Endocytosis in erythrocytes and ghosts: occurrence at 0 degrees C after ATP preincubation

Two steps were required for ATP-dependent endocytosis in resealed erythrocyte ghosts. The first step required incubation with Mg-ATP at 37 °C, while the second step required primaquine and occurred at 0 or at 37 °C. These two steps were apparently also required for ATP-dependent endocytosis in erythrocytes. Endocytosis in white ghosts was similar to that in resealed ghosts and erythrocytes; the main difference was that the requirement of primaquine for the second step was less strict in white ghosts; in them, appreciable endocytosis took place with no added primaquine. Nonetheless, endocytosis in all three types of cells was stimulated by primaquine. The fluidity of the membranes as sensed by spin-labeled phosphatidylcholine was measured with and without primaquine. The fluidity of erythrocytes was increased by addition of primaquine or by conversion of the erythrocytes to white ghosts; the effect primaquine had on the fluidity of white ghosts was not detectable by the spin label. This suggested that a fluidizing or loosening of the membrane structure was required for the second step of ATP-dependent endocytosis, and that this loosening could be accomplished either by primaquine or by the process of preparing white ghosts.     

A flow EPR study of deformation and orientation characteristics of erythrocyte ghosts: A possible effect of an altered state of cytoskeletal network

Summary Using the flow EPR technique, we investigated the resealed ghost deformability in shear flow and the effects of the altered state of cytoskeletal network induced by hypotonic incubation of ghosts. Isotonically resealed ghosts in the presence of Mg-ATP, in which alteration of cytoskeletal network is not effected, have smooth biconcave discoid shapes, and show a flow orientation and deformation behavior similar to that of erythrocytes, except that higher viscosities are required to induce the same degrees of deformation and orientation as in erythrocytes. The flow behavior of resealed ghosts is Mg-ATP dependent, and the shape of the ghosts resealed without Mg-ATP is echinocytic. In contrast, the ghosts resealed by hypotonic incubation show a markedly reduced deformability even with Mg-ATP present. Nonreducing, nondenaturing polyacrylamide gel electrophoresis (PAGE) of the low ionic strength extracts from hypotonically resealed ghosts reveals a shift of the spectrin tetramer-dimer equilibrium toward the dimers. In the maleimide spin-labeled ghosts, the ratios of the weakly immobilized to the strongly immobilized EPR intensities are larger in hypotonically resealed ghosts than in the isotonically resealed ghosts, indicating an enhanced mobility in the spectrin structure in the former. Photomicrographs of hypotonically resealed ghosts show slightly stomatocytic transformations. These data suggest that the shape and the deformability loss in hypotonically resealed ghosts are related to an alteration of the spectrin tetramer-dimer equilibrium in the membrane. Thus, the shift of the equilibrium is likely to affect the regulation of the membrane deformability both in normal and pathological cells such as hereditary elliptocytes.     

On the mechanism of ATP-induced shape changes in human erythrocyte membranes. I. The role of the spectrin complex

Human erythrocyte ghosts have been shown, by scanning electron microscopy, to undergo ATP-dependent shape changes. Under appropriate conditions the ghosts prepared from normal disk-shaped intact cells adopt a highly crenated shape, which in the presence of Mg-ATP at 37 degrees C is slowly converted to the disk shape and eventually to the cup shape. These changes are not observed with other nucleotides or with 5'-adenylyl imidodiphosphate. Anti-spectrin antibodies, incorporated along with the Mg-ATP into the ghosts in amounts less than equivalent to the spectrin, markedly accelerate the shape changes observed with the Mg-ATP alone. The Fab fragments of these antibodies, however, have no effect. The conclusion is that the structural effect produced by the ATP is promoted by the cross-linking of spectrin by its antibodies, and may therefore itself be some kind of polymerization or network formation involving the spectrin complex on the cytoplasmic face of the membrane. The factors that contribute to the shape of the ghost and of the intact erythrocyte are discussed in the light of these findings.     

