Spectrin promotes the association of F-actin with the cytoplasmic surface of the human erythrocyte membrane

We studied the binding of actin to the erythrocyte membrane by a novel application of falling ball viscometry. Our approach is based on the notion that if membranes have multiple binding sites for F-actin they will be able to cross-link and increase the viscosity of actin. Spectrin- and actin-depleted inside-out vesicles reconstituted with purified spectrin dimer or tetramer induce large increases in the viscosity of actin. Comparable concentrations of spectrin alone, inside-out vesicles alone, inside-out vesicles plus heat-denatured spectrin dimmer or tetramer induce large increases in the viscosity of actin. Comparable concentrations of spectrin alone, inside-out vesicles alone, inside-out plus heat denatured spectrin, ghosts, or ghosts plus spectrin have no effect on the viscosity of actin. Centrifugation experiments show that the amount of actin bound to the inside-out vesicles is enhanced in the presence of spectrin. The interactions detected by low-shear viscometry reflect actin interaction with membrane- bound spectrin because (a) prior removal of band 4.1 and ankyrin (band 2.1, the high- affinity membrane attachment site for spectrin) reduces both spectrin binding to the inside-out vesicles and their capacity to stimulate increase in viscosity of actin in the presence of spectrin + actin are inhibited by the addition of the water-soluble 72,000- dalton fragment of ankyrin, which is known to inhibit spectrin reassociation to the membrane. The increases in viscosity of actin induced by inside-out vesicles reconstituted with purified spectrin dimer or tetramer are not observed when samples are incubated at 0 degrees C. This temperature dependence may be related to the temperature-dependent associations we observe in solution studies with purified proteins: addition of ankyrin inhibits actin cross-linking by spectrin tetramer plus band 4.1 at 0 degrees C, and enhances it at 32 degrees C. We conclude (a) that falling ball viscometry can be used to assay actin binding to membranes and (b) that spectrin is involved in attaching actin filaments or oligomers to the cytoplasmic surface of the erythrocyte membrane.     

Shear-response of the spectrin dimer-tetramer equilibrium in the red blood cell membrane

The red cell membrane derives its elasticity and resistance to mechanical stresses from the membrane skeleton, a network composed of spectrin tetramers. These are formed by the head-to-head association of pairs of heterodimers attached at their ends to junctional complexes of several proteins. Here we examine the dynamics of the spectrin dimer-dimer association in the intact membrane. We show that univalent fragments of spectrin, containing the dimer self-association site, will bind to spectrin on the membrane and thereby disrupt the continuity of the protein network. This results in impairment of the mechanical stability of the membrane. When, moreover, the cells are subjected to a continuous low level of shear, even at room temperature, the incorporation of the fragments and the consequent destabilization of the membrane are greatly accentuated. It follows that a modest shearing force, well below that experienced by the red cell in the circulation, is sufficient to sever dimer-dimer links in the network. Our results imply 1) that the membrane accommodates the enormous distortions imposed on it during the passage of the cell through the microvasculature by means of local dissociation of spectrin tetramers to dimers, 2) that the network in situ is in a dynamic state and undergoes a "breathing" action of tetramer dissociation and re-formation.     

Formation and properties of spectrin containing a truncated beta-chain, generated by an endogenous calcium-dependent protease

Spectrin chromatographically isolated from human red cell membranes contains a proteolytic activity, inhibited by leupeptin, with a dependence on calcium ions characteristic of a calpain I. The activity accompanies the spectrin on two successive gel filtration columns and is present in both the dimer and the tetramer. It is cryptic in the ghost membrane and in purified membrane skeletons until these are dissociated, apparently because the spectrin is resistant to attack in the tetrameric state. The activity is more strongly expressed in spectrin preparations from young than from old cells. Since the bound enzyme does not detectably change the elution volume of spectrin in gel filtration, it is likely that its molecular weight is low. Its activity reveals itself only in the formation of a modified spectrin, lacking the COOH-terminal, phosphorylated portion of the beta-chain. The phosphorylated fragment (15-20 kDa) can be identified by gel electrophoresis. The proteolytically modified spectrin dimers are unable to associate with like molecules, but are univalent with respect to formation of hybrid tetramers with native spectrin. The association constant for this process is lower than that for self-association of native spectrin by a factor of only 2. The proteolytically modified spectrin behaves similarly in this respect to a truncated spectrin mutant found in a form of hereditary elliptocytosis. The latter also resembles the proteolytic product in that both give rise to the same altered NH2-terminal tryptic fragment from the alpha-chain.     

