Biochemical characterization of complex formation by human erythrocyte spectrin, protein 4.1, and actin

Ternary complex formation between the major human erythrocyte membrane skeletal proteins spectrin, protein 4.1, and actin was quantified by measuring cosedimentation of spectrin and band 4.1 with F-actin. Complex formation was dependent upon the concentration of spectrin and band 4.1, each of which promoted the binding of the other to F-actin. Simultaneous measurement of the concentrations of spectrin and band 4.1 in the sedimentable complex showed that a single molecule of band 4.1 was sufficient to promote the binding of a spectrin dimer to F-actin. However, the molar ratio of band 4.1/spectrin in the complex was not fixed, ranging from approximately 0.6 to 2.2 as the relative concentration of added spectrin to band 4.1 was decreased. A mole ratio of 0.6 band 4.1/spectrin suggests that a single molecule of band 4.1 can promote the binding of more than one spectrin dimer to an actin filament. Saturation binding studies showed that in the presence of band 4.1 every actin monomer in a filament could bind at least one molecule of spectrin, yielding ternary complexes with spectrin/actin mole ratios as high as 1.4. Electron microscopy of such complexes showed them to consist of actin filaments heavily decorated with spectrin dimers. Ternary complex formation was not affected by alteration in Mg2+ or Ca2+ concentration but was markedly inhibited by KCl above 100 mM and nearly abolished by 10 mM 2,3-diphosphoglycerate or 10 mM adenosine 5'-triphosphate. Our data are used to refine the molecular model of the red cell membrane skeleton.     

Spectrin and protein 4.1 as an actin filament capping complex

Spectrin and protein 4.1, when added to G- or F-actin, cause the formation of short filaments, as judged by the appearance of powerful nucleating activity for G-actin polymerisation. F-Actin filaments are rapidly fragmented under physiological solvent conditions. The effect of cytochalasin E on the polymerisation reaction and the extent of reduction in the critical monomer concentration of actin when spectrin and 4.1 are added suggest that these proteins form a capping system for the more slowly growing, or 'pointed' ends of actin filaments. The interaction is not affected by calcium or by 4.9, the remaining constituent of the purified red cell membrane cytoskeleton.     

Composition of the ternary protein complex of the red cell membrane cytoskeleton

The red cell membrane skeletal network is constructed from actin, spectrin and protein 4.1 in a molar ratio of actin subunits/spectrin heterodimer/protein 4.1 of 2:1:1. This represents saturation of the actin filaments, since incubation with extraneous spectrin and protein 4.1 leads to no binding of additional spectrin, either to the inner surface of ghost membranes or to lipid-free membrane cytoskeletons. Partial extraction of spectrin from the membrane is accompanied by release of actin under all conditions. Regardless of the proportion of spectrin extracted, the molar ratio of spectrin dimers/actin subunits is constant at 1:2. This is not the result of release or cooperative breakdown of whole lattice junctions from the network, for the number of actin filaments, judged by capacity to nucleate polymerisation of added G-actin, remains unchanged even when as much as 60% of the total spectrin has been lost. A similar 1:2:1 stoichiometry characterises the complex formed when G-actin is allowed to polymerise in the presence of varying amounts of spectrin and protein 4.1. When this complex is treated with the depolymerising agent, 1 M guanidine hydrochloride, it breaks down into smaller units of the same stoichiometry. After cross-linking these can be recovered from a gel-filtration column. Complexes prepared starting from G-actin appear to be much more stable than those formed when spectrin and protein 4.1 are bound to F-actin.     

