Ankyrin binds to the 15th repetitive unit of erythroid and nonerythroid beta-spectrin

Ankyrin mediates the attachment of spectrin to transmembrane integral proteins in both erythroid and nonerythroid cells by binding to the beta-subunit of spectrin. Previous studies using enzymatic digestion, 2-nitro-5-thiocyanobenzoic acid cleavage, and rotary shadowing techniques have placed the spectrin-ankyrin binding site in the COOH-terminal third of beta-spectrin, but the precise site is not known. We have used a glutathione S-transferase prokaryotic expression system to prepare recombinant erythroid and nonerythroid beta-spectrin from cDNA encoding approximately the carboxy-terminal half of these proteins. Recombinant spectrin competed on an equimolar basis with 125I-labeled native spectrin for binding to erythrocyte membrane vesicles (IOVs), and also bound ankyrin in vitro as measured by sedimentation velocity experiments. Although full length beta-spectrin could inhibit all spectrin binding to IOVs, recombinant beta-spectrin encompassing the complete ankyrin binding domain but lacking the amino-terminal half of the molecule failed to inhibit about 25% of the binding capacity of the IOVs, suggesting that the ankyrin-independent spectrin membrane binding site must lie in the amino-terminal half of beta-spectrin. A nested set of shortened recombinants was generated by nuclease digestion of beta-spectrin cDNAs from ankyrin binding constructs. These defined the ankyrin binding domain as encompassing the 15th repeat unit in both erythroid and nonerythroid beta-spectrin, amino acid residues 1,768-1,898 in erythroid beta-spectrin. The ankyrin binding repeat unit is atypical in that it lacks the conserved tryptophan at position 45 (1,811) within the repeat and contains a nonhomologous 43 residue segment in the terminal third of the repeat. It also appears that the first 30 residues of this repeat, which are highly conserved between the erythroid and nonerythroid beta-spectrins, are critical for ankyrin binding activity. We hypothesize that ankyrin binds directly to the nonhomologous segment in the 15th repeat unit of both erythroid and nonerythroid beta-spectrin, but that this sequence must be presented in the context of a properly folded spectrin "repeat unit" structure. Future studies will identify which residues within the repeat unit are essential for activity, and which residues determine the specificity of various spectrins for different forms of ankyrin.     

Phosphatidylserine binding sites in erythroid spectrin: location and implications for membrane stability

The erythrocyte membrane is a composite structure consisting of a lipid bilayer tethered to the spectrin-based membrane skeleton. Two complexes of spectrin with other proteins are known to participate in the attachment. Spectrin has also been shown to interact with phosphatidylserine (PS), a component of the lipid bilayer, which is confined to its inner leaflet. That there may be multiple sites of interaction with PS in the spectrin sequence has been inferred, but they have not hitherto been identified. Here we have explored the interaction of PS-containing liposomes with native alpha- and beta-spectrin chains and with recombinant spectrin fragments encompassing the entire sequences of both chains. We show that both alpha-spectrin and beta-spectrin bind PS and that sites of high affinity are located within 8 of the 38 triple-helical structural repeats which make up the bulk of both chains; these are alpha8, alpha9-10, beta2, beta3, beta4, beta12, beta13, and beta14, and PS affinity was also found in the nonhomologous N-terminal domain of the beta-chain. No other fragments of either chain showed appreciable binding. Binding of spectrin and its constituent chains to mixed liposomes of PS and phosphatidylcholine (PC) depended on the proportion of PS. Binding of spectrin dimers to PS liposomes was inhibited by single repeats containing PS binding sites. It is noteworthy that the PS binding sites in beta-spectrin are grouped in close proximity to the sites of attachment both of ankyrin and of 4.1R, the proteins engaged in attachment of spectrin to the membrane. We conjecture that direct interaction of spectrin with PS in the membrane may modulate its interactions with the proteins and that (considering also the known affinity of 4.1R for PS) the formation of PS-rich lipid domains, which have been observed in the red cell membrane, may be a result.     