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.     

Analysis of the self-association of human red cell spectrin

The self-association equilibrium of spectrin has been studied by separating the molecular species present in the cooled reaction mixture by gel electrophoresis. The association constant for formation of the hexamer from dimer and tetramer is lower by an order of magnitude than that for the association of two dimers. The association constant for the formation of the octamer from the hexamer is appreciably larger, and the value appears to reach a constant level for higher oligomers. These observations are explained in terms of conformational strain due to formation of cyclic structures, the distortion being greatest on passing from the tetramer to the hexamer. The association for a single-site interaction between the dimer and a univalent fragment has also been analyzed. The results show that the free energy generated by a single-point interaction is much greater than that obtained by averaging over all pairwise interactions within the oligomers, correcting for the effect of cratic entropy. The results are related to the association state of the spectrin prevailing in the cell. Phosphorylation at the physiological sites in the dimer does not appreciably change the thermodynamics of self-association, at least up to the hexamer.     

Osmotic Stress Alters the Intracellular Distribution of Non-erythroidal Spectrin (Fodrin) in Bovine Aortic Endothelial Cells

Cell swelling is known to result in unfolding of membrane invaginations and restructuring of F-actin. The effect of cell swelling on the intracellular distributions of other cytoskeletal proteins that constitute the submembrane cortical cytoskeleton is virtually unknown. This study focuses on the effects of cell swelling on non-erythroidal spectrin (fodrin, also known as spectrin II), a predominant component of the membrane cytoskeleton. The intracellular distribution of spectrin in vascular endothelial cells was studied by optical sectioning using a 3-D deconvolution microscopy system. Our results show that once bovine aortic endothelial cells (BAECs) reach confluency, the non-erythroidal spectrin is localized in the submembrane regions of the cells. Analysis of the intensity profiles of the non-erythroidal spectrin under isotonic and hypotonic conditions show that: (a) the width of the submembrane spectrin staining increases gradually with time within the first 5 minutes after the osmotic shock; (b) significant recovery is observed after 10 minutes even if the cells are maintained in hypotonic medium, and (c) spectrin distribution is altered by disrupting F-actin with latrunculin A but not by stabilizing F-actin with jasplakinolide. We suggest that cell swelling results in partial translocation of the submembrane spectrin to the cytosol and that it may play a major role in initiation of swelling-induced cellular events.     

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.     

Restriction of the lateral motion of band 3 in the erythrocyte membrane by the cytoskeletal network: dependence on spectrin association state

The effects of incubation of erythrocyte ghosts under various conditions (ionic strength or addition of ankyrin, diamines, or ATP) on the lateral motion of band 3 in the membranes were studied by using the fluorescence photobleaching recovery technique. Incubation of ghosts with exogenous ankyrin increased the immobile fraction of band 3, from 0.6 in intact ghosts to 0.8-0.9 when an average of 0.2 mol of extra ankyrin was bound per mole of band 3. Ankyrin-free band 3 proteins were mobile, but their mobility was governed by the spectrin association state in the cytoskeletal network. The diffusion constant was 5.3 X 10(-11) cm2 s-1 at a spectrin tetramer mole fraction of 0.3-0.4 in 10 mM NaCl/5 mM sodium phosphate, pH 7.8, and decreased 1 order of magnitude when the tetramer fraction increased to 0.5 in higher NaCl concentration (150 mM NaCl). A similar decrease was observed when the spectrin tetramer fraction was increased by 0.2 mM spermine in 10 mM NaCl/10 mM tris(hydroxymethyl)aminomethane hydrochloride, pH 7.6. On the other hand, the rotational motion of band 3 in the membranes was not affected by the spectrin association state. Trypsin treatment of ghosts cleaved off the cytoplasmic domain of band 3 and caused a marked (8-fold) increase in the lateral mobility, D = 4.0 X 10(-10) cm2 s-1. These results indicate that the lateral mobility of ankyrin-free band 3 protein is restricted by interactions of their cytoplasmic domain with the cytoskeletal network. A model is presented that band 3 can pass the network when spectrins are in dissociated dimers and cannot pass when they are tetramers. The lateral diffusion constant is thus determined by the spectrin dimer population in the network.     

