Membrane protein organization in ATP-depleted and irreversibly sickled red cells

It has been proposed that the spectrin-actin submembrane network participates in control of red cell shape and deformability. We have examined ATP- and calcium-dependent changes in organization of spectrin in the membrane employing cross-linking of the nearest membrane protein neighbors by spontaneous or catalyzed (CuSO₄, O-phenanthroline) intermolecular disulfide couplings and two-dimensional sodium dodecyl sulfate polyacrylamide gel electrophoresis. Cross-linking of fresh red cells resulted in the formation of spectrin and actin dimers and tetramers. ATP-depleted red cells differed from fresh cells in the presence of an additional reducible polymer of MW > 1 × 10⁶ selectively enriched in spectrin. This polymer formed spontaneously when red cells were depleted of ATP under aerobic conditions. After anaerobic ATP depletion, the polymer formed in ghosts after cross-linking by catalytic oxidation. Polymerization was prevented by maintenance of ATP and coincided with an ATP-dependent discocyte-echinocyte transformation. This suggests that, in ATP-depleted red cells, spectrin is rearranged to establish closer contacts, and that this may contribute to the discocyte-echinocyte transformation. The introduction of greater than 0.5 mM Ca⁺⁺ into ghosts by inclusion in hemolysis buffer or into fresh red cells (but not ATP-depleted red cells) by treatment with ionophore A23187 spontaneously produced a nonreducible polymer which others have attributed to transamidative cross-linking of spectrin, band 3, and other proteins. Spontaneous formation of both polymer types (reducible in aerobically ATP-depleted red cells and nonreducible in fresh, Ca⁺⁺ enriched red cells) resulted in stabilization (“autocatalytic fixation”) of spheroechinocytic shape. Irreversibly sickled cells, which have increased calcium and decreased ATP, and exhibit a permanent membrane deformation, failed to form any of the above polymers. This suggests that in contrast to normal cells depleted of ATP in vitro, fixation of ISC shape in vivo is not related to Ca- and ATP-dependent membrane protein polymerization. However, ISCs had an increased propensity to form the reducible, spectrin-rich polymer during a subsequent metabolic depletion in vitro. This was associated with transformation of ISCs into spheroechinocytes. Similar echinocytic ISCs were found to constitute 5–10% of the densest fractions of freshly separated ISCs. ISCs then exhibit sphero-echniocyte transformation, both in vitro and in vivo. We propose that this is due to spectrin reorganization that presumably results from the progressively increasing calcium and decreasing ATP of ISCs. These data provide evidence of altered spectrin organization in membranes of ATP-depleted, calcium-enriched red cells in vitro and in vivo.     

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.     

Two-dimensional separation of erythrocyte membrane proteins.

The details of a two-dimensional separation procedure specially designed for the study of erythrocyte membranes are presented. In this highly reproducible method, the membrane proteins are dissolved in sodium dodecyl sulfate and separated first on the basis of charge by isoelectric focusing. The samples are loaded either at the cathode (CIF) or anode (AIF). The CIF samples gave better separation of the acidic proteins, while the AIF was better for the separation of the high molecular weight polypeptides of the erythrocyte. Over 90 discrete polypeptides could be detected with this method in the pH range of 5 to 8. Special attention was given to the higher molecular weight components. For example, six components could be detected within the 90,000 to 100,000 molecular weight range of protein 3, the major membrane protein. A component with the same or very nearly the same molecular weight as spectrin band 2 was detected. It is more basic than spectrin band 2, and both spectrin band 2 and the basic component are readily phosphorylated in the intact cell. However, the phosphorylation of band 2 is cAMP independent while the phosphorylation of the basic component is enhanced by cAMP. In contrast to spectrin, the basic component is not extracted from the membrane with 0.1 mm EDTA, although dilute NaOH will remove it from the membrane. The Ca²⁺-activated transferase of the erythrocyte cytoplasm will not crosslink this component. Calcium does, however, activate the conversion of this component to a lower molecular weight. This high molecular weight basic component has properties attributed to the component labeled 2.1 in Fairbanks' system of nomenclature.     