Biogenesis of the avian erythroid membrane skeleton: receptor-mediated assembly and stabilization of ankyrin (goblin) and spectrin

Ankyrin is an extrinsic membrane protein in human erythrocytes that links the alpha beta-spectrin-based extrinsic membrane skeleton to the membrane by binding simultaneously to the beta-spectrin subunit and to the transmembrane anion transporter. To analyse the temporal and spatial regulation of assembly of this membrane skeleton, we investigated the kinetics of synthesis and assembly of ankyrin ( goblin ) with respect to those of spectrin in chicken embryo erythroid cells. Electrophoretic analysis of Triton X-100 soluble and cytoskeletal fractions show that at steady state both ankyrin and spectrin are detected exclusively in the cytoskeleton. In contrast, continuous labeling of erythroid cells with [35S]methionine, and immunoprecipitation of ankyrin and alpha- and beta-spectrin, reveals that newly synthesized ankyrin and spectrin are partitioned into both the cytoskeletal and Triton X-100 soluble fractions. The soluble pools of ankyrin and beta-spectrin reach a plateau of labeling within 1 h, whereas the soluble pool of alpha-spectrin is substantially larger and reaches a plateau more slowly, reflecting an approximately 3:1 ratio of synthesis of alpha- to beta-spectrin. Ankyrin and beta-spectrin enter the cytoskeletal fraction within 10 min of labeling, and the amount assembled into the cytoskeletal fraction exceeds the amount present in their respective soluble pools within 1 h of labeling. Although alpha-spectrin enters the cytoskeletal fraction with similar kinetics to beta-spectrin and ankyrin, and in amounts equimolar to beta-spectrin, the amount of cytoskeletal alpha-spectrin does not exceed the amount of soluble alpha-spectrin even after 3 h of labeling. Pulse-chase labeling experiments reveal that ankyrin and alpha- and beta-spectrin assembled into the cytoskeleton exhibit no detectable turnover, whereas the Triton X-100 soluble polypeptides are rapidly catabolized, suggesting that stable assembly of the three polypeptides is dependent upon their association with their respective membrane receptor(s). The existence in the detergent-soluble compartment of newly synthesized ankyrin and alpha- and beta-spectrin that are catabolized, rather than assembled, suggests that ankyrin and spectrin are synthesized in excess of available respective membrane binding sites, and that the assembly of these polypeptides, while rapid, is not tightly coupled to their synthesis. We hypothesize that the availability of the high affinity receptor(s) localized on the membrane mediates posttranslationally the extent of assembly of the three cytoskeletal proteins in the correct stoichiometry, their stability, and their spatial localization.     

Lipid-binding role of betaII-spectrin ankyrin-binding domain

It is known that erythroid and non-erythroid spectrins binding of vesicles and monolayers containing PE proved sensitive to inhibition by red blood cell ankyrin. We now show that the bacterially-expressed recombinant peptides representing betaII(brain)-spectrin's ankyrin-binding domain and its truncated mutants showed lipid-binding activity, although only those containing a full-length amino terminal fragment showed high to moderate affinity towards phospholipid mono- and bilayers and a substantial sensitivity of this binding to inhibition by ankyrin. These results are in accordance with our published data on betaI-spectrin's ankyrin-binding domain [Hryniewicz-Jankowska A, et al. Mapping of ankyrin-sensitive, PE/PC mono- and bilayer binding site in erythroid beta-spectrin. Biochem J 2004;382:677-85]. Moreover, we tested also the effect of transient transfection of living cells of several cell-lines with vectors coding for GFP-conjugates including betaII and also betaI full-length ankyrin-binding domain and their truncated fragments on the membrane skeleton organization. The transfection with constructs encoding full-length ankyrin-binding domain of betaII and betaI spectrin resulted in increased aggregation of membrane skeleton and its punctate appearance in contrast to near normal appearance of membrane skeleton of cells transiently transfected with GFP control or construct encoding ankyrin-binding domain truncated at their N-terminal region. Our results therefore indicate the importance of N-terminal region for lipid-binding activity of the beta-spectrin ankyrin-binding domain and its substantial role in maintaining the spectrin-based skeleton distribution.     

The role of hydrophobic interactions in ankyrin-spectrin complex formation

Spectrin and ankyrin are the key components of the erythrocyte cytoskeleton. The recently published crystal structure of the spectrin-ankyrin complex has indicated that their binding involves complementary charge interactions as well as hydrophobic interactions. However, only the former is supported by biochemical evidence. We now show that nonpolar interactions are important for high affinity complex formation, excluding the possibility that the binding is exclusively mediated by association of distinctly charged surfaces. Along these lines we report that substitution of a single hydrophobic residue, F917S in ankyrin, disrupts the structure of the binding site and leads to complete loss of spectrin affinity. Finally, we present data showing that minimal ankyrin binding site in spectrin is formed by helix 14C together with the loop between helices 15 B/C.     