An immunochemical approach for the analysis of membrane protein alterations in Ca2+-loaded human erythrocytes

An increase in the intracellular concentration of Ca²⁺ in human erythrocytes results in the formation of γ-glutamyl-?-lysine cross-linked membrane protein polymers. Following solubilization of the membranes with SDS, these polymers can be isolated on a Lubrol-containing sucrose gradient. Immunoelectrophoresis of the polymeric material with a polyspecific rabbit antibody against human ghosts gave rise to a single, but heterogeneous, precipitate. The polymer was amphiphilic and, on addition to Triton-solubilized erythrocyte membrane proteins, it coprecipitated with spectrin. When the antighost antibody was absorbed with the polymer prior to cross immunoelectrophoresis of normal erythrocyte membrane proteins, the precipitates of glycophorin, acetylcholinesterase, and hemoglobin were normal, whereas the anti-body liters against band 3 protein, spectrin, and ankyrin became reduced. Furthermore, a rabbit antibody raised against the isolated human polymer reacted selectively with the same three membrane proteins. No reactions occurred with lysate proteins.     

Phosphorylation of ankyrin down-regulates its cooperative interaction with spectrin and protein 3

Ankyrin mediates the primary attachment between beta spectrin and protein 3. Ankyrin and spectrin interact in a positively cooperative fashion such that ankyrin binding increases the extent of spectrin tetramer and oligomer formation (Giorgi and Morrow: submitted, 1988). This cooperative interaction is enhanced by the cytoplasmic domain of protein 3, which is prepared as a 45-41-kDa fragment generated by chymotryptic digestion of erythrocyte membranes. Using sensitive isotope-ratio methods and nondenaturing PAGE, we now demonstrate directly (1) the enhanced affinity of ankyrin for spectrin oligomers compared to spectrin dimers; (2) a selective stimulation of the affinity of ankyrin for spectrin oligomer by the 43-kDa cytoplasmic domain of protein 3; and (3) a selective reduction in the affinity of ankyrin for spectrin tetramer and oligomer after its phosphorylation by the erythrocyte cAMP-independent membrane kinase. The phosphorylation of ankyrin does not affect its binding to spectrin dimer. Ankyrin also enhances the rate of interconversion between dimer-tetramer-oligomer by 2-3-fold at 30 degrees C, and in the presence of the 43-kDa fragment, ankyrin stimulates the rate of oligomer interconversions by nearly 40-fold at this temperature. These results demonstrate a long-range cooperative interaction between an integral membrane protein and the peripheral cytoskeleton and indicate that this linkage may be regulated by covalent protein phosphorylation. Such interactions may be of general importance in nonerythroid cells.     

Hemin-promoted peroxidation of red cell cytoskeletal proteins

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

Structural and functional analysis of spectrin from neonatal erythrocytes

Spectrin was purified by rate zonal sedimentation from low-salt extracts of red cell membranes from neonatal and adult blood. Neonatal and adult spectrin cosedimented in sucrose density gradients, comigrated on SDS gels and displayed identical two-dimensional chymotryptic 125I-labelled peptide maps. Neonatal spectrin and adult spectrin exhibited equivalent affinity for both neonatal and adult ankyrin sites on spectrin-depleted inverted membrane vesicles. Purified spectrin heterodimers from neonatal and adult red cells displayed similar self-association equilibrium constants in a fluid phase dimer-dimer association assay. These results suggest that the unique membrane characteristics of the neonatal erythrocyte are not due to a structural or functional alteration of spectrin. Several alternative hypotheses involving other membrane proteins and their linkages are discussed.     

The self-association of ovine erythrocyte spectrin

• 1.1. Spectrin extracted from ovine erythrocyte membranes at low temperature shows association behaviour similar to that reported for human and bovine erythrocytes.
• 2.2. The spectrin tetramer is the predominant oligomer, the dimer is well represented, and smaller amounts of hexamer and higher oligomers are present.
• 3.3. The estimates of parameters describing the self-association of purified ovine spectrin studied by sedimentation equilibrium analysis were found to be indistinguishable from those obtained for human spectrin under the same conditions, within the precision of the measurements.
• 4.4. The data suggest that the cooperative isodesmic model may be general for spectrin, and not a peculiarity of the human

.     

