclude that the increased formation/exposure of L-isoaspartyl residues is one of the major structural alterations occurring in erythrocyte membrane proteins as a result of an oxidative stress event. In the light of these and previous findings, the occurrence of isoaspartyl sites in membrane proteins as a key event in erythrocyte spleen conditioning and hemocatheresis is proposed.     

Purification of erythrocyte protein 4.1 by selective interaction with inositol hexaphosphate.

Protein 4.1 is a multifunctional structural protein occupying a strategic position in the erythrocyte membrane. It is present in the erythrocyte membrane skeleton and in many nonerythroid cells. This report describes a novel method for purifying this protein based on its selective interaction with inositol hexaphosphate dimagnesium tetrapotassium salt. This interaction was discovered in the course of chromatography of high-salt extract of inside-out membrane vesicles on Procion orange MX-2R-Sepharose. The new procedure is simple and selective and produces protein 4.1 with better yield than that obtained with a previously published procedure. The purified protein 4.1 has the same immunoreactivity and the same alpha-chymotryptic digest profile as protein 4.1 purified by published methods and is fully functional in enhancing the interaction between F-actin and spectrin dimers.     

An analogue of the erythroid membrane skeletal protein 4.1 in nonerythroid cells

Protein 4.1 is a crucial component of the erythrocyte membrane skeleton. Responsible for the amplification of the spectrin-actin interaction, its presence is required for the maintenance of erythrocyte integrity. We have demonstrated a 4.1-like protein in nonerythroid cells. An antibody was raised to erythrocyte protein 4.1 purified by KCl extraction (Tyler, J. M., W. R. Hargreaves, and D. Branton, 1979, Proc. Natl. Acad. Sci. USA, 76:5192-5196), and used to identify a serologically cross-reactive protein in polymorphonuclear leukocytes, platelets, and lymphoid cells. The cross-reactive protein(s) were localized to various regions of the cells by immunofluorescence microscopy. Quantitative adsorption studies indicated that at least 30-60% of the anti-4.1 antibodies reacted with this protein, demonstrating significant homology between the erythroid and nonerythroid species. A homologous peptide doublet was observed on immunopeptide maps, although there was not complete identity between the two proteins. When compared with erythrocyte protein 4.1, the nonerythroid protein(s) displayed a lower molecular weight--68,000 as compared with 78,000-and did not bind spectrin or the nonerythroid actin-binding protein filamin. There was no detectable cross-reactivity between human acumentin or human tropomyosin-binding protein, which are similarly sized actin-associated proteins, and erythrocyte protein 4.1. The possible origin and significance of 4.1-related protein(s) in nonerythroid cells are discussed.     

Regulation of the glycophorin C-protein 4.1 membrane-to-skeleton bridge and evaluation of its contribution to erythrocyte membrane stability

The band 3-ankyrin-spectrin bridge and the glycophorin C-protein 4.1-spectrin/actin bridge constitute the two major tethers between the erythrocyte membrane and its spectrin skeleton. Although a structural requirement for the band 3-ankyrin bridge is well established, the contribution of the glycophorin C-protein 4.1 bridge to red cell function remains to be defined. In order to explore this latter bridge further, we have identified and/or characterized five stimuli that sever the linkage in intact erythrocytes and have examined the impact of this rupture on membrane mechanical properties. We report here that elevation of cytosolic 2,3-bisphosphoglycerate, an increase in intracellular Ca(2+), removal of cell O(2), a decrease in intracellular pH, and activation of erythrocyte protein kinase C all promote dissociation of protein 4.1 from glycophorin C, leading to reduced retention of glycophorin C in detergent-extracted spectrin/actin skeletons. Significantly, where mechanical studies could be performed, we also observe that rupture of the membrane-to-skeleton bridge has little or no impact on the mechanical properties of the cell, as assayed by ektacytometry and nickel mesh filtration. We, therefore, suggest that, although regulation of the glycophorin C-protein 4.1-spectrin/actin bridge likely occurs physiologically, the role of the tether and the associated regulatory changes remain to be established.     

