The oligomeric state of spectrin in the rat erythrocyte membrane skeleton

The oligomeric state of spectrin in the erythrocyte membrane skeleton of the rat was investigated following extraction in a low ionic strength buffer for 24 and 96 h. All analyses were quantitatively compared with preparations from human erythrocyte membranes. After nondenaturing agarose-polyacrylamide gel electrophoresis, the human samples revealed their characteristic spectrin oligomer pattern; there were high molecular weight complexes near the origin of the gel, followed by several high order oligomers, tetramers, and dimers. The pattern in the rat membrane skeleton also included tetramers and a high molecular weight complex band, but had only one oligomer and no dimers. With time the high molecular weight complex diminished and oligomers accumulated in both the rat and human, while dimers accumulated only in the human and tetramers accumulated only in the rat. Tetramers decreased with time in the human. Extraction of spectrin increased with time and was greater from rat than the human red cell membrane at both time points. The percentage of spectrin and actin in the low ionic strength extract was similar between species, as analyzed by SDS-polyacrylamide electrophoresis, staining, and densitometry. Proteins 4.1 and 4.9 were present in greater percentages in the human. The only temporal effect on monomeric protein composition was an increase of protein A in the rat. There was no species difference in protein A percentage at 24 h, but at 96 h the rat was greater than the human. The results suggest that there are significant differences in the structural arrangement of the rat and human erythrocyte membrane skeleton.     

Gaps in the erythrocyte membrane skeleton: a stretched net model.

The geometry of spectrin-free regions in the erythrocyte membrane skeleton is modeled using Monte Carlo calculations for an incomplete triangular lattice of entropy springs under tension. Intact springs correspond to normal spectrin molecules, and cut springs correspond to spectrin that is missing or unable to associate normally. As springs are cut and the network is allowed to relax to mechanical equilibrium, gaps in the network appear. Geometrical properties of these gaps are obtained as a function of the fraction of springs cut. The most important property modeled is the area of the largest spectrin-free region; this area increases approximately exponentially as the fraction of normal spectrin decreases from 100% to approximately 50%. The effect of these gaps on lateral diffusion and vesiculation is discussed.     

Reaction of Se with SH groups in spectrin is involved in the stabilization of erythrocyte membrane skeleton

Na2SeO3 supplementation in the dialysis medium could obviously prevent the dissociation of spectrin from the erythrocyte membranes. Such Se effect could be eliminated by pretreatment of erythrocyte membranes with a SH-blocking reagent, iodoacetamide(IAA) or addition of a SH-compound, dithio-threitol. The fluorescence intensity of erythrocyte membranes labelled with the fluorescent probe N-(3-pyrenyl)-maleimide decreased with increasing Na2SeO3 concentration used for pretreatment of ghosts. 31P-NMR spectra of erythrocyte membrane dialyzed in the presence or absence of Na2SeO3 concentration showed a difference in chemical shift anisotropy (delta sigma) between these two samples. These data suggest that the stabilization effect is based on changes in lipid-protein interaction and conformation of membrane skeletal components induced by reaction of their SH groups with Na2SeO3.     

Drosophila spectrin: the membrane skeleton during embryogenesis

The distribution of alpha-spectrin in Drosophila embryos was determined by immunofluorescence using affinity-purified polyclonal or monoclonal antibodies. During early development, spectrin is concentrated near the inner surface of the plasma membrane, in cytoplasmic islands around the syncytial nuclei, and, at lower concentrations, throughout the remainder of the cytoplasm of preblastoderm embryos. As embryogenesis proceeds, the distribution of spectrin shifts with the migrating nuclei toward the embryo surface so that, by nuclear cycle 9, a larger proportion of the spectrin is concentrated near the plasma membrane. During nuclear cycles 9 and 10, as the nuclei reach the cell surface, the plasma membrane-associated spectrin becomes concentrated into caps above the somatic nuclei. Concurrent with the mitotic events of the syncytial blastoderm period, the spectrin caps elongate at interphase and prophase, and divide as metaphase and anaphase progress. During cellularization, the regions of spectrin concentration appear to shift: spectrin increases near the growing furrow canal and concomitantly increases at the embryo surface. In the final phase of furrow growth, the shift in spectrin concentration is reversed: spectrin decreases near the furrow canal and concomitantly increases at the embryo surface. In gastrulae, spectrin accumulates near the embryo surface, especially at the forming amnioproctodeal invagination and cephalic furrow. During the germband elongation stage, the total amount of spectrin in the embryo increases significantly and becomes uniformly distributed at the plasma membrane of almost all cell types. The highest levels of spectrin are in the respiratory tract cells; the lowest levels are in parts of the forming gut. The spatial and temporal changes in spectrin localization suggest that this protein plays a role in stabilizing rather than initiating changes in structural organization in the embryo.     

