Associations of human erythrocyte band 4.2. Binding to ankyrin and to the cytoplasmic domain of band 3

We have examined the associations of purified red cell band 4.2 with red cell membrane and membrane skeletal proteins using in vitro binding assays. Band 4.2 bound to the purified cytoplasmic domain of band 3 with a Kd between 2 and 8 X 10(-7) M. Binding was saturable and slow, requiring 2-4 h to reach equilibrium. This finding confirms previous work suggesting that the principal membrane-binding site for band 4.2 lies within the 43-kDa cytoplasmic domain of band 3 (Korsgren, C., and Cohen, C. M. (1986) J. Biol. Chem. 261, 5536-5543). Band 4.2 also bound to purified ankyrin in solution with a Kd between 1 and 3.5 X 10(-7) M. As with the cytoplasmic domain of band 3, binding was saturable and required 4-5 h to reach equilibrium. Reconstitution with ankyrin of inside-out vesicles stripped of all peripheral proteins had no effect upon band 4.2 binding to membranes; similarly, reconstitution with band 4.2 had no effect upon ankyrin binding. This shows that ankyrin and band 4.2 bind to distinct loci within the 43-kDa band 3 cytoplasmic domain. Coincubation of ankyrin and band 4.2 in solution partially blocked the binding of both proteins to the membrane. Similarly, coincubation of bands 4.1 and 4.2 in solution partially blocked binding of both to membranes. In all cases, the data suggest the possibility that domains on each of these proteins responsible for low affinity membrane binding are principally affected. The data also provide evidence for an association of band 4.2 with band 4.1. Our results show that band 4.2 can form multiple associations with red cell membrane proteins and may therefore play an as yet unrecognized structural role on the membrane.     

Integral protein linkage and the bilayer-skeletal separation energy in red blood cells

Stabilization of the lipid bilayer membrane in red blood cells by its association with an underlying membrane-associated cytoskeleton has long been recognized as critical for proper red blood cell function. One of the principal connections between skeleton and bilayer is via linkages between band 3, the integral membrane protein that transports anions across the cell surface, and membrane skeletal elements including ankyrin, adducin, spectrin, and the junctional complex of the skeleton. Here, we use membrane tether formation coupled with fluorescent labeling of membrane components to examine the importance of band 3 in stabilizing the bilayer-skeletal association. In membranes from a patient deficient in band 3, the energy associated with the bilayer skeleton is approximately zero, whereas when band 3 is immobilized by ligation with the monoclonal antibody R10, the energy of association approximately doubles. Fluorescence images of tethers reveal that ∼40% of the band 3 on the normal cell surface can be pulled into the tether, confirming a lateral segregation of membrane components during tether formation. These results validate a critical role for band 3 in stabilizing the bilayer-skeletal association in red cells.     

Expression, purification, and characterization of the functional dimeric cytoplasmic domain of human erythrocyte band 3 in Escherichia coli.

The cytoplasmic domain of the human erythrocyte membrane protein, band 3 (cdb3), contains binding sites for hemoglobin, several glycolytic enzymes, band 4.1, band 4.2, and ankyrin, and constitutes the major linkage between the membrane skeleton and the membrane. Although erythrocyte cdb3 has been partially purified from proteolyzed red blood cells, further separation of the water-soluble 43-kDa and 41-kDa proteolytic fragments has never been achieved. In order to obtain pure cdb3 for crystallization and site-directed mutagenesis studies, we constructed an expression plasmid that has a tandemly linked T7 promoter placed upstream of the N-terminal 379 amino acids of the erythrocyte band 3 gene. Comparison of several Escherichia coli strains led to the selection of the BL21 (DE3) strain containing the pLysS plasmid as the best host for efficient production of cdb3. About 10 mg of recombinant cdb3 can be easily purified from 4 L of E. coli culture in two simple steps. Comparison of cdb3 released from the red blood cell by proteolysis with recombinant cdb3 reveals that both have the same N-terminal sequence, secondary structure, and pH-dependent conformational change. The purified recombinant cdb3 is also a soluble stable dimer with the same Stokes radius as erythrocyte cdb3. The affinities of the two forms of cdb3 for ankyrin are essentially identical; however, recombinant cdb3 with its unblocked N-terminus exhibits a slightly lower affinity for aldolase.     