Functional characterization of spectrin-actin-binding domains in 4.1 family of proteins

Protein 4.1R is the prototypical member of a protein family that includes 4.1G, 4.1B, and 4.1N. 4.1R plays a crucial role in maintaining membrane mechanical integrity by binding cooperatively to spectrin and actin through its spectrin-actin-binding (SAB) domain. While the binary interaction between 4.1R and spectrin has been well characterized, the actin binding site in 4.1R remains unidentified. Moreover, little is known about the interaction of 4.1R homologues with spectrin and actin. In the present study, we showed that the 8 aa motif (LKKNFMES) within the 10 kDa spectrin-actin-binding domain of 4.1R plays a critical role in binding of 4.1R to actin. Recombinant 4.1R SAB domain peptides with mutations in this motif showed a marked decrease in their ability to form ternary complexes with spectrin and actin. Binary protein-protein interaction studies revealed that this decrease resulted from the inability of mutant SAB peptides to bind to actin filaments while affinity for spectrin was unchanged. We also documented that the 14 C-terminal residues of the 21 amino acid cassette encoded by exon 16 in conjunction with residues 27-43 encoded by exon 17 constituted a fully functional minimal spectrin-binding motif. Finally, we showed that 4.1N SAB domain was unable to form a ternary complex with spectrin and actin, while 4.1G and 4.1B SAB domains were able to form such a complex but less efficiently than 4.1R SAB. This was due to a decrease in the ability of 4.1G and 4.1B SAB domain to interact with actin but not with spectrin. These data enabled us to propose a model for the 4.1R-spectrin-actin ternary complex which may serve as a general paradigm for regulation of spectrin-based cytoskeleton interaction in various cell types.     

Spectrin-dependent and -independent association of F-actin with the erythrocyte membrane

Binding of F-actin to spectrin-actin-depleted erythrocyte membrane inside-out vesicles was measured using [3H]F-actin. F-actin binding to vesicles at 25 degrees C was stimulated 5-10 fold by addition of spectrin dimers or tetramers to vesicles. Spectrin tetramer was twice as effective as dimer in stimulating actin binding, but neither tetramer nor dimer stimulated binding at 4 degrees C. The addition of purified erythrocyte membrane protein band 4.1 to spectrin- reconstituted vesicles doubled their actin-binding capacity. Trypsinization of unreconstituted vesicles that contain < 10% of the spectrin but nearly all of the band 4.1, relative to ghosts, decreased their F-actin-binding capacity by 70%. Whereas little or none of the residual spectrin was affected by trypsinization, band 4.1 was significantly degraded. Our results show that spectrin can anchor actin filaments to the cytoplasmic surface of erythrocyte membranes and suggest that band 4.1 may be importantly involved in the association.     

Ca2(+)-dependent regulation of the spectrin/actin interaction by calmodulin and protein 4.1

The Ca2(+)-dependent regulation of the erythroid membrane cytoskeleton was investigated. The low-salt extract of erythroid membranes, which is mainly composed of spectrin, protein 4.1, and actin, confers a Ca2+ sensitivity on its interaction with F-actin. This Ca2+ sensitivity is fortified by calmodulin and antagonized by trifluoperazine, a potent calmodulin inhibitor. Additionally, calmodulin is detected in the low-salt extract. These results suggest that calmodulin is the sole Ca2(+)-sensitive factor in the low-salt extract. The main target of calmodulin in the erythroid membrane cytoskeleton was further examined. Under native conditions, calmodulin forms a stable and equivalent complex with protein 4.1 as determined by calmodulin affinity chromatography, cross-linking experiments, and fluorescence binding assays with an apparent Kd of 5.5 x 10(-7) M irrespective of the free Ca2+ concentration. Domain mapping with chymotryptic digestion reveals that the calmodulin-binding site resides within the N-terminal 30-kDa fragment of protein 4.1. In contrast, the interaction of calmodulin with spectrin is unexpectedly weak (Kd = 1.2 x 10(-4) M). Given the content of calmodulin in erythrocytes (2-5 microM), these results imply that the major target for calmodulin in the erythroid membrane cytoskeleton is protein 4.1. Low- and high-shear viscometry and binding assays reveal that an equivalent complex of calmodulin with protein 4.1 regulates the spectrin/actin interaction in a Ca2(+)-dependent manner. At a low Ca2+ concentration, protein 4.1 potentiates the actin cross-linking and the actin binding activities of spectrin. At a high Ca2+ concentration, the protein 4.1-potentiated actin cross-linking activity but not the actin binding activity of spectrin is suppressed by Ca2+/calmodulin. The Ca2(+)-dependent regulation of the spectrin/protein 4.1/calmodulin/actin interaction is discussed.     