Contributions of the beta-subunit to spectrin structure and function

The three avian spectrins that have been characterized consist of a common alpha-subunit (240 kD) paired with an isoform-specific beta-subunit from either erythrocyte (220 or 230 kD), brain (235 kD), or intestinal brush border (260 kD). Analysis of avian spectrins, with their naturally occurring "subunit replacement" has proved useful in assessing the relative contribution of each subunit to spectrin function. In this study we have completed a survey of avian spectrin binding properties and present morphometric analysis of the relative flexibility and linearity of various avian and human spectrin isoforms. Evidence is presented that, like its mammalian counterpart, avian brain spectrin binds human erythroid ankyrin with low affinity. Cosedimentation analysis demonstrates that 1) avian erythroid protein 4.1 stimulates spectrin-actin binding of both mammalian and avian erythrocyte and brain spectrins, but not the TW 260/240 isoform, 2) calpactin I does not potentiate actin binding of either TW 260/240 or brain spectrin, and 3) erythrocyte adducin does not stimulate the interaction of TW 260/240 with actin. In addition, a morphometric analysis of rotary-shadow images of spectrin isoforms, individual subunits, and reconstituted complexes from isolated subunits was performed. This analysis revealed that the overall flexibility and linearity of a given spectrin heterodimer and tetramer is largely determined by the intrinsic rigidity and linearity of its beta-spectrin subunit. No additional rigidity appears to be imparted by noncovalent associations between the subunits. The scaled flexural rigidity of the most rigid spectrin analyzed (human brain) is similar to that reported for F-actin.     

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.     

Structural insights into the stability and flexibility of unusual erythroid spectrin repeats

Erythroid spectrin, a major component of the cytoskeletal network of the red cell which contributes to both the stability and the elasticity of the red cell membrane, is composed of two subunits, alpha and beta, each formed by 16-20 tandem repeats. The properties of the repeats and their relative arrangement are thought to be key determinants of spectrin flexibility. Here we report a 2.4 A resolution crystal structure of human erythroid beta-spectrin repeats 8 and 9. This two-repeat fragment is unusual as it exhibits low stability of folding and one of its repeats lacks two tryptophans highly conserved among spectrin repeats. Two key factors responsible for the lower stability and, possibly, its flexibility, are revealed by the structure. A third novel feature of the structure is the relative orientation of the two repeats, which increases the range of possible conformations and provides new insights into atomic models of spectrin flexibility.     

Comprehensive analysis of all triple helical repeats in beta-spectrins reveals patterns of selective evolutionary conservation

The spectrin superfamily (spectrin, alpha-actinin, utrophin and dystrophin) has in common a triple helical repeating unit of ~106 amino acid residues. In spectrin, alpha and beta chains contain multiple copies of this repeat. beta-spectrin chains contain the majority of binding activities in spectrin and are essential for animal life. Canonical beta-spectrins have 17 repeats; beta-heavy spectrins have 30. Here, the repeats of five human beta-spectrins, plus beta-spectrins from several other vertebrates and invertebrates, have been analysed. Repeats 1, 2, 14 and 17 in canonical beta are highly conserved between invertebrates and vertebrates, and repeat 8 in some isoforms. This is consistent with conservation of critical functions, since repeats 1, 2 and 17 bind alpha-spectrin. Repeats 1 of beta-spectrins are not always detected by SMART or Pfam tools. A profile hidden Markov model of beta-spectrin repeat 1 detects alpha-actinins, but not utrophin or dystrophin. Novel examples of repeat 1 were detected in the spectraplakins MACF1, BPAG1 and plectin close to the actin-binding domain. Ankyrin binds to the C-terminal portion of repeat 14; the high conservation of this entire repeat may point to additional, undiscovered ligand-binding activities. This analysis indicates that the basic triple helical repeat pattern was adapted early in the evolution of the spectrin superfamily to encompass essential binding activities, which characterise individual repeats in proteins extant today.     

Cloning and chromosomal localization of the human cytoskeletal alpha-actinin gene reveals linkage to the beta-spectrin gene.

We report the cloning and characterization of a full-length cDNA encoding the human cytoskeletal isoform of alpha-actinin (alpha A), a ubiquitous actin-binding protein that shares structural homology with spectrin and dystrophin. The gene encodes 891 amino acids with 96%-98% sequence identity at the amino acid level to chicken nonskeletal muscle alpha A. Transient expression in COS cells produces a protein of approximately 104 kD that comigrates on SDS-PAGE with native alpha A. This alpha A gene is localized to chromosome 14q22-q24 by somatic cell hybrid and in situ hybridization analyses. Pulsed-field gel analysis of human genomic DNA revealed identically sized fragments when cDNA probes for alpha A and erythroid beta-spectrin were used; the latter gene has been previously localized to chromosome 14, band q22. These observations indicate that the genes for cytoskeletal alpha A and beta-spectrin are, in all likelihood, closely physically linked and that, in accordance with their similar structural features, they arose by partial duplication of an ancestral gene.     