From the spectrin gene to the assembly of the membrane skeleton

The complete nucleotide sequence coding for the chicken brain alpha-spectrin was determined. It comprises the entire coding frame, 5'- and 3'-untranslated sequences terminating in a poly(A)-tail. The deduced amino acid sequence shows that the alpha-chain contains 22 segments, 20 of which correspond to the typical 106 residue repeat of the human erythrocyte spectrin. Some segments non-homologous to the repeat structure reside in the middle and COOH-terminal regions. Sequence comparisons with other proteins show that these segments evidently harbour some structural and functional features such as: homology to alpha-actinin and dystrophin, two typical EF-hand structures (calcium-binding) and a putative calmodulin-binding site in the COOH-terminus and a sequence homologous to various src-tyrosine kinases and to phospholipase C in the middle of the molecule. Comparison of our sequence with other partial alpha-spectrin sequences shows that alpha-spectrin is well conserved in different species and that the human erythrocyte alpha-spectrin is divergent.     

Visualization of the hexagonal lattice in the erythrocyte membrane skeleton

The isolated membrane skeleton of human erythrocytes was studied by high resolution negative staining electron microscopy. When the skeletal meshwork is spread onto a thin carbon film, clear images of a primarily hexagonal lattice of junctional F-actin complexes crosslinked by spectrin filaments are obtained. The regularly ordered network extends over the entire membrane skeleton. Some of the junctional complexes are arranged in the form of pentagons and septagons, approximately 3 and 8%, respectively. At least five forms of spectrin crosslinks are detected in the spread skeleton including a single spectrin tetramer linking two junctional complexes, three-armed Y-shaped spectrin molecules linking three junctional complexes, three-armed spectrin molecules connecting two junctional complexes with two arms bound to one complex and the third arm bound to the adjacent complex, double spectrin filaments linking two junctional complexes, and four-armed spectrin molecules linking two junctional complexes. Of these, the crosslinks of single spectrin tetramers and three-armed molecules are the most abundant and represent 84 and 11% of the total crosslinks, respectively. These observations are compatible with the presence of spectrin tetramers and oligomers in the erythrocyte membrane skeleton. Globular structures (9-12 nm in diameter) are attached to the majority of the spectrin tetramers or higher order oligomer-like molecules, approximately 80 nm from the distal ends of the spectrin tetramers. These globular structures are ankyrinor ankyrin/band 3-containing complexes, since they are absent when ankyrin and residual band 3 are extracted from the skeleton under hypertonic conditions.     

Structure of the erythrocyte membrane skeleton as observed by atomic force microscopy.

The structure of the membrane skeleton on the cytoplasmic surface of the erythrocyte plasma membrane was observed in dried human erythrocyte ghosts by atomic force microscopy (AFM), taking advantage of its high sensitivity to small height variations in surfaces. The majority of the membrane skeleton can be imaged, even on the extracellular surface of the membrane. Various fixation and drying methods were examined for preparation of ghost membrane samples for AFM observation, and it was found that freeze-drying (freezing by rapid immersion in a cryogen) of unfixed specimens was a fast and simple way to obtain consistently good results for observation without removing the membrane or extending the membrane skeleton. Observation of the membrane skeleton at the external surface of the cell was possible mainly because the bilayer portion of the membrane sank into the cell during the drying process. The average mesh size of the spectrin network observed at the extracellular and cytoplasmic surfaces of the plasma membrane was 4800 and 3000 nm2, respectively, which indicates that spectrin forms a three-dimensionally folded meshwork, and that 80% of spectrin can be observed at the extracellular surface of the plasma membrane.     

Direct involvement of spectrin thiols in maintaining erythrocyte membrane thermal stability and spectrin dimer self-association

Human erythrocytes vesiculate upon exposure to temperatures of 49 degrees C and above. Pretreatment of the cells with the thiol-alkylating agent N-ethylmaleimide (NEM) lowers the temperature needed to produce the same effect. Concomitant with the cells' heat susceptibility, skeletal mechanical instability and an increase in spectrin dissociation have been reported (Smith and Palek (1983) Blood 62, 1190). In the present study, similar results were achieved by preincubation of the cells with diamide, which could be reversed by reduction with dithiothreitol. Another oxidative agent, sodium tetrathionate, could only induce the temperature susceptibility, with little effect on spectrin dissociation. Incubation of spectrin solutions with NEM or diamide caused decreased association of spectrin dimers and increased dissociation of spectrin tetramers. Estimation of membrane and spectrin thiols in the treated cells showed that NEM was effective while blocking less than 20% of the thiols. Diamide and tetrathionate blocked more than 50% of the thiols, but were less effective than NEM. It is suggested that some very defined population of thiols is essential for spectrin self-association and for membrane thermal stability. They are more available to NEM than to diamide and less so to tetrathionate. Other thiols participate in maintaining the membrane thermal stability only.     