Spectrin rearrangement early in erythrocyte ghost endocytosis

The endocytic vacuoles induced in white ghosts were found to be depleted of spectrin and therefore it was proposed that they arose from spectrin-free areas in the erythrocyte membrane. To follow changes in spectrin distribution during endocytosis, affinity-purified rabbit antispectrin antibodies were produced. Quantitative techniques were developed for the use of a highly specific 125I-F(ab')2 antispectrin, and these showed that before the appearance of vacuoles, as assessed by phase microscopy, there was a reproducible decrease in immunoreactive spectrin. To determine whether this spectrin decrease represented a local or diffuse spectrin loss or a spectrin rearrangement, morphologic studies were undertaken using transmission electron microscopy on samples treated with rabbit antispectrin and ferritin-conjugated goat anti-rabbit immunoglobulin. These studies showed that endocytosis was preceded by the creation of extensive spectrin-free areas separated by discrete spectrin-containing zones. Pretreatment of ghosts with alkaline phosphatase blocked all forms of endocytosis and prevented the creation of spectrin-free areas. Therefore, it is proposed that under the impetus of endocytosis inducers, phosphorylated spectrin is redistributed so that spectrin-free zones are created, and that endocytic vacuoles form and fuse in spectrin-free areas.     

Actin in erythrocyte ghosts and its association with spectrin. Evidence for a nonfilamentous form of these two molecules in situ

Actin was isolated from erythrocyte ghosts. It is identical to muscle actin in its molecular weight, net charge, ability to polymerize into filaments with the double helical morphology, and its decoration with heavy meromyosin (HMM). when erythrocyte ghosts are incubated in 0.1 mM EDTA, actin and spectrin are solubilized. Spectrin has a larger molecular weight than muscle myosin. When salt is added to the EDTA extract, a branching filamentous polymer is formed. However, when muscle actin and the EDTA extract are mixed together in the presence of salt, the viscosity achieved is less than the viscosity of the solution if spectrin is omitted. Thus, spectrin seems to inhibit the polymerization of actin. If the actin is already polymerized, the addition of spectrin increases the viscosity of the solution, presumably by cross-linking the actin filaments. The addition of HMM of trypsin to erythrocyte ghosts results in filament formation in situ. These agents apparently act by detaching erythrocyte actin from spectrin, thereby allowing the polmerization of one or both proteins to occur. Since filaments are not present in untreated erythrocyte ghosts, we conclude that erythrocyte actin and spectrin associate to form an anastomosing network beneath the erythrocyte membrane. This network presumably functions in restricting the lateral movement of membrane-penetrating particles.     

Spectrin band 1 and 2 are antigenically distinct and are not composed of subunits.

Human erythrocyte membranes and freshly isolated spectrin were separated into their constituent peptides by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. The peptides were electrophoresed from slices of such gels into agarose gels containing anti-spectrin antibodies and Triton X-100. In fresh preparations, precipitin arcs were observed only against peptides migrating as bands 1 and 2. It was found that bands 1 and 2 did not cross-react. There were two major arcs from band 1 and one principal arc from band 2, plus minor splitting of these arcs. None of the band 1 arcs fused with band 2 arcs. In fresh erythrocyte ghosts only bands 1 and 2 reacted with anti-spectrin; bands 2.1, 3, and 5, in particular, showed no precipitin arcs. However, in aged ghosts, arcs appeared in the band 3 region; in aged isolated spectrin, arcs appeared in the band 2.1 region; and in trypsin-degraded spectrin, reactive species occurred in all molecular weight classes. It is concluded that spectrin has no subunits smaller than 220,000 molecular weight and that bands 1 and 2 are immunochemically distinct.     

The role of ankyrin in shape and deformability change of human erythrocyte ghosts