Independent movement, dimerization and stability of tandem repeats of chicken brain alpha-spectrin

Previous X-ray crystal structures have shown that linkers of five amino acid residues connecting pairs of chicken brain alpha-spectrin and human erythroid beta-spectrin repeats can undergo bending without losing their alpha-helical structure. To test whether bending at one linker can influence bending at an adjacent linker, the structures of two and three repeat fragments of chicken brain alpha-spectrin have been determined by X-ray crystallography. The structure of the three-repeat fragment clearly shows that bending at one linker can occur independently of bending at an adjacent linker. This observation increases the possible trajectories of modeled chains of spectrin repeats. Furthermore, the three-repeat molecule crystallized as an antiparallel dimer with a significantly smaller buried interfacial area than that of alpha-actinin, a spectrin-related molecule, but large enough and of a type indicating biological specificity. Comparison of the structures of the spectrin and alpha-actinin dimers supports weak association of the former, which could not be detected by analytical ultracentrifugation, versus strong association of the latter, which has been observed by others. To correlate features of the structure with solution properties and to test a previous model of stable spectrin and dystrophin repeats, the number of inter-helical interactions in each repeat of several spectrin structures were counted and compared to their thermal stabilities. Inter-helical interactions, but not all interactions, increased in parallel with measured thermal stabilities of each repeat and in agreement with the thermal stabilities of two and three repeats and also partial repeats of spectrin.     

Mapping the binding site on ankyrin for the voltage-dependent sodium channel from brain.

Erythrocyte ankyrin is a member of a family of proteins that mediate the linkage between membrane proteins and the underlying spectrin-actin-based cytoskeleton. Ankyrin has been shown to interact with a variety of integral membrane proteins such as the anion exchanger, the Na+K(+)-ATPase, and the voltage-dependent sodium channel (NaCh) in brain. To understand how ankyrin interacts with these proteins and maintains its specificity and high affinity for the voltage-dependent NaCh, we have mapped the binding site on ankyrin for the NaCh by examining the binding of purified ankyrin subfragments, prepared by proteolytic cleavage, to the purified rat brain NaCh incorporated into liposomes. 125I-Labeled ankyrin and the radiolabeled 89- and 43-kDa fragments of ankyrin bind to the NaCh with high affinities and with Kd values of 34, 22, and 63 nM, respectively, and have stoichiometries of approximately 1 mol/mol NaCh. The 72-kDa spectrin binding domain is inactive and does not bind to the NaCh. Dissection of ankyrin reveals that the 43-kDa domain retains all the binding properties of native ankyrin to the NaCh. Analysis of the primary structure reveals that the NaCh binding site is confined to a domain of ankyrin consisting entirely of the 11 terminal 33-amino acid repeats and is distinct from the ankyrin domains that interact with spectrin and the Na+K(+)-ATPase.     

Full-length sequence of the cDNA for human erythroid beta-spectrin

Spectrin is the major molecular consituent of the red cell membrane skeleton. We have isolated overlapping human erythroid beta-spectrin cDNA clones and determined 6773 base pairs of contiguous nucleotide sequence. This includes the entire coding sequence of beta-spectrin. The sequence translates into a 2137 amino acid, 246-kDa peptide. beta-Spectrin is found to consist of three distinct domains. Domain I, at the N terminus, is a 272-amino acid region lacking resemblance to the spectrin repetitive motif. Sequences in this region exhibit striking sequence homology, at both nucleotide and amino acid levels, to the N-terminal "actin-binding" domains of alpha-actinin and dystrophin. Between residues 51 and 270 there is 55% amino acid identity to human dystrophin, with only four single amino acid gaps in alignment. Domain II consists of 17 spectrin repeats. Several sequence variations are observed in typical repeat structure. Homology to alpha-actinin extends beyond domain I into the N-terminal portion of domain II. Domain III, 52 amino acid residues at the C terminus, does not adhere to the spectrin repeat motif. Combining knowledge of spectrin primary structure with previously reported functional studies, it is possible to make several inferences regarding structure/function relationships within the beta-spectrin molecule.     