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.     

Identification and functional characterization of protein 4.1R and actin-binding sites in erythrocyte beta spectrin: regulation of the interactions by phosphatidylinositol-4,5-bisphosphate

The ternary complex of spectrin, F-actin, and protein 4.1R defines the erythrocyte membrane skeletal network, which governs the stability and elasticity of the membrane. It has been shown that both 4.1R and actin bind to the N-terminal region (residues 1-301) of the spectrin beta chain, which contains two calponin homology domains, designated CH1 and CH2. Here, we show that 4.1R also binds to the separate CH1 and CH2 domains. Unexpectedly, truncation of the CH2 domain by its 20 amino acids, corresponding to its N-terminal alpha helix, was found to greatly enhance its binding to 4.1R. The intact N terminus and the CH1 but not the CH2 domain bind to F-actin, but again, deletion of the first 20 amino acids of the latter exposes an actin-binding activity. As expected, the polypeptide 1-301 inhibits the binding of spectrin dimer to actin and formation of the spectrin-actin-4.1R ternary complex in vitro. Furthermore, the binding of 4.1R to 1-301 is greatly enhanced by PIP(2), implying the existence of a regulatory switch in the cell.     

Ultrastructure of unit fragments of the skeleton of the human erythrocyte membrane

We have examined fragments of the filamentous network underlying the human erythrocyte membrane by high-resolution electron microscopy. Networks were released from ghosts by extraction with Triton X-100, freed of extraneous proteins in 1.5 M NaCl, and collected by centrifugation onto a sucrose cushion. These preparations contained primarily protein bands 1 + 2 (spectrin), band 4.1 and band 5 (actin). The networks were partially disassembled by incubation at 37 degrees C in 2 mM NaPi (pH 7), which caused the preferential dissociation of spectrin tetramers to dimers. The fragments so generated were fractionated by gel filtration chromatography and visualized by negative staining with uranyl acetate on fenestrated carbon films. Unit complexes, which sedimented at approximately 40S, contained linear filaments approximately 7-8 nm diam from which several slender and convoluted filaments projected. The linear filaments had a mean length of 52 +/- 17 nm and a serrated profile reminiscent of F-actin. They could be decorated in an arrowhead pattern with S1 fragments of muscle heavy meromyosin which, incidentally, displaced the convoluted filaments. Furthermore, the linear filaments nucleated the polymerization of rabbit muscle G-actin, predominantly but not exclusively from the fast-growing ends. On this basis, we have identified the linear filaments as F-actin; we infer that the convoluted filaments are spectrin. Spectrin molecules were usually attached to actin filaments in clusters that showed a preference for the ends of the F-actin. We also observed free globules up to 15 nm diam, usually associated with three spectrin molecules, which also nucleated actin polymerization; these may be simple junctional complexes of spectrin, actin, and band 4.1. In larger ensembles, spectrin tetramers linked actin filaments and/or globules into irregular arrays. Intact networks were an elaboration of the basic pattern manifested by the fragments. Thus, we have provided ultrastructural evidence that the submembrane skeleton is organized, as widely inferred from less direct information, into short actin filaments linked by multiple tetramers of spectrin clustered at sites of association with band 4.1.     

Separation of the lipid bilayer from the membrane skeleton during discocyte-echinocyte transformation of human erythrocyte ghosts

The membrane skeleton, a protein lattice at the internal side of the red cell membrane, is principally composed of spectrin, actin and proteins 4.1 and 4.9. We have examined negatively stained red cell ghosts and demonstrated, on an ultrastructural level, a separation of the lipid bilayer from the membrane skeleton during echinocytic transformation. The electron micrographs of discoidal red cell ghosts suspended in hypotonic buffer revealed a filamentous reticulum that uniformly laminated the entire submembrane region. transformation of the discoidal ghosts into echinocytic form, as induced by incubation in isotonic buffer, resulted in a disruption of skeletal continuity underlying the surface contour of the membrane spicule. The submembrane reticulum extended into the base and the neck of the spiny processes of the crenated ghosts but was absent at the tip of these projections. In addition, membrane vesicles without a submembrane reticulum were detected either attached to the tips of the spicules or released into the supernatant from the echinocytic ghosts. Protein analysis revealed that the released vesicles were enriched in bands 3, 4.1 and 7 and contained very little of the membrane skeletal proteins, spectrin and actin. The data indicate that during echinocyte formation, parts of the lipid bilayer physically separate from the membrane skeleton, leading to a formation of skeleton-poor lipid vesicles.     