Interaction of spectrin with hemin disaggregates spectrin associations

Crude spectrin preparations were extracted from red cell membranes either in dimeric or tetrameric forms and incubated at 4 degrees C with hemin. The mixtures were subjected immediately or after 18 hours to nondenaturing electrophoresis. It was found that immediately after addition of 0.3 mM hemin, the fraction of spectrin complexed with other skeletal proteins, disaggregated to tetramer and dimer forms. After incubation for 18 hours at 4 degrees C most of the spectrin appeared in two additional bands which contained more hemin and migrated on the gels as molecular weight forms smaller than the dimers. Since SDS electrophoresis showed that spectrin subunits retained their integrity in these mixtures, it was concluded that hemin bound spectrin dissociates with time into monomers. It is suggested that there are pathophysiological implications to the disaggregation of spectrin complexes in the cytoskeleton by hemin.     

In vitro proteolysis of brain spectrin by calpain I inhibits association of spectrin with ankyrin-independent membrane binding site(s).

This report demonstrates that specific proteolysis of brain spectrin by a calcium-dependent protease, calpain I, abolishes association of brain spectrin with the ankyrin-independent binding site(s) in brain membranes. Calpain I cleaves the beta subunit of spectrin at the N-terminal end leaving a 218-kDa fragment and cleaves the alpha subunit in the midregion to produce 150- and 130-kDa fragments. Calpain-proteolyzed spectrin almost completely loses the capacity to displace binding of intact spectrin to membranes. Spectrin digested by calpain I under conditions that almost completely destroyed membrane-binding remained associated as a tetramer and retained about 60% of the ability to associate with actin filaments. Cleavage of spectrin occurred at sites distinct from the membrane-binding site which is located on the beta subunit since the isolated 218-kDa fragment of the beta subunit as well as a reconstituted complex of alpha and 218-kDa beta subunit fragment partially regained binding activity. Moreover, cleavage of the alpha subunit alone reduced the affinity of spectrin for membranes by 2-fold. A consequence of distinct sites for calpain I cleavage and membrane-binding is that calpain I can digest spectrin while spectrin is complexed with other proteins and therefore has the potential to mediate disassembly of a spectrin-actin network from membranes.     

Self-assembly of spectrin oligomers in vitro: a basis for a dynamic cytoskeleton

Purified human erythrocyte spectrin is able to form large oligomeric species without the collaboration of any other proteins. This reversible self-assembly process is both temperature and concentration dependent and seems to be mediated by the same kinds of low affinity noncovalent associations between spectrin monomers that promote tetramer formation. Low ionic strength extracts of erythrocyte membranes also contain these oligomeric species. These results support the idea that spectrin oligomers and the factors that regulate their formation may be responsible for both the stability and the versatility of the erythrocyte membrane cytoskeleton. It is postulated that the high concentrations of spectrin necessary for oligomerization are maintained in vivo by a high-affinity interaction with ankyrin. Such a coupling of high and low affinity interactions in multifunctional proteins may have significant implications for membrane structure and function.     

Tryptophan phosphorescence study of the internal dynamics of human erythrocyte membrane proteins upon spectrin modification

Room-temperature tryptophan phosphorescence has been used analyze the slow (millisecond) internal dynamics of proteins in isolated native human erythrocyte membranes, after removal of 95% of spectrin, and after thermal denaturation of spectrin or medium acidification to pH 6.0–4.0, as well as the internal dynamics of spectrin extracted from the membrane in solution. The integral membrane proteins prove to differ sharply from spectrin in their structural and dynamic state. The millisecond movements of structural elements in integral proteins are considerably hindered as compared with spectrin. Removal of the bulk of spectrin from membranes leads to amplification of slow fluctuations in the structure of integral proteins. This suggests involvement of spectrin in the control of the structural and dynamic state of the erythrocyte membrane proteins. The acidification of the medium to pH 6.0–4.0 decreases the internal dynamics of native membrane proteins, which is explained by the pH-induced aggregation of spectrin. After thermal denaturation of spectrin, there is no pH-induced increase in the rigidity of the structure of membrane proteins.     

The isolation of aggregates of spectrin from bovine erythrocyte membranes.