Correlation between protein 4.1a/4.1b ratio and erythrocyte life span

Erythrocyte membranes from various healthy mammals contained a doublet of protein 4.1a and 4.1b, which appeared to differ by 2-3 kDa on sodium dodecyl sulfate polyacrylamide gel electrophoresis. The ratio of protein 4.1a/4.1b showed much variety among animal species, and the 4.1a/4.1b ratio correlated to the mean erythrocyte life span, that is, the mean cell age in circulating blood. We also found that the 4.1b is the predominant form in the immature erythroid cells such as reticulocytes and K562 cells. In addition, the 4.1b but not 4.1a protein was metabolically labeled with [35S]methionine in the erythropoietic cells from anemic mouse. Immunological detection showed that there is a doublet of minor variants of protein 4.1 with apparent molecular masses slightly more than those of 4.1a and 4.1b. The ratio of these minor isoforms designated as 4.1a + and 4.1b + revealed the alteration during erythrocyte senescence as observed in 4.1a/4.1b ratio. These results show that protein 4.1 may be synthesized as 4.1b and 4.1b + and intercalated into membrane skeletons at an early stage of erythroidal differentiation, and that the posttranslational modification into 4.1a and 4.1a + appears to occur by a common mechanism in many mammalian species. Feline erythrocytes, however, appeared to lack such a postsynthetic processing of protein 4.1, and exhibited one major component of 4.1b with the other minor variant of 4.1b +.     

Hemin-mediated dissociation of erythrocyte membrane skeletal proteins

Spectrin tetramers and oligomers in normal erythrocytes are cross-linked by actin and protein 4.1 to form a two-dimensional membrane skeletal network. In the present study, we find that hemin, a breakdown product of hemoglobin, progressively (a) alters the conformation of spectrin as revealed by electron microscope studies and by the decreased resistance of spectrin to proteolytic degradation, (b) alters the conformation of protein 4.1 as revealed by the increased mobility of protein 4.1 on nondenaturing gel electrophoresis, (c) weakens spectrin dimer alpha beta-dimer alpha beta, spectrin alpha-spectrin beta, as well as spectrin-protein 4.1 associations as analyzed by nondenaturing gel electrophoresis, and (d) diminishes the structural stability of erythrocyte membrane skeletons (i.e. Triton-insoluble ghost residues) subjected to mechanical shearing. Since hemin may be liberated from oxidized or unstable mutant hemoglobin under pathological conditions, these hemin-induced effects on spectrin, protein 4.1, and membrane skeletal stability may play a role in the membrane lesion of these erythrocytes.     

The effect of mild diamide oxidation on the structure and function of human erythrocyte spectrin

Oxidants can alter erythrocyte membrane properties and cause ultimate hemolysis, but the mechanisms responsible for these changes are not understood. A protein skeleton preserves the normal integrity of the erythrocyte membrane. In this study, we investigated the effects of limited chemical oxidation on the structure and function of the major skeletal protein, spectrin. After mild treatment of spectrin with 2.5 microM diamide, with formation of an average of only one disulfide bond, we observed a 50% reduction in the ability of protein 4.1 to amplify spectrin-actin binding. The oxidized spectrin specifically lacked the ability to bind protein 4.1, whereas all other spectrin functions remained intact. However, oxidation also produced a structural change in spectrin. A rapidly migrating species appeared on non-denaturing gels in a dose-dependent manner with increasing diamide concentrations. By electron microscopy, the oxidized spectrin appeared as single-stranded signet rings with irregular knob-like protrusions. Fifty per cent of spectrin was converted to the ring form after the formation of an average of two disulfide bonds. Both the structural and functional defects were reversed by chemical reduction. The loss of spectrin function or the structural transformation in spectrin may contribute to erythrocyte membrane failure in the oxidative environment.     

Immunological detection of an analogue of the erythroid protein 4.1 in endothelial cells

Endothelial cells (EC) of arterial and venous origin were investigated by indirect immunofluorescence and immunoautoradiography for the presence of red cell membrane 4.1-like protein. By immunofluorescence, EC exhibited a relatively uniform fluorescent staining sometimes of a reticular pattern, distributed over the entire cell. All controls were negative. Immunoblot analysis of EC revealed a cross reactive band of a molecular weight comparable to that of the erythrocyte band 4.1. These findings indicate that endothelial cells of arterial and venous origin express a polypeptide immunologically related to the erythrocyte protein 4.1, which may play an important role in membrane-cytoskeleton interactions.     

