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

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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.     

Non-erythroid beta spectrin interacting proteins and their effects on spectrin tetramerization

With yeast two-hybrid methods, we used a C-terminal fragment (residues 1697–2145) of non-erythroid beta spectrin (βII-C), including the region involved in the association with alpha spectrin to form tetramers, as the bait to screen a human brain cDNA library to identify proteins interacting with βII-C. We applied stringent selection steps to eliminate false positives and identified 17 proteins that interacted with βII-C (IP_βII-C s). The proteins include a fragment (residues 38–284) of “THAP domain containing, apoptosis associated protein 3, isoform CRA g”, “glioma tumor suppressor candidate region gene 2” (residues 1-478), a fragment (residues 74–442) of septin 8 isoform c, a fragment (residues 704–953) of “coatomer protein complex, subunit beta 1, a fragment (residues 146–614) of zinc-finger protein 251, and a fragment (residues 284–435) of syntaxin binding protein 1. We used yeast three-hybrid system to determine the effects of these βII-C interacting proteins as well as of 7 proteins previously identified to interact with the tetramerization region of non-erythroid alpha spectrin (IP_αII-N s) [1] on spectrin tetramer formation. The results showed that 3 IP_βII-C s were able to bind βII-C even in the presence of αII-N, and 4 IP_αII-N s were able to bind αII-N in the presence of βII-C. We also found that the syntaxin binding protein 1 fragment abolished αII-N and βII-C interaction, suggesting that this protein may inhibit or regulate non-erythroid spectrin tetramer formation.     

The effects of p-mercuribenzenesulfonate on purified spectrin and actin

The compound p-mercuribenzenefulfonate was found to affect the self-association behavior of both spectrin and actin. The reagent brings about the depolymerization of F-actin, as judged from the decrease in the fluorescence of an attached pyrene label, with a second-order rate constant an order of magnitude less than that for the disruption of isolated erythrocyte cytoskeletons. Therefore, it is unlikely that the depolymerization of actin is the rate-determining step in the mercurial-dependent disruption of the erythrocyte cytoskeleton. Low reagent concentrations caused an initial rapid dissociation of spectrin tetramers at a rate comparable with that of cytoskeleton disruption. Prolonged incubation, or higher reagent concentrations, resulted in subsequent aggregation of spectrin. The reagent also prevented the interaction between spectrin and actin, presumably through its depolymerization of actin and its effects on spectrin. The early event in the disruption of isolated erythrocyte cytoskeletons by p-mercuribenzenesulfonate thus appears to be the dissociation of spectrin oligomers. Subsequent depolymerization of actin brought about by the reagent then results in total disruption of the cytoskeleton.     

The abnormal phosphorylation of spectrin in human hereditary spherocytosis

The phosphorylation of the proteins of the erythrocyte membrane of patients suffering from hereditary spherocytosis is investigated in intact erythrocytes by their incubation in the presence of radioactive inorganic phosphate. Examination of the phosphorylated components by high-resolution two-dimensional gel electrophoresis reveals only one defect in the pathological membranes, a depressed phosphorylation of the smaller polypeptide of spectrin; band 2. The phosphorylation of band 2 is measured with reference to the phosphorylation of syndein ($\text{2.1 + 2.2 + 2.3}$). In patients showing overt clinical symptoms and for whom splenectomy is advocated the phosphorylation of band 2 is depressed by approx. 70%. After splenectomy the phosphorylation of membrane proteins is restored to normal levels.     

Physical-chemical studies of spectrin

In recent years considerable progress has been made in the understanding of the structure and function of the red blood cell membrane. The protein spectrin, of high molecular weight and propensity for self-association, appears to play a major role, in concert with actin, in maintaining the shape and integrity of the membrane. A study of the physical-chemical properties of spectrin, and its size, shape, self-association pattern, and its interaction with other components, leads to a plausible model for the way this protein performs its biological role. The evidence from the structure and interactions of spectrin suggests a structure which is relatively symmetrical yet highly expanded, and which allows extensive, two-dimensional network formation with actin. In these respects, the structure of spectrin is quite different from that of myosin, to which it has often been likened.     

An electro-optic study of human erythrocyte spectrin dimers. The presence of calcium ions does not alter spectrin flexibility

In order to determine whether the presence of Ca2+ increases the stiffness of the highly elongated and flexible spectrin molecules, we have carried out a birefringence relaxation study of isolated human erythrocyte spectrin dimers. Our measurements indicate no significant change in the flexibility of spectrin in solutions containing 0-10(-3) M Ca2+. This finding indicates that decreased spectrin flexibility is not the major functional mechanism underlying the decreased erythrocyte deformability reported as result of elevated intracellular levels of Ca2+. We find that the persistence length of spectrin dimers is less than 20 nm and is not dependent on the Ca2+ concentration.     

The self-association of human spectrin at high concentration.