Actin protofilament orientation in deformation of the erythrocyte membrane skeleton

The red cell's spectrin-actin network is known to sustain local states of shear, dilation, and condensation, and yet the short actin filaments are found to maintain membrane-tangent and near-random azimuthal orientations. When calibrated with polarization results for single actin filaments, imaging of micropipette-deformed red cell ghosts has allowed an assessment of actin orientations and possible reorientations in the network. At the hemispherical cap of the aspirated projection, where the network can be dilated severalfold, filaments have the same membrane-tangent orientation as on a relatively unstrained portion of membrane. Likewise, over the length of the network projection pulled into the micropipette, where the network is strongly sheared in axial extension and circumferential contraction, actin maintains its tangent orientation and is only very weakly aligned with network extension. Similar results are found for the integral membrane protein Band 3. Allowing for thermal fluctuations, we deduce a bound for the effective coupling constant, alpha, between network shear and azimuthal orientation of the protofilament. The finding that alpha must be about an order of magnitude or more below its tight-coupling value illustrates how nanostructural kinematics can decouple from more macroscopic responses. Monte Carlo simulations of spectrin-actin networks at approximately 10-nm resolution further support this conclusion and substantiate an image of protofilaments as elements of a high-temperature spin glass.     

Ubiquitination of spectrin regulates the erythrocyte spectrin-protein-4.1-actin ternary complex dissociation: implications for the sickle cell membrane skeleton.

It has been demonstrated by our laboratory that the irreversibly sickled cell (ISC) spectrin-4.1-actin complex dissociates slowly as compared to ternary complexes formed out of control (AA) and reversibly sickle cell (RSCs) core skeletons. These studies indicated that the molecular basis for the inability of irreversibly sickled cells (ISCs) to change shape is a skeleton that disassembles, and therefore reassembles, very slowly. The present study is based on the following observations: a) alpha-spectrin repeats 20 and 21 contain ubiquitination sites, and b) The spectrin repeats beta-1 and beta-2 are in direct contact with spectrin repeats alpha-20 and alpha-21 during spectrin heterodimer formation, and contain the protein 4.1 binding domain. We demonstrate here that alpha-spectrin ubiquitination at repeats 20 and 21 increases the dissociation of the spectrin-protein-4.1-actin ternary complex thereby regulating protein 4.1's ability to stimulate the spectrin-actin interaction. Performing in vitro ternary complex dissociation assays with AA control and sickle cell SS spectrin (isolated from high-density sickle cells), we further demonstrate that reduced ubiquitination of alpha-spectrin is, in part, responsible for the locked membrane skeleton in sickle cell disease.     

Ankyrin-independent membrane protein-binding sites for brain and erythrocyte spectrin

Brain spectrin reassociates in in vitro binding assays with protein(s) in highly extracted brain membranes quantitatively depleted of ankyrin and spectrin. These newly described membrane sites for spectrin are biologically significant and involve a protein since (a) binding occurs optimally at physiological pH (6.7-6.9) and salt concentrations (50 mM), (b) binding is abolished by digestion of membranes with alpha-chymotrypsin, (c) Scatchard analysis is consistent with a binding capacity of at least 50 pmol/mg total membrane protein, and highest affinity of 3 nM. The major ankyrin-independent binding activity of brain spectrin is localized to the beta subunit of spectrin. Brain membranes also contain high affinity binding sites for erythrocyte spectrin, but a 3-4 fold lower capacity than for brain spectrin. Some spectrin-binding sites associate preferentially with brain spectrin, some with erythrocyte spectrin, and some associate with both types of spectrin. Erythrocyte spectrin contains distinct binding domains for ankyrin and brain membrane protein sites, since the Mr = 72,000 spectrin-binding fragment of ankyrin does not compete for binding of spectrin to brain membranes. Spectrin binds to a small number of ankyrin-independent sites in erythrocyte membranes present in about 10,000-15,000 copies/cell or 10% of the number of sites for ankyrin. Brain spectrin binds to these sites better than erythrocyte spectrin suggesting that erythrocytes have residual binding sites for nonerythroid spectrin. Ankyrin-independent-binding proteins that selectively bind to certain isoforms of spectrin provide a potentially important flexibility in cellular localization and time of synthesis of proteins involved in spectrin-membrane interactions. This flexibility has implications for assembly of the membrane skeleton and targeting of spectrin isoforms to specialized regions of cells.     