Phospholipid-induced structural changes to an erythroid beta spectrin ankyrin-dependent lipid-binding site

The region of beta-spectrin that is responsible for interactions with ankyrin was shown to comprise an ankyrin-sensitive lipid-binding site. Structural studies indicate that it exhibits a mixed 3(10)/alpha helical conformation and is highly amphipathic. These features together with the distinctively conserved sequence of the lipid-binding site motivated us to explore the mechanism of its interactions with biological membranes. A series of singly and doubly spin-labeled erythroid beta-spectrin-derived peptides was constructed, and the spin-label mobility and spin-spin distances were analyzed via electron paramagnetic resonance spectroscopy and two different calculation methods. The results indicate that in beta-spectrin, the lipid-binding domain, which is part of the 14(th) segment, has the topology of typical triple-helical spectrin repeat. However, it undergoes significant changes when interacting with phospholipids or detergents. A mechanism for these interactions is proposed in this paper.     

Association of brain ankyrin with brain membranes and isolation of active proteolytic fragments of membrane-associated ankyrin-binding protein(s)

An assay has been developed to measure association of brain ankyrin with protein site(s) in brain membranes that are independent of spectrin and tubulin, behave as integral membrane proteins, and appear to be similar in several respects to the erythrocyte anion channel. Brain membranes were depleted of ankyrin, spectrin, and other peripheral membrane proteins by a brief incubation in 0.1 M sodium hydroxide. Binding of ankyrin to these membranes fulfilled experimentally testable criteria for a specific protein-protein association. Binding was optimal at physiological values for ionic strength and pH, was of high affinity (Kd = 20-60 nM), and the capacity of 25 pmol/mg of brain membrane protein is in the same range as the number of spectrin tetramers (30 pmol/mg). The membrane-binding site(s) for brain ankyrin are likely to be related in some way to the cytoplasmic domain of the erythrocyte anion channel since binding was inhibited by the anion channel domain and by erythrocyte ankyrin. The binding site(s) for brain ankyrin were released from the membrane by limited proteolysis as active water-soluble fragments capable of inhibiting binding of ankyrin to membranes. Ankyrin-binding fragments of Mr = 40,000 and 68,000 were selectively bound to an erythrocyte ankyrin affinity column. The fragment of Mr = 40,000 is close to the size of the cytoplasmic domain of the erythrocyte anion channel. It is likely based on these results that membrane attachment proteins for ankyrin are present in brain and other tissues and that these membrane proteins have domains homologous at least in conformation to the ankyrin-binding site of the erythrocyte anion channel.     

Brain ankyrin. Purification of a 72,000 Mr spectrin-binding domain

Polypeptides of Mr = 190,000-220,000 that cross-react with erythrocyte ankyrin were detected in immunoblots of membranes from pig lens, pig brain, and rat liver. The cross-reacting polypeptides from brain were cleaved by chymotrypsin to fragments of Mr = 95,000 and 72,000 which are the same size as fragments obtained with erythrocyte ankyrin. The brain 72,000 Mr fragment associated with erythrocyte spectrin, and the binding occurred at the same site as that of erythrocyte ankyrin 72,000 Mr fragment since (a) brain 72,000 Mr fragment was adsorbed to erythrocyte spectrin-agarose and (b) 125I-labeled erythrocyte spectrin bound to brain 72,000 Mr fragment following transfer of the fragment from a sodium dodecyl sulfate gel to nitrocellulose paper, and this binding was displaced by erythrocyte ankyrin 72,000 Mr fragment. Brain 72,000 Mr fragment was purified about 400-fold by selective extraction and by continuous chromatography on columns attached in series containing DEAE-cellulose followed by erythrocyte spectrin coupled to agarose, and finally hydroxylapatite. The brain 72,000 Mr fragment was not derived from contaminating erythrocytes since peptide maps of pig brain and pig erythrocyte 72,000 Mr fragments were distinct. The amount of brain 72,000 Mr fragment was estimated as 0.28% of membrane protein or 39 pmol/mg based on radioimmunoassay with 125I-labeled brain fragment and antibody against erythrocyte ankyrin. Brain spectrin tetramer was present in about the same number of copies (30 pmol/mg of membrane protein) based on densitometry of Coomassie blue-stained sodium dodecyl sulfate gels. The binding site on brain spectrin for both brain and erythrocyte ankyrin 72,000 Mr fragments was localized by electron microscopy to the midregion of spectrin tetramers about 90 nM from the near end and 110 nM from the far end. These studies demonstrate the presence in brain membranes of a protein closely related to erythrocyte ankyrin, and are consistent with a function of the brain ankyrin as a membrane attachment site for brain spectrin.     