The self-association of purified human spectrin has been studied at sedimentation equilibrium over a wide range of concentration (0-20 g/L) at 30 degrees C and pH 7.5. Coincidence of apparent weight average molecular weight and omega (r) plots as a function of total spectrin concentration indicated that equilibrium was attained and that no significant concentration of solute was incapable of participating in the self-association reaction. Under these conditions, no significant dissociation of the heterodimer to component polypeptide chains could be detected. The behavior of spectrin between 0 and 20 g/L can be described reasonably well by a cooperative isodesmic model, in which the protomer for association is the alpha beta heterodimer. With this model, the equilibrium constant for the heterodimer-tetramer step, K24, is 2 x 10(6) M-1, and K(iso), the equilibrium constant describing all other steps, is approximately 0.2 x 10(6) M-1. The returned value of the second virial coefficient for this model, 1.0 x 10(-7) L mol g-2, is consistent with the lower limit of values calculated for the heterodimer from the charge and Stokes radius of spectrin. On the other hand, the attenuated indefinite association model fails to describe the self-association of spectrin adequately over the range 0-20 g/L. Systematic decreases in the estimates of the second virial coefficient and the equilibrium constants for association beyond the tetramer suggest that the assumption of a single value of the second virial coefficient may not be appropriate for spectrin, and that non-ideality would best be taken into account by consideration of the detailed solution composition.     

Avian lens spectrin: subunit composition compared with erythrocyte and brain spectrin

Chicken lens spectrin is composed predominantly of equimolar amounts of two polypeptides with solubility properties similar, but not identical, to erythrocyte spectrin. The larger polypeptide, Mr 240,000 (lens alpha-spectrin), co-migrates with erythrocyte and brain alpha-spectrin on one- and two-dimensional SDS polyacrylamide gels and cross-reacts with antibodies specific for chicken erythrocyte alpha-spectrin; the smaller polypeptide, Mr 235,000 (lens gamma-spectrin), co-migrates with brain gamma-spectrin and does not cross-react with either the alpha-spectrin antibodies specific for chicken erythrocyte beta-spectrin. Minor amounts of polypeptides antigenically related to erythrocyte beta-spectrin with a greater electrophoretic mobility than lens gamma-spectrin are also detected in lens. The equimolar ratio of lens alpha- and gamma-spectrin is invariantly maintained during the extraction of lens plasma membranes under different conditions, or after immunoprecipitation of whole extracts of lens with erythrocyte alpha-spectrin antibodies. Two-dimensional peptide mapping reveals that whereas alpha-spectrins from chicken erythrocytes, brain, and lens are highly homologous, the gamma-spectrins, although related, have some cell-type-specific peptides and are substantially different from erythrocyte beta-spectrin. Thus, the expression of cell-type-specific gamma- and beta-spectrins may be the basis for the assembly of a spectrin-plasma membrane complex whose molecular composition is tailored to the functional requirements of the particular cell-type.     

The role of spectrin in erythrocyte ghost endocytosis.

Endocytosis in white ghosts prepared from human erythrocytes was induced by three methods: incubation with Mg-ATP, incubation with 0.1 mM EDTA, and digestion with 20 nanograms (ng.) per ml. of trypsin. In each case the endocytic vacuoles that were produced when separated and analyzed on SDS-polyacrylamide gel electrophoresis were found to be depleted of spectrin. This observation suggested that a requirement for endocytosis is the establishment of spectrin-free domains in the membrane. This hypothesis was tested by pre-incubating ghosts with anti-spectrin antibodies. Pre-incubation with anti-spectrin antibody blocked white ghost endocytosis produced either by Mg-ATP, EDTA, or trypsin. Therefore, it is proposed that spectrin has a key role in the endocytosis process.     

Brain spectrin exerts much stronger effect on anionic phospholipid monolayers than erythroid spectrin

Red blood cell spectrin and its nonerythroid analogues are linked to integral proteins of the membrane by several skeletal protein receptors, such as ankyrin and protein 4.1 together with p55. However, there are also many reasons for believing that they are insufficient to engender all the properties that characterise the native membrane. Therefore, we are concerned with the mechanism by which brain spectrin interacts with phospholipids of the membrane bilayer. Brain and erythrocyte spectrin were shown previously to bind phospholipid vesicles as well as monolayers prepared from aminophospholipids: phosphatidylethanolamine and phosphatidylserine and their mixtures with phosphatidylcholine (PC).In the present study, it is shown that brain spectrin binds to monolayers prepared from anionic phospholipids, such as phosphatidylinositol (PI), phosphatidic acid (PA), phosphatidyl glycerol, diphosphatidylglycerol, and their mixtures with PC. Brain spectrin injected into the subphase to reach nanomolar concentration induced a substantial increase in the surface pressure of monolayers prepared from the phospholipids and their mixtures mentioned above, possibly by penetrating them. This effect is stronger in the case of monolayers prepared from anionic phospholipids alone and weaker when monolayers were prepared from mixtures with PC. The weakest effect was observed in the case of phosphatidylinositol-4,5-bisphosphate monolayers. An interaction of brain spectrin with monolayers prepared from anionic phospholipids (PI/PC 7:3 and PA/PC 7:3) was inhibited (PI/PC much stronger than PA/PC) by purified erythrocyte ankyrin, which indicates that the binding site for those lipids is located in the β-subunit, possibly in, or in close proximity of, the ankyrin-binding site.In contrast, erythrocyte spectrin injected into the subphase induced a change in the surface pressure of monolayers prepared from anionic phospholipids, which was equal or smaller than the value of surface pressure change induced by protein without a monolayer. This effect was different from what had been observed previously for monolayers prepared from aminophospholipids and their mixtures with PC, and from the data for nonerythroid spectrin presented here.     