Human erythrocyte membranes (ghosts) from acid/citrate/dextrose preserved blood were digested with trypsin (protein/trypsin = 100:1) under hypotonic conditions and then analyzed by SDS-polyacrylamide gel electrophoresis. After digestion for about 20-30 s at 0 degree C, only ankyrin had disappeared and other bands including spectrin, actin, band 4.1 and band 3 remained intact. This observation was supported by electron micrographs showing that the horizontally disposed, filamentous structure was a little apart from the lipid bilayer and its components were not destroyed. In contrast to intact ghosts, treatment with chlorpromazine, or Mg-ATP did not induce shape change in these trypsin-treated ghosts. The number of transformable cells correlated closely with the amount of remaining ankyrin in the SDS-polyacrylamide gel electrophoresis pattern. Furthermore, the chlorpromazine- and Mg-ATP-induced decreases in viscosity of suspensions of erythrocyte ghosts were also prevented by trypsin treatment for 20-30 s at 0 degree C. These findings suggest that ankyrin plays an important role in the change in shape and deformability of erythrocyte ghosts. The molecular mechanism of drug-induced shape change and the role of undermembrane structure in regulating erythrocyte shape and deformability are discussed.     

Suppression of high-pressure-induced hemolysis of human erythrocytes by preincubation at 49 degrees C.

When human erythrocytes were preincubated at 37-52 degrees C under atmospheric pressure before exposure to a pressure of 200 MPa at 37 degrees C, the value of hemolysis was constant (about 43%) up to 45 degrees C but became minimal at 49 degrees C. The results from anti-spectrin antibody-entrapped red ghosts, spectrin-free vesicles, and N-(1-pyrenyl)iodoacetamide-labeled ghosts suggest that the denaturation of spectrin is associated with such behavior of hemolysis at 49 degrees C. The vesicles released at 200 MPa by 49 degrees C-preincubated erythrocytes were smaller than those released by the treatment at 49 degrees C or 200 MPa alone. The size of vesicles released at 200 MPa was independent of preincubation temperature up to 45 degrees C, and the vesicles released from 49 degrees C-preincubated erythrocytes became smaller with increasing pressure up to 200 MPa. Thus, hemolysis and vesiculation under high pressure are greatly affected by the conformation of spectrin before compression. Since spectrin remains intact up to 45 degrees C, the compression of erythrocytes at 200 MPa induces structural changes of spectrin followed by the release of large vesicles and hemolysis. On the other hand, in erythrocytes that are undergoing vesiculation due to spectrin denaturation at 49 degrees C, compression produces smaller vesicles, so that the hemolysis is suppressed.     

Extraction of membrane proteins in low ionic strengths]

Hemoglobin and the low molecular weight proteins 8 and 9 are extracted from ghosts during low ionic washing after the hypotonic hemolysis of erythrocytes. Furthermore, a loss of the proteins 4.5 and 7 was observed. The protein patterns of ghosts after isotonic hemolysis by freezing and thawing resemble the ghost protein patterns after hypotonic hemolysis and incomplete deprivation of Hb. Many if not all membrane proteins are eluted by repeated incubations of the ghosts in solutions of low ionic strength in the presence of EDTA. The spectrins, the proteins 5, 4.5, 7 and residual Hb are extracted preferentially. A selective extraction of the spectrins and the protein 5 is not detectable under these conditions. Often the spectrin bands are subdivided following low ionic incubation.     

Monoclonal antibodies to red cell cytoskeletal proteins

Monoclonal antibodies to human red cell cytoskeletal proteins were produced following immunization of mice with Triton shells produced from intact red cells. Two lines producing antibodies binding to spectrin and actin, respectively, were subcloned and further characterized. Clones producing the anti-spectrin antibody were stable. The antibody was monoclonal and specific for spectrin band 2. The anti-actin clones were unstable.     

Membrane perturbations of erythrocyte ghosts by spectrin release

The cytoskeleton plays an important role in the stability and function of the membrane. Spectrin release from erythrocyte ghosts makes the membrane more fragile. However, the detail of membrane fragility has remained unclear. In the present study, the effects of incubation temperatures and polyamines on the membrane structure of ghosts under hypotonic conditions have been examined. Upon exposure of ghosts to a hypotonic buffer at 0-37 degrees C, reduction of ghost volume, spectrin release and decrease of band 3-cytoskeleton interactions were clearly observed above 30 degrees C. However, such changes were completely inhibited by spermine and spermidine. Interestingly, conformational changes of spectrin induced at 37 degrees C or 49 degrees C were not suppressed by both polyamines. Flow cytometry of fluorescein isothiocyanate-labelled ghosts exposed to 37 degrees C demonstrated the two peaks corresponding to ghosts with normal spectrin content and decreased one. Taken together, these results indicate that the degree of spectrin release from the membrane under hypotonic conditions is not same in all ghosts, and that polyamines inhibit the spectrin release followed by changes in the membrane structure, but not conformational changes of spectrin.     