Plasmodium falciparum histidine-rich protein 1 associates with the band 3 binding domain of ankyrin in the infected red cell membrane

Infection of erythrocytes by the malaria parasite Plasmodium falciparum results in the export of several parasite proteins into the erythrocyte cytoplasm. Changes occur in the infected erythrocyte due to altered phosphorylation of proteins and to novel interactions between host and parasite proteins, particularly at the membrane skeleton. In erythrocytes, the spectrin based red cell membrane skeleton is linked to the erythrocyte plasma membrane through interactions of ankyrin with spectrin and band 3. Here we report an association between the P. falciparum histidine-rich protein (PfHRP1) and phosphorylated proteolytic fragments of red cell ankyrin. Immunochemical, biochemical and biophysical studies indicate that the 89 kDa band 3 binding domain and the 62 kDa spectrin-binding domain of ankyrin are co-precipitated by mAb 89 against PfHRP1, and that native and recombinant ankyrin fragments bind to the 5' repeat region of PfHRP1. PfHRP1 is responsible for anchoring the parasite cytoadherence ligand to the erythrocyte membrane skeleton, and this additional interaction with ankyrin would strengthen the ability of PfEMP1 to resist shear stress.     

Ankyrin is necessary for both drug-induced and ATP-induced shape change of human erythrocyte ghosts

Human erythrocyte membranes from ACD preseved blood were digested with trypsin (Protein: trypsin=100:1) and analyzed by SDS PAGE. After digestion for 20 sec at 0°C, only ankyrin disappeared but other bands including spectrin, band 4.1 and band 3 remained intact. In contrast to intact membranes, treatment with chlorpromazine or MgATP or HEPES did not induce shape change in these membranes. The number of transformable cells correlated closely with the amount of remaining ankyrin. We conclude that ankyrin is necessary for their shape change. This is the first direct evidence that ankyrin is involved in the maintenance of red cell shape. Three additional lines of indirect evidence are also presented.     

Interaction of thiourea with band 3 in human red cell membranes

Summary Although urea transport across the human red cell membrane has been studied extensively, there is disagreement as to whether urea and water permeate the red cell by the same channel. We have suggested that the red cell anion transport protein, band 3, is responsible for both water and urea transport. Thiourea inhibits urea transport and also modulates the normal inhibition of water transport produced by the sulfhydryl reagent,pCMBS. In view of these interactions, we have looked for independent evidence of interaction between thiourea and band 3. Since the fluorescent stilbene anion transport inhibitor, DBDS, increases its fluorescence by two orders of magnitude when bound to band 3 we have used this fluorescence enhancement to study thiourea/band 3 interactions. Our experiments have shown that there is a thiourea binding site on band 3 and we have determined the kinetic and equilibrium constants describing this interaction. Furthermore,pCMBS has been found to modulate the thiourea/band 3 interaction and we have determined the kinetic and equilibrium constants of the interaction in the presence ofpCMBS. These experiments indicate that there is an operational complex which transmits conformational signals among the thiourea,pCMBS and DBDS sites. This finding is consistent with the view that a single protein or protein complex is responsible for all the red cell transport functions in which urea is involved.     