A human beta-spectrin gene promoter directs high level expression in erythroid but not muscle or neural cells

beta-Spectrin is an erythrocyte membrane protein that is defective in many patients with abnormalities of red blood cell shape including hereditary spherocytosis and elliptocytosis. It is expressed not only in erythroid tissues but also in muscle and brain. We wished to determine the regulatory elements that determine the tissue-specific expression of the beta-spectrin gene. We mapped the 5'-end of the beta-spectrin erythroid cDNA and cloned the 5'-flanking genomic DNA containing the putative beta-spectrin gene promoter. Using transfection of promoter/reporter plasmids in human tissue culture cell lines, in vitro DNase I footprinting analyses, and gel mobility shift assays, a beta-spectrin gene erythroid promoter with two binding sites for GATA-1 and one site for CACCC-related proteins was identified. All three binding sites were required for full promoter activity; one of the GATA-1 motifs and the CACCC-binding motif were essential for activity. The beta-spectrin gene promoter was able to be transactivated in heterologous cells by forced expression of GATA-1. In transgenic mice, a reporter gene directed by the beta-spectrin promoter was expressed in erythroid tissues at all stages of development. Only weak expression of the reporter gene was detected in muscle and brain tissue, suggesting that additional regulatory elements are required for high level expression of the beta-spectrin gene in these tissues.     

Mapping the binding sites of human erythrocyte ankyrin for the anion exchanger and spectrin

This report describes initial characterization of the binding sites of ankyrin for spectrin and the anion exchanger using defined subfragments isolated from purified ankyrin domains. The spectrin-binding domain of ankyrin is comprised of two subdomains: an acidic, proline-rich region (pI = 4) involving the amino-terminal 80 residues from 828 to 908 and a basic region (pI = 8.8) that extends from 898 to 1386. The amino-terminal 70 amino acids of the spectrin-binding domain are critical for association with spectrin, since a subfragment missing this region is only 5% as active as the intact domain in displacing binding of spectrin to inside-out membrane vesicles, while deletion of the first 38 residues of the acidic domain results in a 10-fold reduction in activity. The anion exchanger-binding site is confined to an 89-kDa domain that was isolated and characterized as a globular molecule with approximately 30% alpha-helical configuration. A subfragment of the 89-kDa domain extending from residues 403 to 779 (or possibly 740) retains ability to associate with the anion exchanger. The 89-kDa domain is comprised of a series of tandem repeats of 33 amino acids that extend from residues 35 to 778 (Lux, S., John, K., and Bennett, V. (1990) Nature 344, 36-42). The activity of residues 403-779 demonstrates that the 33-amino acid repeats of the 89-kDa domain are responsible for association between ankyrin and the anion exchanger. The 33-amino acid repeating sequence of ankyrin represents an ancient motif also found in proteins of Drosophila, yeast, and Caenor habditis elegans. The finding that the 33-amino acid repeating sequence is involved in interaction with the anion exchanger implies that this motif may perform a role in molecular recognition in diverse proteins.     

The structural basis of ankyrin function. II. Identification of two functional domains

Human erythrocyte ankyrin was cleaved by restricted proteolysis at 0 degrees C into two distinct chemical domains. The site on ankyrin that binds spectrin was found to be within a 55,000-dalton domain by spectrin affinity chromatography and co-sedimentation with spectrin in a sucrose gradient. A 32,000-dalton fragment of this domain was prepared (tryptic digest, 0 degrees C, 24 h), separated by gel filtration, and shown to inhibit spectrin binding to the membrane. By comparison with previous two-dimensional peptide maps, the spectrin-binding site was located within this 32,000-dalton fragment near the end of the molecule. The band 3-binding site was identified within an 82,000-dalton domain by binding to a band 3 affinity column. Gel electrophoresis in the absence of detergents confirmed these results and demonstrated that a peptide from the cytoplasmic portion of band 3 retained the capacity to bind the 82,000-dalton domain. The binding properties of the structural domains of ankyrin were correlated with a determination of the affinity constant of the intact molecule. Ankyrin bound with a high affinity to the cytoplasmic portion of band 3 (KD = 8 X 10(-8) M) and to spectrin tetramer (KD = 1 X 10(-7) M) but less so to spectrin dimer (KD = 1 X 10(-6) M). These findings are summarized in a preliminary structural and functional model of ankyrin's role in linking spectrin to the membrane.