The Use of Ascorbate as a Probe of Opioid Receptor Structure: Evidence for two Independent Mechanisms of Receptor Destruction by Ascorbate

Abstract

Ascorbate (20 mM) pretreatment of brain membrane suspensions at 37° produced a rapid irreversible loss of specific opioid binding. There was no reduction in specific ³H-haloperidol binding. Ascorbate induced loss of opioid binding under these experimental conditions was not blocked by low concentrations of EDTA or Mn⁺⁺. In contrast, the slowly developing loss of opioid binding during exposure to 1 mM ascorbate at 23° was completely inhibited by 10^?5M EDTA or Mn⁺⁺. At 37°, D-isoasoorbate, and several other reducing agents (glutathione, dithiothreitol, oysteine) produced a loss of opioid binding similar to that seen with ascorbate. It is concluded that 1 mM ascorbate at 23°, and 20 mM ascorbate at 37°, destroy opioid binding sites by two independent mechanisms. Lipid peroxidation is implicated at low ascorbate concentrations; a reductive process appears to be responsible for the ascorbate induced loss of binding at higher concentrations.     

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.     

Integral membrane protein interaction with Triton cytoskeletons of erythrocytes

The organization of erythrocyte membrane lipids and proteins has been studied following the release of cytoplasmic components with the non-ionic detergent Triton X-100. After detergent extraction, a detergent-resistant complex called the erythrocyte cytoskeleton is separated from detergent, solubilized lipid and protein by sucrose buoyant density sedimentation. In cytoskeletons prepared under isotonic conditions all of the major erythrocyte membrane proteins are retained except for the integral protein, glycophorin, which is quantitatively solubilized and another integral glycoprotein, band 3, which is only 60% removed. When cytoskeletons are prepared in hypertonic KCl solutions, band 3 is fully solubilized along with bands 2.1 and 4.2 and several minor components. The resulting cytoskeletons have the same morphology as those prepared in isotonic buffer but they are composed of only three major peripheral proteins, spectrin, actin and band 4.1. We have designated this peripheral protein complex the 'shell' of the erythrocyte membrane, and have shown that the attachment of band 3 to the shell satisfies the criteria for a specific interaction. Although Triton did affect erythrocyte shape, cytoskeleton lipid content and the activity of membrane proteases, there was no indication that Triton altered the attachment of band 3 to the shell. We suggest that band 3 attaches to the shell as part of a ternary complex of bands 2.1, 3 and 4.2.     

On the mechanism of ATP-induced shape changes in the human erythrocyte membranes: the role of ATP

In the preceding paper (Sheetz, M. and S.J. Singer. 1977. J Cell Biol. 73:638-646) it was shown that erythrocyte ghosts undergo pronounced shape changes in the presence of mg-ATP. The biochemical effects of the action of ATP are herein examined. The biochemical effects of the action of ATP are herein examined. Phosphorylation by ATP of spectrin component 2 of the erythrocyte membrane is known to occur. We have shown that it is only membrane protein that is significantly phosphorylated under the conditions where the shape changes are produced. The extent of this phosphorylation rises with increasing ATP concentration, reaching nearly 1 mol phosphoryle group per mole of component 2 at 8mM ATP. Most of this phosphorylation appears to occur at a single site on the protein molecule, according to cyanogen bromide peptide cleavage experiments. The degree of phosphorylation of component 2 is apparently also regulated by a membrane-bound protein phosphatase. This activity can be demonstrated in erythrocyte ghosts prepared from intact cells prelabeled with [(32)P]phosphate. In addition to the phosphorylation of component 2, some phosphorylation of lipids, mainly of phosphatidylinositol, is also known to occur. The ghost shape changes are, however, shown to be correlated with the degree of phosphorylation of component 2. In such experiment, the incorporation of exogenous phosphatases into ghosts reversed the shape changes produced by ATP, or by the membrane-intercalating drug chlorpromazine. The results obtained in this and the preceding paper are consistent with the proposal that the erythrocyte membrane possesses kinase and phosphates activities which produce phosphorylation and dephosphorylation of a specific site on spectrin component 2 molecules; the steady-state level of this phosphorylation regulates the structural state of the spectrin complex on the cytoplasmic surface of the membrane, which in turn exerts an important control on the shape of the cell.     

Human erythrocyte spectrin: Phosphorylation in intact cells and purification of the 32P-labeled protein in a non-aggregated state

[³²P]spectrin (0.5 Ci/mMole) has been isolated from human erythrocytes incubated with ³²Pi and purified to homogeneity by preparative rate zonal sedimentation on linear sucrose gradients. ³²P-label, localized in band 2, co-elutes with spectrin from ghosts with a similar dependence on ionic strength and Mg⁺⁺ ion, and has the same sedimentation coefficient and an identical effective Stokes radius. [³²P]spectrin reassociates in a specific manner with spectrin-depleted membranes. Bands 1 and 2 bind in equal ratios, and the ³²P-label is distributed with band 2. Purified [³²P]spectrin is not aggregated since this protein migrates as a symmetrical peak on Sepharose(C1)4B at about 1.6 Vo and sediments at 8S_20,w on sucrose gradients.     