红细胞膜带4.2蛋白的结构与功能

带4.2蛋白是一种重要的红细胞膜蛋白,与红细胞的形态、可变形性及携氧功能有至关重要的联系。它通过与带3蛋白(阴离子通道蛋白)、锚蛋白结合,稳定的连接在细胞膜的内表面,连接着膜骨架网架结构与细胞膜,是膜骨架与脂质双分子层连接的重要纽带。带4.2蛋白的缺失会引起球形或椭圆形红细胞增多症及不同程度的溶血性贫血,严重的情况需要摘除脾脏来进行治疗。近年来研究认为,带4.2蛋白在维持细胞膜骨架的完整性和稳定性方面扮演了重要角色。现对带4.2蛋白结构及功能的研究状况进行综述。     

Purification and properties of human erythrocyte band 4.2. Association with the cytoplasmic domain of band 3

We have purified the human erythrocyte membrane protein band 4.2 to greater than 85% homogeneity. The protein was extracted from spectrin-actin-depleted inside-out vesicles in a pH 11 medium and purified by gel filtration in the presence of 1 M KI. The purified protein was heterogeneous and had an average S20,w of 5.5 and an average Stokes radius of 82 A. By electron microscopy, the protein appeared heterogeneous in size and shape, having a diameter ranging from 80 to 150 A. The protein bound saturably to band 4.2-depleted red cell inside-out vesicles, and the binding exhibited a concave Scatchard plot. Binding was reduced greater than 90% by proteolytic digestion of membranes. Digestion studies suggested that there are two classes of binding sites for band 4.2 on the cytoplasmic aspect of red cell membranes, one of which is likely to be band 3. The purified 43-kDa cytoplasmic domain of band 3 competed for band 4.2 binding to red cell membranes and could completely abolish binding when added at a concentration of greater than 200 micrograms/ml. The purification of band 4.2 and the characterization of its association with red cell membranes should facilitate the discovery of the function of this major red cell membrane protein.     

Both ankyrin and band 4.1 are required to restrict the rotational mobility of band 3 in the human erythrocyte membrane.

A population of band 3 proteins in the human erythrocyte membrane is known to have restricted rotational mobility due to interaction with cytoskeletal proteins. We have further investigated the cause of this restriction by measuring the effects on band 3 rotational mobility of rebinding ankyrin and band 4.1 to ghosts stripped of these proteins as well as spectrin and actin. Rebinding either ankyrin or 4.1 alone has no detectable effect on band 3 mobility. Rebinding both these proteins together does, however, reimpose a restriction on band 3 rotation. The effect on band 3 rotational mobility of rebinding ankyrin and 4.1 are similar irrespective of whether or not band 4.2 is removed from the membrane. We suggest that ankyrin and 4.1 together promote the formation of slowly rotating clusters of band 3.     

Localization of the ankyrin-binding site on erythrocyte membrane protein, band 3

The predominant attachment site of the spectrin-based cytoskeleton to the erythrocyte membrane occurs via the interaction of ankyrin with the cytoplasmic domain of band 3 (cdb3). In order to further characterize this interaction, we have conducted experiments to localize the ankyrin-binding site on cdb3. Four monoclonal and three antipeptide polyclonal antibodies were raised against cdb3 and used in competition studies to identify regions of close association of cdb3 with ankyrin. Antibodies to regions of cdb3 near the cytoplasmic domain-membrane spanning domain junction had no effect on 125I-ankyrin binding. Likewise, an antibody to a highly conserved region between residues 142 and 154 did not inhibit ankyrin binding. However, antibodies at or near the cysteine 201-317 cluster and the proposed proline-rich hinge in the center of cdb3 were potent inhibitors of ankyrin association, as were antibodies to the acidic NH2 terminus. Additional evidence for interaction of ankyrin with the NH2-terminal region of cdb3 was obtained by demonstrating the ability of ankyrin to inhibit tyrosine phosphorylation of cdb3 at its NH2 terminus by a purified calf thymus tyrosine kinase. These studies reveal two regions of cdb3, distant in primary sequence, which interact with ankyrin. A specific conformation of cdb3 may be required to permit these regions to simultaneously associate with ankyrin and allow binding to occur.     