Radiolabel-transfer cross-linking demonstrates that protein 4.1 binds to the N-terminal region of beta spectrin and to actin in binary interactions

Erythrocyte protein 4.1 plays a major role in stabilizing the spectrin-actin junction of the erythrocyte membrane skeleton. The particular sites on spectrin responsible for the binding of actin and protein 4.1 have not been specifically defined, although the general region of the 'tail' end, opposite the self-association site, has been deduced by electron microscopy. Using a photoactivatable, radiolabel-transfer cross-linker, 1-[N-(2-hydroxy-5-azidobenzoyl)-2-aminoethyl]-4-(N-hydroxysuccinimidyl)- succinate, we have determined that the binding site for protein 4.1 on spectrin resides in the N-terminal region of beta spectrin within a sequence homologous to the actin-binding region of alpha actinin. Moreover, this technique provided clear evidence for a direct binding interaction between actin filaments and protein 4.1 that was confirmed by rapid-sedimentation assays. In summary, use of radiolabel-transfer cross-linking has enabled assignment of the protein-4.1-binding site on erythrocyte spectrin and has identified a previously ill-defined binary interaction between protein 4.1 and F-actin.     

The role of band 4.1 in the association of actin with erythrocyte membranes

Spectrin stimulates the association of F-actin with erythrocyte inside-out vesicles. Although inside-out vesicles are nearly devoid of two of the three major cytoskeletal proteins, spectrin and actin, they retain nearly all of the cytoskeletal protein designated band 4.1. Inside-out vesicles which have been substantially depleted of band 4.1 by extraction in 1 M KCl, 0.4 M urea and then reconstituted with spectrin show a markedly diminished ability to bind actin by comparison with vesicles containing normal amounts of band 4.1. This diminution is not due to an impaired ability of the vesicles to bind spectrin. Addition of purified band 4.1 to vesicles either before or after they have been reconstituted with spectrin restores their actin binding capacity to near normal levels as does addition of a spectrin-band 4.1 complex prepared by sucrose gradient centrifugation. Band 4.1 bound to vesicles in the absence of added spectrin has no effect on actin binding. Our results suggest that a spectrin band 4.1 complex is responsible for binding actin to erythrocyte membranes.     