Role of spectrin in Amoeba proteus, as studied by microinjection of anti-spectrin monoclonal antibodies.

Spectrin is a major protein accounting for about 5% of whole-cell proteins in Amoeba proteus, and the precipitation of spectrin by intracellular injection of purified anti-spectrin monoclonal antibodies has a profound effect on cell morphology, motility, and movement-related cell activities in amoebae. Thus, amoebae injected with anti-spectrin antibodies show drastic changes in their shape and movement, suggesting that amoeba spectrin plays an important structural role, unlike nonerythroid spectrins in other cells. However, precipitation of spectrin does not affect the distribution of F-actin in amoebae.     

A spectrin-like protein in retinal rod outer segments

Biochemical and immunochemical studies indicate that rod outer segments (ROS) of bovine photoreceptor cells contain a Mr 240,000 polypeptide related to the alpha-subunit of red blood cell (RBC) spectrin. With the use of sodium dodecyl sulfate gel electrophoresis in conjunction with the immunoblotting technique, monoclonal antibody 4B2 was found to bind to a Mr 240,000 polypeptide in ROS that is distinct from the prominent Mr 220,000 concanavalin A binding glycoprotein. The Mr 240,000 polypeptide is highly susceptible to degradation by endogenous proteases. It does not appear to be an integral membrane protein but is tightly membrane associated since it can be partially extracted from ROS membranes with urea in the absence of detergent. The 4B2 antibody cross-reacted with RBC ghosts and bovine brain microsomal membranes. Radioimmune assays and immunoblotting analysis of purified bovine RBC spectrin further revealed that the 4B2 antibody predominantly labeled the alpha-chain of RBC spectrin having an apparent molecular weight of 240,000. Polyclonal anti-spectrin antibody that bound to both the alpha- and beta-chain of RBC spectrin predominantly labeled a Mr 240,000 polypeptide of ROS membranes. Two faintly labeled bands in the molecular weight range of 210,000-220,000 were also observed. These components may represent variants of the beta-chain of spectrin that are weakly cross-reacting or present in smaller quantities than the alpha-chain.(ABSTRACT TRUNCATED AT 250 WORDS)     

Spectrin phosphorylation and shape change of human erythrocyte ghosts

Human erthrocyte membranes in isotonic medium change shape from crenated spheres to biconcave disks and cup-forms when incubated at 37 degrees C in the presence of MgATP (M. P. Sheetz and S. J. Singer, 1977, J. Cell Biol. 73:638-646). The postulated relationship between spectrin phosphorylation and shape change (W. Birchmeier and S. J. Singer, 1977, J. Cell Biol. 73:647-659) is examined in this report. Salt extraction of white ghosts reduced spectrin phosphorylation during shape changes by 85-95%. Salt extraction did not alter crenation, rate of MgATP-dependent shape change, or the fraction (greater than 80%) ultimately converted to disks and cup-forms after 1 h. Spectrin was partially dephosphorylated in intact cells by subjection to metabolic depletion in vitro. Membranes from depleted cells exhibited normal shape-change behavior. Shape-change behavior was influenced by the hemolysis buffer and temperature and by the time required for membrane preparation. Tris and phosphate ghosts lost the capacity to change shape after standing for 1-2 h at 0 degrees C. Hemolysis in HEPES or N- tris(hydroxymethyl)methyl-2-aminoethanesulfonic acid yielded ghosts that were converted rapidly to disks in the absence of ATP and did not undergo further conversion to cup-forms. These effects could not be attributed to differential dephsphorylation of spectrin, because dephosphorylation during ghost preparation and incubation was negligible. These results suggest that spectrin phosphorylation is not required for MgATP-dependent shape change. It is proposed that other biochemical events induce membrane curvature changes and that the role of spectrin is passive.     