Caspase remodeling of the spectrin membrane skeleton during lens development and aging

Terminal differentiation of lens fiber cells resembles the apoptotic process in that organelles are lost, DNA is fragmented, and changes in membrane morphology occur. However, unlike classically apoptotic cells, which are disintegrated by membrane blebbing and vesiculation, aging lens fiber cells are compressed into the center of the lens, where they undergo cell-cell fusion and the formation of specialized membrane interdigitations. In classically apoptotic cells, caspase cleavage of the cytoskeletal protein alpha-spectrin to approximately 150-kDa fragments is believed to be important for membrane blebbing. We report that caspase(s) cleave alpha-spectrin to approximately 150-kDa fragments and beta-spectrin to approximately 120- and approximately 80-kDa fragments during late embryonic chick lens development. These fragments continue to accumulate with age so that in the oldest fiber cells of the adult lens, most, if not all, of the spectrin is cleaved to discrete fragments. Thus, unlike classical apoptosis, where caspase-cleaved spectrin is short lived, lens fiber cells contain spectrin fragments that appear to be stable for the lifetime of the organism. Moreover, fragmentation of spectrin results in reduced membrane association and thus may lead to permanent remodeling of the membrane skeleton. Partial and specific proteolysis of membrane skeleton components by caspases may be important for age-related membrane changes in the lens.     

Involvement of spectrin in the maintenance of phase-state asymmetry in the erythrocyte membrane

The fluorescent probe merocyanine 540 does not stain the plasma membrane of normal human or murine erythrocytes, nor of genetically abnormal human spherocytic erythrocytes. It does, however, stain erythrocyte membranes in several systems in which the underlying spectrin network is altered or missing. Because of the greater affinity of merocyanine 540 for fluid—phase lipid bilayers, these results suggest that the external leaflet of erythrocyte membranes becomes more disordered upon alteration or loss of the internal spectrin network. Analysis of the transbilayer arrangement of membrane phospholipids by digestion with phospholipase A2 suggests that lipid compositional asymmetry of the erythrocyte membrane is responsible for a phase-state asymmetry between the two lipid leaflets, and that spectrin is required to maintain this asymmetry and the gel-like state of the external leaflet.     

Essential control of an endothelial cell ISOC by the spectrin membrane skeleton

Mechanism(s) underlying activation of store-operated Ca2+ entry currents, ISOC, remain incompletely understood. F-actin configuration is an important determinant of channel function, although the nature of interaction between the cytoskeleton and ISOC channels is unknown. We examined whether the spectrin membrane skeleton couples Ca2+ store depletion to Ca2+ entry. Thapsigargin activated an endothelial cell ISOC (-45 pA at -80 mV) that reversed at +40 mV, was inwardly rectifying when Ca2+ was the charge carrier, and was inhibited by La3+ (50 microM). Disruption of the spectrin-protein 4.1 interaction at residues A207-V445 of betaSpIISigma1 decreased the thapsigargin-induced global cytosolic Ca2+ response by 50% and selectively abolished the endothelial cell ISOC, without altering activation of a nonselective current through cyclic nucleotide-gated channels. In contrast, disruption of the spectrin-actin interaction at residues A47-K186 of betaSpIISigma1 did not decrease the thapsigargin-induced global cytosolic Ca2+ response or inhibit ISOC. Results indicate that the spectrin-protein 4.1 interaction selectively controls ISOC, indicating that physical coupling between calcium release and calcium entry is reliant upon the spectrin membrane skeleton.     

Ultrastructure of the intact skeleton of the human erythrocyte membrane

Filamentous skeletons were liberated from isolated human erythrocyte membranes in Triton X-100, spread on fenestrated carbon films, negatively stained, and viewed intact and unfixed in the transmission electron microscope. Two forms of the skeleton were examined: (a) basic skeletons, stripped of accessory proteins with 1.5 M NaCl so that they contain predominantly polypeptide bands 1, 2, 4.1, and 5; and (b) unstripped skeletons, which also bore accessory proteins such as ankyrin and band 3 and small plaques of residual lipid. Freshly prepared skeletons were highly condensed. Incubation at low ionic strength and in the presence of dithiothreitol for an hour or more caused an expansion of the skeletons, which greatly increased the visibility of their elements. The expansion may reflect the opening of spectrin from a compact to an elongated disposition. Expanded skeletons appeared to be organized as networks of short actin filaments joined by multiple (5-8) spectrin tetramers. In unstripped preparations, globular masses were observed near the centers of the spectrin filaments, probably corresponding to complexes of ankyrin with band 3 oligomers. Some of these globules linked pairs of spectrin filaments. Skeletons prepared with a minimum of perturbation had thickened actin protofilaments, presumably reflecting the presence of accessory proteins. The length of these actin filaments was highly uniform, averaging 33 +/- 5 nm. This is the length of nonmuscle tropomyosin. Since there is almost enough tropomyosin present to saturate the F-actin, our data support the hypothesis that tropomyosin may determine the length of actin protofilaments in the red cell membrane.