Identification of the Components of a Glycolytic Enzyme Metabolon on the Human Red Blood Cell Membrane

Glycolytic enzymes (GEs) have been shown to exist in multienzyme complexes on the inner surface of the human erythrocyte membrane. Because no protein other than band 3 has been found to interact with GEs, and because several GEs do not bind band 3, we decided to identify the additional membrane proteins that serve as docking sites for GE on the membrane. For this purpose, a method known as “label transfer” that employs a photoactivatable trifunctional cross-linking reagent to deliver a biotin from a derivatized GE to its binding partner on the membrane was used. Mass spectrometry analysis of membrane proteins that were biotinylated following rebinding and photoactivation of labeled GAPDH, aldolase, lactate dehydrogenase, and pyruvate kinase revealed not only the anticipated binding partner, band 3, but also the association of GEs with specific peptides in α- and β-spectrin, ankyrin, actin, p55, and protein 4.2. More importantly, the labeled GEs were also found to transfer biotin to other GEs in the complex, demonstrating for the first time that GEs also associate with each other in their membrane complexes. Surprisingly, a new GE binding site was repeatedly identified near the junction of the membrane-spanning and cytoplasmic domains of band 3, and this binding site was confirmed by direct binding studies. These results not only identify new components of the membrane-associated GE complexes but also provide molecular details on the specific peptides that form the interfacial contacts within each interaction.     

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.     

Accumulation of altered aspartyl residues in erythrocyte proteins from patients with Down's syndrome

Spontaneous protein deamidation of labile Asn residues, generating L-isoaspartates and D-aspartates, is associated with cell aging and is enhanced by an oxidative microenvironment; to minimize the damage, the isoaspartate residues can be 'repaired' by a specific L-isoaspartate (D-aspartate) protein O-methyltransferase (PIMT). As both premature aging and chronic oxidative stress are typical features of Down's syndrome (DS), we tested the hypothesis that deamidated proteins may build up in trisomic patients. Blood samples were obtained from children with karyotypically confirmed full trisomy 21 and from age-matched healthy controls. Using recombinant PIMT as a probe, we demonstrated a dramatic rise of L-isoaspartates in erythrocyte membrane proteins from DS patients. The content of D-aspartate was also significantly increased. The integrity of the repair system was checked by evaluating methionine transport, PIMT specific activity, and intracellular concentrations of adenosylmethionine and adenosylhomocysteine. The overall methylation pathway was directly monitored by incubating fresh red blood cells with methyl-labeled methionine; a three-fold increase of protein methyl esters was detected in trisomic children. Deamidated species include ankyrin, band 4.1, band 4.2 and the integral membrane protein band 3; ankyrin and band 4.1 were significantly hypermethylated in DS. When DS red blood cells were subjected to oxidative treatment in vitro, the increase of protein deamidation paralleled lipid peroxidation and free radical generation. We observed a similar pattern in Epstein-Barr virus B-lymphocytes from trisomic patients. In conclusion, our findings support the hypothesis that protein instability at asparagine sites is a biochemical feature of DS, presumably depending upon the oxidative microenvironment. The possible pathophysiological implications are discussed.     

Role ofN-Myristylation in Targeting of Band 4.2 (Pallidin) in Nonerythroid Cells

Band 4.2 (pallidin) is a major erythrocyte membrane protein which has been detected in a number of nonerythroid cell types. Increasing evidence suggests that band 4.2 is involved in maintaining membrane stability in the erythrocyte. For example, band 4.2 binds to the integral membrane protein band 3 and to cytoskeletal proteins in the erythrocyte membrane, and band 4.2 deficiency results in varying degrees of hemolytic anemia. We have previously shown that human erythrocyte band 4.2 is myristylated at its penultimate glycine. Here we report that when expressed in both Sf9 and COS cells, myristylated forms of band 4.2 are detected at different intracellular locations than nonmyristylated forms. We also show that the unspliced form of human erythrocyte band 4.2 (a minor form in reticulocytes which contains an additional 30 amino acids after the first three N-terminal amino acids compared to the major erythroid form) is myristylated only at a barely detectable level, while mouse erythrocyte band 4.2 (homologous to the major erythroid form of human band 4.2) is myristylated at a level comparable to that of human band 4.2. These results suggest that myristylation plays a key role in the targeting of band 4.2 to specific intracellular locations and is likely to have a role in the function of this protein.     