Effects of intracellular Ca2+ and proteolytic digestion of the membrane skeleton on the mechanical properties of the red blood cell membrane

Intracellular Ca2+ at concentrations ranging from 0 to 10 mumol/l increases the shear modulus of surface elasticity (mu) and the surface viscosity (eta) of human red blood cells by 20% and 70%, respectively. K+ selective channels in the red cell membrane become activated by Ca2+. The activation still occurs to the same extent when the membrane skeleton is degraded by incorporation of trypsin into resealed red cell ghosts, suggesting that the channel activation is not controlled by the proteins of the membrane skeleton and is independent of mu and eta. Incorporation of trypsin at concentrations ranging from 0 to 100 ng/ml into red cell ghosts leads to a graded digestion of spectrin, a cleavage of the band 3 protein and a release of the binding proteins ankyrin and band 4.1. These alterations are accompanied by an increase of the lateral mobility of the band 3 protein which, at 40 ng/ml trypsin, reaches a plateau value where the rate of lateral diffusion is enhanced by about two orders of magnitude above the rate measured in controls without trypsin. Proteolytic digestion by 10-20 ng/ml trypsin leads to a degradation of more than 40% of the spectrin and increases the rate of lateral diffusion to about 20-70% of the value observed at the plateau. Nevertheless, mu and eta remain virtually unaltered. However, the stability of the membrane is decreased to the point where a slight mechanical extension, or the shear produced by centrifugation results in disintegration and vesiculation, precluding measurements of eta and mu in ghosts treated with higher concentrations of trypsin. These findings indicate that alterations of the structural integrity of the membrane skeleton exert drastically different effects on mu and eta on the one hand and on the stability of the membrane on the other.     

Possible identity of a membrane-bound with a soluble cyclic AMP-independent erythrocyte protein kinase that phosphorylates spectrin

A soluble casein kinase isolated and purified to homogeneity from the human erythrocyte cytosol by phosphocellulose and Sephadex G-200 chromatographies is indistinguishable from the membrane-bound casein (spectrin) kinase according to physical and site-specificity criteria. The soluble enzyme shows an Mr of about 30000 by gel filtration and comigrates with the purified membrane spectrin kinase as a single polypeptide of 32000 Da on sodium dodecyl sulfate polyacrylamide gels. The soluble kinase phosphorylates spectrin in situ in spectrin kinase-depleted ghosts and catalyzes the in vitro phosphorylation of partially dephosphorylated spectrin with saturation kinetics identical to those displayed by the membrane spectrin kinase. When component 2 of spectrin that had been phosphorylated with [gamma-32P]ATP by either the soluble or the membrane kinases was subjected to limited proteolysis, the same 21500 Da papain-generated phosphopeptide was found to have been produced by the two enzymes. The same 21500 Da phosphopeptide was identified after papain digestion of spectrin isolated from intact cells that had been incubated with 32Pi. However, this particular peptide was not labeled in spectrin that had been phosphorylated in vitro by the catalytic subunit of cyclic AMP-dependent protein kinase. Identical phosphopeptide patterns were obtained by gel filtration and two-dimensional peptide maps of trypsin-cleaved component 2 of spectrin that had been labeled in situ, in intact ghosts or in spectrin kinase-depleted ghosts supplemented with the soluble kinase. These findings indicate a possible identity of the soluble with the membrane-bound casein (spectrin) kinase.     

Involvement of erythrocyte skeletal proteins in the modulation of membrane fluidity by phenothiazines

The effects of phenothiazines (chlorpromazine, chlorpromazine sulfoxide, and trifluoperazine) and antimitotic drugs (colchicine and vinblastine) on the erythrocyte membrane have been investigated. Chlorpromazine and trifluoperazine induced a dose-dependent increase in the freedom of motion of stearic acid spin-labels bound to both intact erythrocytes and ghosts, but did not affect the freedom of motion of stearic acids bound to vesicles depleted of spectrin and actin or of ghosts resealed with anti-spectrin antibodies. Further, chlorpromazine and trifluoperazine were able to eliminate a protein 4.1 dependent membrane thermal transition detected by stearic acid spin-labels at 8.5 +/- 1.5 degrees C. Antimitotic drugs and chlorpromazine sulfoxide did not change either the freedom of motion of stearic acid spin-labels or the 8.5 degrees C membrane thermal transition. Results indicate the involvement of skeletal proteins as possible membrane target sites of biologically active phenothiazines and suggest that the control of stearic acid spin-label freedom of motion is mediated by the spectrin-actin network and the proteins that link the skeletal network to the membrane.     