Aggregated states of spectrin from bovine erythrocyte membranes can be detected in sedimentation velocity experiments. These aggregates have been isolated by means of gel filtration on columns of 4% agarose. They appear to be stable over a wide range of pH and ionic strength, although they are dissociated by sodium dodecyl sulphate. Sedimentation equilibrium measurements yielded values of 960 000 and 480 000 for the molecular weights of the major aggregates, corresponding to a tetramer and dimer, respectively. The presence of different aggregated states in spectrin preparations may explain the wide variation in the reported physical properties of spectrin.     

Association of spectrin with its membrane attachment site restricts lateral mobility of human erythrocyte integral membrane proteins

Interactions between spectrin and the inner surface of the human erythrocyte membrane have been implicated in the control of lateral mobility of the integral membrane proteins. We report here that incubation of “leaky” erythrocytes with a water-soluble proteolytic fragment containing the membrane attachment site for spectrin achieves a selective and controlled dissociation of spectrin from the membrane, and increases the rate of lateral mobility of fluorescein isothiocyanate-labeled integral membrane proteins (> 70% of label in band 3 and PAS-1). Mobility of membrane proteins is measured as an increase in the percentage of uniformly fluorescent cells with time after fusion of fluorescent with nonfluorescent erythrocytes by Sendai virus. The cells are permeable to macromolecules since virus-fused erythrocytes lose most of their hemoglobin. The membrane attachment site for spectrin has been solubilized by limited proteolysis of inside-out erythrocyte vesicles and has been purified (V). Bennett, J Biol Chem 253:2292 (1978). This 72,000-dalton fragment binds to spectrin in solution, competitively inhibits association of ³²P-spectrin with inside-out vesicles with a K_i of 10^?7M, and causes rapid dissociation of ³²P-spectrin from vesicles. Both acid-treated 72,000-dalton fragment and the 45,000 dalton-cytoplasmic portion of band 3, which also was isolated from the proteolytic digest, have no effect on spectrin binding, release, or membrane protein mobility. The enhancement of membrane protein lateral mobility by the same polypeptide that inhibits binding of spectrin to inverted vesicles and displaces spectrin from these vesicles provides direct evidence that the interaction of spectrin with protein components in the membrane restricts the lateral mobility of integral membrane proteins in the erythrocyte.     

Phosphorylation and dephosphorylation of spectrin

The phosphorylation of spectrin polypeptide 2 is thought to be involved in the metabolically dependent regulation of red cell shape and deformability. Spectrin phosphorylation is not affected by cAMP. The reaction in isolated membranes resembles the cAMP-independent, salt-stimulated phosphorylation of an exogenous substrate, casein, by enzyme(s) present both in isolated membranes and cytoplasmic extracts. Spectrin kinase is selectively eluted from membranes by 0.5 M NaCl and co-fractionates with eluted casein kinase. Phosphorylation of band 3 in the membrane is inhibited by salt, but the band 3 kinase is otherwise indistinguishable operationally from spectrin kinase. The membrane-bound casein (spectrin) kinase is not eluted efficiently with spectrin at low ionic strength; about 80% of the activity is apparently bound at sites (perhaps on or near band 3) other than spectrin. Partitioning of casein kinase between cytoplasm and membrane is metabolically dependent; the proportion of casein kinase on the membrane can range from 25% to 75%, but for fresh cells is normally about 40%. Dephosphorylation of phosphorylated spectrin has not been studied intensively. Slow release of ³²Pi from [³²P] spectrin on the membrane can be demonstrated, but phosphatase activity measured against solubilized [³²P] spectrin is concentrated in the cytoplasm. The crude cytoplasmic phosphospectrin phosphatase is inhibited by various anions – notably, ATP and 2,3-DPG at physiological concentrations. Regulation of spectrin phosphorylation in intact cells has not been studied. We speculate that spectrin phosphorylation state may be regulated (1) by metabolic intermediates and other internal chemical signals that modulate kinase and phosphatase activities per se or determine their intracellular localization and (2) by membrane deformation that alters enzyme–spectrin interaction locally. Progress in the isolation and characterization of spectrin kinase and phosphospectrin phosphatase should lead to the resolution of major questions raised by previous work: the relationships between membrane-bound and cytoplasmic forms of the enzymes, the nature of their physical interactions with the membrane, and the regulation of their activities in defined cell-free systems.