A dynamical study on the interactions between the cytoskeleton components in the human erythrocyte as detected by saturation transfer electron paramagnetic resonance of spin-labeled spectrin, ankyrin, and protein 4.1

Isolated human erythrocyte spectrin, ankyrin, and protein 4.1 have been labeled with the maleimide spin label, 3-maleimido-2,2,5,5-tetramethyl-1-pyrrolidinyloxyl, and studied by saturation transfer electron paramagnetic resonance spectroscopy. The presence of the labels does not affect the reassociation of these proteins with erythrocyte membranes selectively depleted of either spectrin-actin or of all the extrinsic proteins. When maleimide spin-labeled spectrin is reassociated with the erythrocyte membrane in presence of all the cytoskeleton components, including endogeneous or purified muscle actin, spectrin still preserves its flexible character. The rotational mobilities of maleimide spin-labeled ankyrin and maleimide spin-labeled protein 4.1 are of the same order of magnitude (tau c (L"/L) approximately 5 X 10(-5) and 8 X 10(-5) s, respectively, at 2 degrees C), while protein 4.1 is almost three times smaller in size than ankyrin. This result indicates that the movements of membrane-bound maleimide spin-labeled protein 4.1 are more restricted than those of ankyrin. This suggests that their respective binding sites have different structural properties. The rotational movements of both proteins are slowed down on the addition of spectrin indicating that protein 4.1 as well as ankyrin also represents one of the links of the cytoskeleton to the membrane.     

Ca(2+)-dependent and Ca(2+)-independent calmodulin binding sites in erythrocyte protein 4.1. Implications for regulation of protein 4.1 interactions with transmembrane proteins

In vitro protein binding assays identified two distinct calmodulin (CaM) binding sites within the NH(2)-terminal 30-kDa domain of erythrocyte protein 4.1 (4.1R): a Ca(2+)-independent binding site (A(264)KKLWKVCVEHHTFFRL) and a Ca(2+)-dependent binding site (A(181)KKLSMYGVDLHKAKDL). Synthetic peptides corresponding to these sequences bound CaM in vitro; conversely, deletion of these peptides from a 30-kDa construct reduced binding to CaM. Thus, 4.1R is a unique CaM-binding protein in that it has distinct Ca(2+)-dependent and Ca(2+)-independent high affinity CaM binding sites. CaM bound to 4.1R at a stoichiometry of 1:1 both in the presence and absence of Ca(2+), implying that one CaM molecule binds to two distinct sites in the same molecule of 4.1R. Interactions of 4.1R with membrane proteins such as band 3 is regulated by Ca(2+) and CaM. While the intrinsic affinity of the 30-kDa domain for the cytoplasmic tail of erythrocyte membrane band 3 was not altered by elimination of one or both CaM binding sites, the ability of Ca(2+)/CaM to down-regulate 4. 1R-band 3 interaction was abrogated by such deletions. Thus, regulation of protein 4.1 binding to membrane proteins by Ca(2+) and CaM requires binding of CaM to both Ca(2+)-independent and Ca(2+)-dependent sites in protein 4.1.     

Alteration Young’s moduli by protein 4.1 phosphorylation play a potential role in the deformability development of vertebrate erythrocytes