Preparation of red-cell-membrane cytoskeletal constituents and characterisation of protein 4.1

A new and rapid method is described for the preparation of protein 4.1, the protein which modulates the interaction between spectrin and actin in the membrane cytoskeleton of the red cell. The method is based on the dissociation of purified membrane cytoskeletons in concentrated Tris at neutral pH, followed by gel filtration in the same medium. This procedure also yields spectrin and actin, as well as the fourth cytoskeletal constituent, protein 4.9, in relatively pure form, and ankyrin. Protein 4.1 is monomeric under our conditions of solvent and protein concentration, with a relative molecular mass, as determined from sedimentation equilibrium, of about 78 000; its sedimentation coefficient and Stokes' radius are those of a globular, though somewhat asymmetric or flexible molecule. It forms a strong complex with F-actin and spectrin. Protein 4.9 is also recovered in active form, and will bind strongly to F-actin.     

Identification of Contact Sites between Ankyrin and Band 3 in the Human Erythrocyte Membrane

The red cell membrane is stabilized by a spectrin/actin-based cortical cytoskeleton connected to the phospholipid bilayer via multiple protein bridges. By virtue of its interaction with ankyrin and adducin, the anion transporter, band 3 (AE1), contributes prominently to these bridges. In a previous study, we demonstrated that an exposed loop comprising residues 175-185 of the cytoplasmic domain of band 3 (cdB3) constitutes a critical docking site for ankyrin on band 3. In this paper, we demonstrate that an adjacent loop, comprising residues 63-73 of cdB3, is also essential for ankyrin binding. Data that support this hypothesis include the following. (1) Deletion or mutation of residues within the latter loop abrogates ankyrin binding without affecting cdB3 structure or its other functions. (2) Association of cdB3 with ankyrin is inhibited by competition with the loop peptide. (3) Resealing of the loop peptide into erythrocyte ghosts alters membrane morphology and stability. To characterize cdB3-ankyrin interaction further, we identified their interfacial contact sites using molecular docking software and the crystal structures of D(3)D(4)-ankyrin and cdB3. The best fit for the interaction reveals multiple salt bridges and hydrophobic contacts between the two proteins. The most important ion pair interactions are (i) cdB3 K69-ankyrin E645, (ii) cdB3 E72-ankyrin K611, and (iii) cdB3 D183-ankyrin N601 and Q634. Mutation of these four residues on ankyrin yielded an ankyrin with a native CD spectrum but little or no affinity for cdB3. These data define the docking interface between cdB3 and ankyrin in greater detail.     

Study of human erythrocyte membrane protein interactions by selective solubilization of Triton-skeletons

Summary— The membrane skeleton, responsible for shape and mechanical properties of the red cell, was purified by the Triton extraction procedure in presence of 5 mM, 150 mM or 600 mM NaCl. The proportion of spectrin, protein 4.1 and actin present in erythrocyte skeletons does not depend on the molarity of NaCl used. In contrast ankyrin, protein band 3 and protein 4.2 are removed from skeletons as the ionic strength increased. Solubilization assays of membrane skeletons were used to study protein interactions inside the skeleton. Solubilization was performed by Tris, a non-selective disruptive reagent, or by p-mercuribenzene sulfonic acid (PMBS), which principally release spectrin and actin. Tris action was assessed by calculation of the percentage of solubilized proteins, which increased proportionally with Tris molarity. PMBS action was kinetically determined as the decrease in skeleton turbidity. With these two reagents, we observed a lower dissociation of skeletons prepared with high ionic strength buffer. Erythrocyte pretreatment with okadaic acid, an inhibitor of serine-threonine phosphatases, revealed a phosphorylation-induced skeleton gelation and a better resistance to Tris-solubilization.     