Characterization of human erythrocyte cytoskeletal ATPase

Human erythrocyte cytoskeletal ATPase was extracted with 0.2 mM ATP (pH 8.0) from Triton X-100 treated ghosts. The ATPase fraction contained mainly spectrin, actin, and band 4.1. When the ATPase fraction was applied to a Sepharose 4B column, 90% of the ATPase activity was recovered in a spectrin, actin, and band 4.1 complex fraction and none was detected in the spectrin fraction. A specific activity of the complex ATPase was 60-120 nmol/(mg protein X h). No ATPase activity was detected in the presence of EDTA. The presence of magnesium in the incubation medium was essential for the ATPase activity. The activity was activated by KCl and was almost completely inhibited by 10(-5) M free calcium in the presence of 0.2 mM MgCl2. The Ki for Ca2+ was 7 X 10(-7) M. Phalloidin and DNase 1, which affect actin, inhibited this K,Mg-ATPase activity by 95%, but cytochalasin B did not inhibit it. N-Ethylmaleimide activated the ATPase 1.6-fold. The order of affinity for nucleotides was ATP greater than ITP greater than CTP, ADP, AMP-PNP, GTP. A specific ATPase activity of purified actin was 50 nmol/(mg X h). These results suggest that the cytoskeletal ATPase is actin ATPase and the actin ATPase is activated by spectrin and band 4.1.     

Selective association of spectrin with the cytoplasmic surface of human erythrocyte plasma membranes. Quantitative determination with purified (32P)spectrin.

A specific association between spectrin and the inner surface of the human erythrocyte membrane has been examined by measuring the binding of purified [32P]spectrin to inside out, spectrin-depleted vesicles and to right side out ghost vesicles. Spectrin was labeled by incubating erythrocytes with 32Pi, and eluted from the ghost membranes by extraction in 0.3 mM NaPO4, pH 7.6. [32P]Spectrin was separated from actin and other proteins and isolated in a nonaggregated state as a So20,w = 7 S (in 0.3 mM NaPO4) or So20,w = 8 S (in 20 mM KCl, 0.3 mM NaPO4) protein after sedimentation on linear sucrose gradients. Binding of [32P]spectrin to inverted vesicles devoid of spectrin and actin was at least 10-fold greater than to right side out membranes, and exhibited different properties. Association with inside out vesicles was slow, was decreased to the value for right side out vesicles at high pH, or after heating spectrin above 50 degrees prior to assay, and was saturable with increasing levels of spectrin. Binding to everted vesicles was rapid, unaffected by pH or by heating spectrin, and rose linearly with the concentration of spectrin. Scatchard plots of binding to inverted vesicles were linear at pH 7.6, with a KD of 45 microng/ml, while at pH 6.6, plots were curvilinear and consistent with two types of interactions with a KD of 4 and 19 microng/ml, respectively. The maximal binding capacity at both pH values was about 200 microng of spectrin/mg of membrane protein. Unlabeled spectrin competed for binding with 50% displacement at 27 microng/ml. [32P]Spectrin dissociated and associated with inverted vesicles with an identical dependence on ionic strength as observed for elution of native spectrin from ghosts. MgCl2, CaCl2 (1 to 4 mM) and EDTA (0.5 to 1 mM) had little effect on binding in the presence of 20 mM KCl, while at low ionic strength, MgCl2 (1 mM) increased binding and inhibited dissociation to the same extent as 10 to 20 mM KCl. Binding was abolished by pretreatment of vesicles with 0.1 M acetic acid, or with 0.1 microng/ml of trypsin. The periodic acid-Schiff-staining bands were unaffected by trypsin digestion which destroyed binding; mild digestion, which decreased binding only 50%, converted Band 3 almost completely to a membrane-bound 50,000-dalton fragment resistant to further proteolysis. These experiments suggest that attachment of spectrin to the cytoplasmic surface of the membrane results from a selective protein-protein interaction which is independent of erythrocyte actin. A direct role of the major sialoglycoprotein or Band 3 as a membrane binding site appears unlikely.     