The mechanical properties of vertebrate erythrocytes depend on their cytoskeletal protein networks. Membrane skeleton proteins spectrin and protein 4.1 (4.1R) cross-link with actin to maintain membrane stability under mechanical stress. Phosphorylation of 4.1R alters the affinity of 4.1R for spectrin–actin binding and this modulates the mechanical properties of human erythrocytes. In this study, phorbol 12-myristate-13-acetate (PMA)-induced phosphorylation of 4.1R was tested, erythrocyte deformability was determined and the erythrocyte elastic modulus was detected in human, chick, frog and fish. Furthermore, amino acid sequences of the functionally important domains of 4.1R were analyzed. Results showed that PMA-induced phosphorylation of 4.1R decreased erythrocyte deformability and this property was stable after 1 h. The values of Young’s modulus alteration gradually decreased from human to fish (0.388±0.035 kPa, 0.219±0.022 kPa, 0.191±0.036 kPa and 0.141±0.007 kPa). Ser-312 and Ser-331 are located within the consensus sequence recognized by protein kinase C (PKC); however, Ser-331 in zebrafish was replaced by Ala-331. The sequence of the 8 aa motif from vertebrate 4.1R showed only one amino acid mutation in frog and numerous substitutions in fish. Analyses of Young’s modulus suggested that the interaction between 4.1R with the spectrin–actin binding domain may have a special relationship with the development of erythrocyte deformability. In addition, amino acid mutations in 4.1R further supported this relationship. Thus, we hypothesize that alteration of membrane skeleton protein binding affinity may play a potential role in the development of erythrocyte deformability, and alteration of Young’s modulus values may provide a method for determining the deformability development of vertebrate erythrocytes.     

Isolation of cDNA clones for human erythrocyte membrane sialoglycoproteins alpha and delta.

We have isolated almost full-length cDNA clones corresponding to human erythrocyte membrane sialoglycoproteins alpha (glycophorin A) and delta (glycophorin B). The predicted amino acid sequence of delta differs at two amino acid residues from the sequence determined by peptide sequencing. The sialoglycoprotein delta clone we have isolated contains an interrupting sequence within the region that gives rise to the cleaved N-terminal leader sequence for the protein and represents a product that is unlikely to be inserted into the erythrocyte membrane. Comparison of the cDNA sequences of alpha and delta shows very strong homology at the DNA level within the coding regions. The two mRNA sequences are closely related and differ by a number of clearly defined insertions and deletions.     

High molecular weight microtubule-associated proteins from pig brain are immunologically related to human erythrocyte membrane proteins spectrin, ankyrin, proteins 4.1 and 4.2

The microtubule-associated proteins MAPs 1 and 2 from pig brain have been found to react with antibodies directed against human ankyrin and spectrin, respectively (Bennett and Davis, 1981; Davis and Bennett, 1982). In a complementary approach we have prepared antibodies against MAP1 alpha. MAP1 gamma and MAP2 purified from pig brain and tested their reactivity with human erythrocyte membrane proteins. Anti-MAP1 alpha was shown to react with alpha and beta-spectrin and with protein 4.1; anti-MAP1 gamma reacted with alpha-spectrin and ankyrin and with a 60 K peptide which copurified with human spectrin. Finally anti-MAP2 was specific for beta-spectrin and protein 4.2. The biological function of protein 4.2 is still unknown but details on the interactions between ankyrin, spectrin and protein 4.1 and their role in mediating the linkage of oligomeric actin on the erythrocyte membrane are well documented. The present results, which demonstrate extended immunological analogies between pig brain high molecular weight MAPs and human erythrocyte membrane proteins, may reflect the presence, in the two families of proteins, of similar functionally important epitopes.     

Protein 4.1N is required for the formation of the lateral membrane domain in human bronchial epithelial cells

The membrane skeleton forms a scaffold on the cytoplasmic side of the plasma membrane. The erythrocyte membrane represents an archetype of such structural organization. It has been documented that a similar membrane skeleton also exits in the Golgi complex. It has been previously shown that βII spectrin and ankyrin G are localized at the lateral membrane of human bronchial epithelial cells. Here we show that protein 4.1N is also located at the lateral membrane where it associates E-cadherin, β-catenin and βII spectrin. Importantly, depletion of 4.1N by RNAi in human bronchial epithelial cells resulted in decreased height of lateral membrane, which was reversed following re-expression of mouse 4.1N. Furthermore, although the initial phase of lateral membrane biogenesis proceeded normally in 4.1N-depleted cells, the final height of the lateral membrane of 4.1N-depleted cells was shorter compared to that of control cells. Our findings together with previous findings imply that 4.1N, βII spectrin and ankyrin G are structural components of the lateral membrane skeleton and that this skeleton plays an essential role in the assembly of a fully functional lateral membrane.     