Quantitative determination of virus-membrane fusion events. Fusion of influenza virions with plasma membranes and membranes of endocytic vesicles in living cultured cells

Incubation of fluorescently labeled influenza virus particles with living cultured cells such as lymphoma S-49 cells or hepatoma tissue culture cells resulted in a relatively high degree of fluorescence dequenching. Increase in the degree of fluorescence (35-40% fluorescence dequenching) was observed following incubation at pH 5.0 as well as at pH 7.4. On the other hand, incubation of fluorescently labeled influenza virions with erythrocyte ghosts resulted in fluorescence dequenching only upon incubation at pH 5.0. Only a low degree of fluorescence dequenching was observed upon incubation with inactivated unfusogenic influenza or with hemagglutinino-influenza virions. The results of the present work clearly suggest that the fluorescence dequenching observed at pH 5.0 resulted from fusion with the cells' plasma membranes, while that at pH 7.4 was with the membranes of endocytic vacuoles following endocytosis of the virus particles. Our results show that only the fluorescence dequenching observed at pH 7.4--but not that obtained at pH 5.0--was inhibited by lysosomotropic agents such as methylamine and ammonium chloride, or inhibitors of endocytosis such as EDTA and NaN3.     

Actin—membrane interactions: Association of G-actin with the red cell membrane

Chemically tritiated actin from rabbit skeletal muscle was used to investigate the association of G-actin with the red cell membrane. The tritiated actin was shown to be identical to unmodified actin in its ability to polymerize and to activate heavy meromyosin ATPase. Using sealed and unsealed red cell ghosts we have shown that G-actin binds to the cytoplasmic but not the extracellular membrane surface of ghosts. Inside-out vesicles which have been stripped of endogenous actin and spectrin by low-ionic-strength incubation bind little G-actin. However, when a crude spectrin extract containing primarily spectrin, actin, and band 4.1 is added back to stripped vesicles, subsequent binding of G-actin can be increased up to 40-fold. Further, this crude spectrin extract can compete for and abolish G-actin binding to unsealed ghosts. Actin binding to ghosts increases linearly with added G-actin and requires the presence of magnesium. In addition, actin binding is inhibited by cytochalasin B and DNAase I. Negative staining reveals an abundance of actin filaments formed when G-actin is added to reconstituted inside-out vesicles but none when it is added to unreconstituted vesicles. These observations indicate that added G-actin binds to the red cell membrane via filament formation nucleated by some membrane component at the cytoplasmic surface.     

ATP-induced endocytosis in human erythrocyte ghosts. Characterization of the process and isolation of the endocytosed vesicles.

ATP-induced endocytosis in human erythrocyte ghosts has been studied, and a procedure for the isolation of the endocytotic vesicles is described. Under isotonic conditions and 37 degrees C, optimal endocytosis occurs with concentrations of 4 to 10 mM MgATP. Within 30 min, up to 45% of the membrane is removed from the surface and converted into sealed inside-out vesicles. Local anesthetics, such as chlorpromazine, potentiate ATP-induced endocytosis in ghosts. Forcing cells containing endocytotic vesicles through a hypodermic needle leads to the exclusive fragmentation of the outermost plasma membrane. The endocytosed vesicles can then be separated from these fragments by centrifugation on a gradient of dextran T70. Biochemical analyses indicate that endocytotic vesicles contain full complements of the major membrane proteins (i.e. also spectrin and actin), common phospholipids, fatty acids, and cholesterol. Furthermore, they exhibit a fully intact spectrin component 2 phosphorylation machinery. In contrast, MgATPase activity is largely excluded from these vesicles. The novel inside-out vesicles described have properties different from those of previously analyzed fragments of the erythrocyte membrane. They will permit a detailed study of a native spectrin-actin network now exposed to the outside.