Diversity in membrane binding sites of ankyrins. Brain ankyrin, erythrocyte ankyrin, and processed erythrocyte ankyrin associate with distinct sites in kidney microsomes

This report presents evidence for diversity in membrane binding sites between three forms of ankyrin: brain ankyrin, erythrocyte ankyrin, and a variant of erythrocyte ankyrin (protein 2.2) present in circulating human erythrocytes that is missing a regulatory domain. These ankyrins were compared with respect to binding to kidney microsomes and exhibited the following behavior. 1) Brain and erythrocyte ankyrin each bind to distinct sites. 2) Protein 2.2 is an activated ankyrin that binds to all of the sites accessible to both brain and erythrocyte ankyrin and, in addition, associates with its own specialized sites. 3) The specificity of these membrane sites for various ankyrins is not absolute but reflects 2.5-10-fold differences in relative affinities. Further evidence that binding sites of different ankyrins share some common features is that the cytoplasmic domain of the erythrocyte anion transporter associates with all three ankyrins and displaces binding of the ankyrin variants to kidney membranes. The differences between erythrocyte and brain ankyrins in association with kidney membranes are likely to have physiological relevance to kidney because immunologically related isoforms of ankyrin are expressed in this tissue: erythroid ankyrin which is restricted to the basolateral domains of two cell types and a brain-related ankyrin expressed in all cells and present on apical as well as basolateral membrane surfaces. An unanticipated observation was the discovery of a membrane-associated ankyrin protease in kidney that is specific for erythrocyte ankyrin and may selectively activate the erythroid isoform of ankyrin. The variety of binding sites within this group of ankyrin proteins supports the idea that ankyrins are capable of linking a number of different membrane proteins to the spectrin-actin skeleton.     

Analysis of changes in tyrosine and serine phosphorylation of red cell membrane proteins induced by P. falciparum growth

Phosphorylation of erythrocyte membrane proteins has been previously documented following infection and intracellular growth of the malarial parasite, Plasmodium falciparum in red cells. Much of this data dealt with phosphorylation of serine residues. In this study, we report detailed characterization of phosphorylation of serine and tyrosine residues of red cell membrane proteins following infection by P falciparum. Western blot analysis using anti‐phosphotyrosine and anti‐phosphoserine antibodies following 2‐DE in conjunction with double channel laser‐induced infrared fluorescence enabled accurate assessment of phosphorylation changes. Tyrosine phosphorylation of band 3 represented the earliest modification observed during parasite development. Band 3 tyrosine phosphorylation observed at the ring stage appears to be under the control of Syk kinase. Serine and tyrosine phosphorylation of additional cytoskeletal, trans‐membrane and membrane associated proteins was documented as intracellular development of parasite progressed. Importantly, during late schizont stage of parasite maturation, we observed widespread protein dephosphorylation. In vitro treatments that caused distinct activation of red cell tyrosine and serine kinases elicited phosphorylative patterns similar to what observed in parasitized red blood cell, suggesting primary involvement of erythrocyte kinases. Identification of tyrosine phosphorylations of band 3, band 4.2, catalase and actin which have not been previously described in P. falciparum infected red cells suggests new potential regulatory mechanisms that could modify the functions of the host cell membrane.     

In vitro digestion of spectrin, protein 4.1 and ankyrin by erythrocyte calcium dependent neutral protease (calpain I)

1. In whole ghosts, ankyrin, protein 4.1, protein band 3 and spectrin are lysed by purified calpain I in the presence of calcium. 2. Limited calpain lysis of purified ankyrin results in several peptides, including a 85 kD peptide bearing the ankyrin interaction site for the protein band 3 internal fragment (43 kD), and a 55 kD peptide carrying the ankyrin-spectrin interaction site. 3. These peptides are differently phosphorylated: the 85 kD by cytosol casein kinase, and the 55 kD by membrane casein kinase. 4. Protein 4.1 lysis mainly produces a 30 kD peptide resistant to proteolysis. 5. The spectrin beta-chain is more sensitive to calpain cleavage than the alpha chain; both chains seem to be cleaved in a similar sequential manner. 6. Limited proteolysis of spectrin dimer does not impede tetramerization in vitro.