Factors affecting the relative magnitudes of the ouabain-sensitive and the ouabain-insensitive fluxes of thallium ion in erythrocytes

A maximal rate of the ouabain-sensitive 204-Tl influx in human erythrocytes can be attained at trace concentrations of Tl+ in Mg2+ isotonic media free of K+ and Na+. The maximal influx of Tl+ from isotonic Mg(NO3)2 at 20 degrees C and pH 7.4 was 0.45 mM.l(-1).h-1 with a Km of 0.025 mM. In contrast to the active influx of Tl+, the passive Tl+ fluxes were neither saturated nor influenced by external cations in the range of concentrations of Tl+ and K+ studied. The rate constants of Tl+ passive fluxes in human and cat erythrocytes can be related to pH by the equation log kin(OUT)= -A + B.pH, where A and B are empirical constants for particular conditions. The apparent activation energy was 16 and 11 kcal/mol in sulphate and nitrate media, respectively. Tl+ and the alkali metal cations seem to overcome a common barrier in the erythrocyte membrane. Nevertheless, the rate of the passive penetration of Tl+ is about two orders of magnitude faster than those of K+ or Rb+. An extra non-Coulombic interaction between Tl+ and membrane ligands appears to be involved providing an accumulation of Tl+ somewhere in the vicinity of the membrane barrier and increasing the diffusion fluxes of Tl+ in both directions.     

Formation of γ-glutamyl-ϵ-lysine bridges between membrane proteins by a Ca2+-regulated enzyme in intact erythrocytes

A rise in the intracellular concentration of Ca²⁺-ions in human erythrocytes causes the formation of high-molecular-weight membrane protein polymers, cross-linked by γ-glutamyl-?-lysine side chain bridges. Cross-linking involves proteins at the cytoplasmic side of the membrane (band 4.1, spectrin, and band 3 materials) and the reaction is catalyzed by the intrinsic transglutaminase. This enzyme is regulated by Ca²⁺-ions and it exists in a latent form in normal cells. The protein polymer, isolated from the membranes of Ca²⁺-loaded intact human red cells, is heterogeneous in size and may contain as many as 6 moles of γ-glutamyl-?-lysine cross-links per 100,000 gm of protein. Synthetic compounds, which either compete against the ?-lysine cross-linking functionalities of the protein substrates (eg, histamine, aminoacetonitrile, cystamine) or directly inactivate the transamidase (eg, cystamine), inhibit the membrane polymerization reaction in intact human erythrocytes. They also interfere with the Ca²⁺-induced irreversible shape change from discocyte to echinocyte and inhibit the irreversible loss of membrane deformability. Thus, the transamidase-catalyzed production of γ-glutamyl-?-lysine cross-links in the membrane may be a common denominator in these cellular manifestations.     

Ion and pH gradients across the transport membrane of mitochondria following Mn ++ uptake in the presence of acetate

The electron paramagnetic resonance (EPR) spectrum of Mn⁺⁺ loaded mitochondria is affected by the presence of the permeant anion acetate (Ac^?) in the medium. The hyperfine sextet, shown earlier to have spectral characteristics like those expected of osmotically active Mn⁺⁺ in the matrix space, grows in intensity with increasing [Ac^?]. From estimates of mitochondrial water, the free internal [Mn⁺⁺] can be calculated. The gradient of free [Mn⁺⁺] across the inner mitochondrial membrane is believed to be at least 500:1 under conditions of high [Ac^?]. Since Mn⁺⁺ solubility is limited by [OH^?], it is possible to place an upper limit on the pH in the matrix space. The variation of free internal [Mn⁺⁺], as measured by EPR, with external pH indicates that the [H⁺] gradient is 1–1.5 pH units in the absence of permeant anions and considerably less in the presence of 100 mM acetate.     

Photoactivated cross-linking of proteins within the erythrocyte membrane core.

We describe the reactions of three lipophilic, photoactivated cross-linking reagents, 1,5-diazidonapthalene, 4,4'-diazidobiphenyl, and the reversible 4,4'-dithiobisphenylazide, with erythrocyte membranes. Cross-linking occurs only upon photoactivation. At pH 7 to 8, only spectrin components are cross-linked by these reagents. At pH 5.0 to 5.5 several additional membrane proteins including the major "integral" membrane proteins are also cross-linked, despite equivalent binding of the cross-linkers at neutral and acid pH. The cross-linking rates of various membrane proteins at pH 5.0 to 5.5 depend distinctly upon duration of photoactivation. Bidimensional electrophoresis of membrane proteins after cross-linking with the reversible cross-linker, 4,4'-dithiobisphenylazide, has allowed for the identification of homopolymeric products of cross-linking (e.g. dimers and tetramers of Band 3) and heterocomplexes (spectrin plus other membrane proteins). The data suggest that at reduced pH, cross-linking can proceed not only at the membrane surface but also in the membrane core.     