Spectrin plus band 4.1 cross-link actin. Regulation by micromolar calcium

A low-salt extract prepared from human erythrocyte membranes forms a solid gel when purified rabbit muscle G- or F-actin is added to it to give a concentration of approximately 1 mg/ml. This extract contains spectrin, actin, band 4.1, band 4.9, hemoglobin, and several minor components. Pellets obtained by centrifugation of the gelled material at 43,000 g for 10 min contain spectrin, actin, band 4.1, and band 4.9. Although extracts that are diluted severalfold do not gel when actin is added to them, the viscosity of the mixtures increases dramatically over that of G-actin alone, extract alone, or F-actin alone at equivalent concentrations. Heat-denatured extract is completely inactive. Under conditions of physiological ionic strength and pH, information of this supramolecular structure is inhibited by raising the free calcium ion concentration to micromolar levels. Low-salt extracts prepared by initial extraction at 37 degrees C (and stored at 0 degree C) gel after actin is added to them only when warmed, whereas extracts prepared by extraction at 0 degree C are active on ice as well as after warming. Preincubation of the 37 degrees C low-salt extract under conditions that favor conversion of spectrin dimer to tetramer greatly enhances gelation activity at 0 degree C. Conversely, preincubation of the 0 degree C low-salt extract under conditions that favor conversion of spectrin tetramer to dimer greatly diminishes gelation activity at 0 degree C. Spectrin dimers or tetramers are purified from the 37 dgrees or 0 degree C low-salt extract by gel filtration at 4 degrees C over Sepharose 4B. The addition of actin to either purified spectrin dimer (at 32 degrees C) or tetramer (at 0 degree C or 32 degrees C) results in relatively small increases in viscosity, whereas the addition of actin to a high-molecular-weight complex (HMW complex) containing spectrin, actin, band 4.1, and band 4.9 results in dramatic, calcium-sensitive increases in viscosity. These viscosities are comparable to those obtained with the 37 degrees or 0 degree C low-salt extracts. The addition of purified band 4.1 to either purified spectrin dimer (at 32 degrees C) or purified spectrin tetramer (at 0 degree C) plus actin results in large increases in viscosity similar to those observed for the HMW complex and the crude extract, which is in agreement with a recent report by E. Ungewickell, P. M. Bennett, R. Calvert, V. Ohanian, and W. B. Gratzer. 1979 Nature (Lond.) 280:811-814. We suggest that this spectrin-actin-band 4.1 gel represents a major structural component of the erythrocyte cytoskeleton.     

The genetics of the protein 4.1 family: organizers of the membrane and cytoskeleton

Protein 4.1 (also called band 4.1 or simply 4.1) was originally identified as an abundant protein of the human erythrocyte, in which it stabilizes the spectrin/actin cytoskeleton. The protein and its relatives have since been found in many cell types of metazoan organisms and they are often concentrated in the nucleus, as well as in cell-cell junctions. They form multimolecular complexes with transmembrane and membrane-associated proteins, and these complexes may be important for both structural stability and signal transduction at sites of cell contact.     

Functional characterization of human erythrocyte spectrin alpha and beta chains: association with actin and erythrocyte protein 4.1

Human erythrocyte spectrin alpha and beta chains were purified by preparative sodium dodecyl sulfate gel electrophoresis and also by DEAE-cellulose chromatography in the presence of urea. The purified chains behaved as individual monomers on sucrose gradients and did not form homodimers. Recombination of the chains led to the formation of alpha-beta heterodimers with sedimentation characteristics identical with native alpha-beta dimers. The binding of 125I-labeled band 4.1 to alpha and beta chains was measured by sucrose gradient rate zonal sedimentation and by quantitative immunoassay. It was found that both alpha and beta chains associated with 125I-labeled band 4.1 in a nearly identical manner over the range of band 4.1 concentration studied. The association was abolished by heat denaturation of the spectrin chains or by denaturation of band 4.1 with a 40-fold molar excess of N-ethylmaleimide. As expected, purified beta chains but not alpha chains bound to 125I-labeled ankyrin as measured by a quantitative radioimmunoassay. The binding of purified alpha chains, beta chains, and recombinant alpha-beta heterodimers to F-actin was measured in the presence of band 4.1. We found that alpha or beta chains separately exhibited no band 4.1 dependent association with F-actin but that alpha-beta heterodimers formed by recombination of the chains did. We conclude that spectrin binding to F-actin in the presence of band 4.1 requires the participation of both of spectrin's polypeptide chains.     

Structural unit of the erythrocyte cytoskeleton. Isolation and electron microscopic examination

We isolated a protein complex containing major cytoskeletal components from the Triton shell of bovine erythrocytes. This protein complex, which we called the 26-S complex, consisted of three major components, spectrin, band-4.1 protein and actin, and one minor component, band-4.9 protein. The molar ratio of spectrin heterodimer:band 4.1:actin was determined by sodium dodecyl sulfate (SDS) gel electrophoresis to be about 1:2:2, approximately the same as that for the Triton shell. By electron microscopic examinations of rotary-shadowed specimens, it was revealed that the 26-S complex had a "spider-like" morphology with a central core and several spectrin heterodimers radiating from it. The number of spectrin arms in the complex was not constant but was in the range between 3 and 6. The complexes with five spectrin heterodimers were the most numerous. The results showed that the 26-S complex contained on the average five spectrin heterodimers, ten band-4.1 polypeptides and ten actin monomers. As judged from the formation of oligomeric 26-S complexes through spectrin arms, the central core of the complex presumably contains band 4.1 and actin. Supporting this conclusion, the central core acted as a nucleus for actin polymerization when the 26-S complex was mixed with G-actin under an actin-polymerizing condition. The 26-S complex could form large aggregates under a certain condition that spectrin was promoted to associate from dimer to tetramer. We conclude that the 26-S complex is the structural unit of the erythrocyte cytoskeleton.     