The isolation and functional identification of a protein from the human erythrocyte `ghost''

A protein, initially identified as a band on polyacrylamide-gel electrophoresis of erythrocyte ;ghosts', was isolated by selective extraction of ;ghosts' with EDTA solutions. The molecular weight of the polypeptide chain was estimated as 33000 and it represents approx. 5% of the membrane protein. The N-terminal sequence of the protein was established. Comparison with known protein sequences suggested that the protein might be the erythrocyte d-glyceraldehyde 3-phosphate dehydrogenase. This identification was confirmed by direct enzyme assay. It is suggested that this enzyme, which is strongly retained by erythrocyte ;ghosts' on haemolysis of erythrocytes, is unlikely to be an integral part of the structure of the erythrocyte membrane.     

The oligomeric state of spectrin in the rat erythrocyte membrane skeleton

The oligomeric state of spectrin in the erythrocyte membrane skeleton of the rat was investigated following extraction in a low ionic strength buffer for 24 and 96 h. All analyses were quantitatively compared with preparations from human erythrocyte membranes. After nondenaturing agarose-polyacrylamide gel electrophoresis, the human samples revealed their characteristic spectrin oligomer pattern; there were high molecular weight complexes near the origin of the gel, followed by several high order oligomers, tetramers, and dimers. The pattern in the rat membrane skeleton also included tetramers and a high molecular weight complex band, but had only one oligomer and no dimers. With time the high molecular weight complex diminished and oligomers accumulated in both the rat and human, while dimers accumulated only in the human and tetramers accumulated only in the rat. Tetramers decreased with time in the human. Extraction of spectrin increased with time and was greater from rat than the human red cell membrane at both time points. The percentage of spectrin and actin in the low ionic strength extract was similar between species, as analyzed by SDS-polyacrylamide electrophoresis, staining, and densitometry. Proteins 4.1 and 4.9 were present in greater percentages in the human. The only temporal effect on monomeric protein composition was an increase of protein A in the rat. There was no species difference in protein A percentage at 24 h, but at 96 h the rat was greater than the human. The results suggest that there are significant differences in the structural arrangement of the rat and human erythrocyte membrane skeleton.     

Interaction of biological membranes with the cytoskeletal framework of living cells

The review is focused on the molecular structure and function of the proteins composing the actin-based cytokeletal cortex, located at the cytoplasmic face of plasma membranes of eucaryotic cells, which stabilizes integral membrane proteins in separate domains of cell membranes. It includes a survey of the molecular properties of teh proteins of the erythrocyte membrane skeleton such as spectrin, ankyrin, protein 4.1, and adducin. The properties of the immunological counterparts of erythroid cortical proteins found in nonerythroid tissues and cells are compared. The structural organization and function of the newly discovered class of calcium-binding proteins, nonerythroid peripheral membrane proteins, calpactins, are also described. Finally, the discussion of some experimental models illustrates that the membrane skeleton of living cells is actively involved in a wide variety of essential biological functions ranging from differentiation, to maintenance of cell polarity and cell shape, and regulation of exocytotic processes.     

Membrane skeletal protein 4.1 of avian erythrocytes is composed of multiple variants that exhibit tissue-specific expression

The avian analog of mammalian erythrocyte protein 4.1, a structural component of the membrane skeleton, has been identified. It is present at the plasma membranes of avian erythrocytes and lens cells, but has not been found elsewhere in comparable amounts. In chickens, it exists as six variants with molecular masses of 87, 100, 115, 150, 160, and 175 kd. The corresponding polypeptides in turkeys are each about 3 kd smaller, suggesting that all may be encoded by a single gene. These variants have similar solubility properties and nearly identical two-dimensional iodopeptide maps that are similar to those of mammalian protein 4.1, but they are differentially phosphorylated. The three smallest variants are the predominant forms in avian erythrocytes, while the two largest variants predominate in avian lens cells. In contrast, mammalian erythrocytes and lens cells exhibit patterns of variants that are more similar to each other. These results show that only a subset of spectrin-containing cells possess protein 4.1, and that these cells differentially express the variants of protein 4.1 in a manner that may reflect corresponding functional differences.