Hemolysis of human erythrocytes under hydrostatic pressure is suppressed by cross-linking of membrane proteins

The effects of cross-linking of membrane proteins on hemolysis of human erythrocytes under high pressure (2.0 kbar) were examined. The membrane proteins were cross-linked by oxidation of their SH-groups with diamide (0.05-0.5 mM) under different pressures (1-1,000 bar) at which no hemolysis occurs. As the pressure during diamide treatment was raised, the degree of hemolysis under 2.0 kbar and the quantity of cytoskeletal proteins extracted in a low ionic strength medium were gradually decreased. However, both values were increased by reduction with dithiothreitol. From the determination of membrane SH-groups, it was found that cross-linking of membrane proteins by diamide was accelerated under pressure. Only in erythrocytes treated with diamide under pressure were parts of spectrin and ankyrin, in addition to band 3 and band 4.2 proteins, extracted by using Triton X-100. One- and two-dimensional SDS-PAGE of membrane proteins showed that cross-linking of the membrane with cytoskeletal meshwork through linking proteins, in addition to that of membrane proteins themselves, was formed only in the diamide treatment under pressure. These results indicate that pressure-induced hemolysis is greatly suppressed by the supramolecular-weight polymers formed among membrane proteins, and that the high pressure technique is useful for cross-linking membrane proteins with diamide.     

The interaction of adenine nucleotides with the red cell membrane: A calorimetric study

The interaction of two adenine nucleotides with the red cell membrane was investigated using highly sensitive differential scanning calorimetry. It was found that ADP and AMP-PNP (an ATP analogue) preferentially modify the A transition, which has been shown to involve the unfolding of a portion of spectrin, an erythrocyte membrane protein complex. The interaction of ADP with spectrin was shown to be reversible and facilitated by the usual cofactor, Mg²⁺. The ADP-induced modification, however, is only observed for membrane associated spectrin; ADP has no effect on extracted spectrin. The results presented are consistent with an ADP-induced conformational change in the spectrin complex which leads to a change in the spectrin-membrane interaction. ADP, but not AMP-PNP, is shown to modify an additional calorimetric transition (B₂) associated with a structural change in the transmembrane protein band 3. This behavior is characteristic of inhibitors of anion transport in the red cell. ADP is also found to be an inhibitor of anion transport in red cells.     

Interactions between protein 4.1 and band 3. An alternative binding site for an element of the membrane skeleton

Protein 4.1 from human erythrocytes formed a complex with band 3 in inside-out erythrocyte membrane vesicles and with soluble peptides derived from the cytoplasmic domain of band 3. Protein 4.1 labeled metabolically with 32P bound saturably to vesicles depleted of endogenous protein 4.1. The soluble cytoplasmic domain of band 3 (43K) competitively displaced approximately 60% of bound 32P-protein 4.1 from reconstituted membrane vesicles. Pretreatment of vesicles with anti-43K similarly inhibited the rebinding of protein 4.1. In solution, 125I-43K formed a complex with protein 4.1 that saturated at 1:1 stoichiometry and migrated as a discrete band when analyzed by nondenaturing polyacrylamide gel electrophoresis. In rate-zonal sedimentation in isotonic salt solutions, protein 4.1 and 43K sedimented as a sharp peak at 4.4 S. In experiments aimed at exploring the role of the protein 4.1-band 3 interaction in the organization of the membrane skeleton, the effect of spectrin was investigated. Spectrin and protein 4.1 formed a complex which co-sedimented in sucrose gradients, but the addition of 43K to preformed spectrin-protein 4.1 complexes resulted in disruption of the complex and co-sedimentation of most of the protein 4.1 with 43K. These results suggest that protein 4.1 can associate with band 3 in the erythrocyte membrane and that this association may modulate the attachment of the membrane skeleton to the membrane.     

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.     

Adenylate cyclase activity of membrane fractions isolated from sea urchin sperm

The adenylate cyclase activity of sperm membrane fragments isolated from Lytechinus pictus sperm according to Cross [20] has been studied. Two distinct fractions preferentially coming from the flagellar plasma membrane are obtained. Surface I¹²⁵-labeling experiments performed by Cross [20] indicate that these membranes are representative of the entire sperm plasma membrane. Both fractions are enriched in their adenylate cyclase activity: the specific activity of the top membranes is eightfold higher than in whole sperm, whereas that of the middle membranes is 15-fold higher. The cyclase seems to be associated with the membranes. Lytechinus pictus egg jelly has no effect or slightly inhibits the adenylate cyclase activity of the isolated sperm plasma membrane fragments. Mg⁺⁺ and Na⁺ stimulated their cyclase activity about sevenfold at 2.5 mM Mn⁺⁺ and 3.2 mM ATP. At this ATP to Mn⁺⁺ ratio, high concentrations of Ca⁺⁺ have a small stimulatory effect.     

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.