An examination of the soluble oligomeric complexes extracted from the red cell membrane and their relation to the membrane cytoskeleton

A part of the spectrin extracted from red cell membranes at low ionic strength occurs in the form of a high-molecular weight oligomeric complex with actin and proteins 4.1 and 4.9. When the extraction is performed at 35 degrees, the spectrin is present in this complex as the dimer, all higher forms being dissociated. We have been unable to establish any correlation between the fraction of the spectrin thus complexed and the metabolic state of the cell. At least a large part of the complex appears to be a defined monodisperse species, sedimenting at 31S. The actin is present as short protofilaments. The average number of spectrin molecules associated with each molecule of complex has been studied by cytochalasin binding and electron microscopy. The complexes present the appearance in the electron microscope of spiders, in which the legs are spectrin dimers, attached to a globular element, containing by inference, actin and proteins 4.1 and 4.9; they are active in nucleating the polymerization of G-actin. The complexes are extremely stable, being resistant to dissociation under the conditions of the deoxyribonuclease assay, even after treatment with trypsin to degrade the actin-associated proteins. It is suggested that the complexes represent intact junctions of the membrane cytoskeletal network. Relevant structural features of the network are revealed by electron microscopy. The results lead to inferences concerning the mechanism of dissociation of the network from the membrane.     

The spectrin-actin junction of erythrocyte membrane skeletons

High-resolution electron microscopy of erythrocyte membrane skeletons has provided striking images of a regular lattice-like organization with five or six spectrin molecules attached to short actin filaments to form a sheet of five- and six-sided polygons. Visualization of the membrane skeletons has focused attention on the (spectrin)5,6-actin oligomers, which form the vertices of the polygons, as basic structural units of the lattice. Membrane skeletons and isolated junctional complexes contain four proteins that are stable components of this structure in the following ratios: 1 mol of spectrin dimer, 2-3 mol of actin, 1 mol of protein 4.1 and 0.1-0.5 mol of protein 4.9 (numbers refer to mobility on SDS gels). Additional proteins have been identified that are candidates to interact with the junction, based on in vitro assays, although they have not yet been localized to this structure and include: tropomyosin, tropomyosin-binding protein and adducin. The spectrin-actin complex with its associated proteins has a key structural role in mediating cross-linking of spectrin into the network of the membrane skeleton, and is a potential site for regulation of membrane properties. The purpose of this article is to review properties of known and potential constituent proteins of the spectrin-actin junction, regulation of their interactions, the role of junction proteins in erythrocyte membrane dysfunction, and to consider aspects of assembly of the junctions.     

Spectrin-4.1-actin complex of the human erythrocyte: Molecular basis of its ability to bind cytochalasins with high-affinity and to accelerate actin polymerization in vitro

The spectrin-4.1-actin complex isolated from the cytoskeleton of human erythrocyte [3] was found to be similar to muscle F-actin in several aspects: Both the complex and F-actin nucleate cytochalasin-sensitive actin polymerization; both bind dihydrocytochalasin B with similar binding constants; both can be depolymerized by DNase I with loss of cytochalasin binding activity. From these results, we conclude that the actin in the complex is in an oligomeric form. However, the presence of spectrin and band 4.1 in the complex not only stabilized the actin in the complex as evidenced by its resistance to depolymerization in low-ionic-strength conditions and to DNase I as compared with F-actin, but also altered the characteristics of the binding site(s) for cytochalasins believed to be located at the “barbed” (polymerizing) end of the oligomeric actin.