Brain spectrin exerts much stronger effect on anionic phospholipid monolayers than erythroid spectrin

Red blood cell spectrin and its nonerythroid analogues are linked to integral proteins of the membrane by several skeletal protein receptors, such as ankyrin and protein 4.1 together with p55. However, there are also many reasons for believing that they are insufficient to engender all the properties that characterise the native membrane. Therefore, we are concerned with the mechanism by which brain spectrin interacts with phospholipids of the membrane bilayer. Brain and erythrocyte spectrin were shown previously to bind phospholipid vesicles as well as monolayers prepared from aminophospholipids: phosphatidylethanolamine and phosphatidylserine and their mixtures with phosphatidylcholine (PC).In the present study, it is shown that brain spectrin binds to monolayers prepared from anionic phospholipids, such as phosphatidylinositol (PI), phosphatidic acid (PA), phosphatidyl glycerol, diphosphatidylglycerol, and their mixtures with PC. Brain spectrin injected into the subphase to reach nanomolar concentration induced a substantial increase in the surface pressure of monolayers prepared from the phospholipids and their mixtures mentioned above, possibly by penetrating them. This effect is stronger in the case of monolayers prepared from anionic phospholipids alone and weaker when monolayers were prepared from mixtures with PC. The weakest effect was observed in the case of phosphatidylinositol-4,5-bisphosphate monolayers. An interaction of brain spectrin with monolayers prepared from anionic phospholipids (PI/PC 7:3 and PA/PC 7:3) was inhibited (PI/PC much stronger than PA/PC) by purified erythrocyte ankyrin, which indicates that the binding site for those lipids is located in the beta-subunit, possibly in, or in close proximity of, the ankyrin-binding site.In contrast, erythrocyte spectrin injected into the subphase induced a change in the surface pressure of monolayers prepared from anionic phospholipids, which was equal or smaller than the value of surface pressure change induced by protein without a monolayer. This effect was different from what had been observed previously for monolayers prepared from aminophospholipids and their mixtures with PC, and from the data for nonerythroid spectrin presented here.     

Erythroid spectrin in miceller detergents

We have studied the interaction of spectrin, the major protein of the erythrocyte cytoskeleton, with four commonly used detergents at concentrations above their critical miceller concentrations (cmc). Fluorescence spectroscopic studies on the emission intensity, steady state polarization, quenching with acrylamide, and time-resolved fluorescence measurements were done with spectrin in anionic detergents, e.g., SDS, deoxycholate, and nonionic detergents, e.g., Triton-X-100 and octylglucoside at concentrations double their respective cmc's. The spectrin-detergent complexes in all four systems have been characterized by far-UV CD and measurements on tryptophan fluorescence in combination with fluorescence of the extrinsic probe, pyrene. Tryptophan fluorescence studies revealed quaternary structural changes due to unzipping of the spectrin subunits in Triton-X-100 without complete dissociation. Both Triton-X-100 and SDS were found to partially denature spectrin indicated by the far-UV CD. Octylglucoside and deoxycholate are shown to have the least structural perturbations on the cytoskeletal protein, rationalizing the use of octylglucoside, in particular and also deoxycholate to be the most effective in preparing cytoskeletal fractions from erythrocytes rather than the Triton-X-100 that has long been used for preparing the Triton shells.     

Evolution of the spectrin repeat

We now know that the evolution of multidomain proteins has frequently involved genetic duplication events. These, however, are sometimes difficult to trace because of low sequence similarity between duplicated segments. Spectrin, the major component of the membrane skeleton that provides elasticity to the cell, contains tandemly repeated sequences of 106 amino acid residues. The same repeats are also present in α-actinin, dystrophin and utrophin. Sequence alignments and phylogenetic trees of these domains allow us to interpret the evolutionary relationship between these proteins, concluding that spectrin evolved from α-actinin by an elongation process that included two duplications of a block of seven repeats. This analysis shows how a modular protein unit can be used in the evolution of large cytoskeletal structures.     

Membrane orientation of sheep spectrin

Based primarily on studies of human erythrocytes, current theories of the structure and organization of erythrocyte membrane localize spectrin to the membrane cytoplasmic surface. Affinity purified anti-sheep spectrin antibodies were used in indirect immunofluorescence studies of intact erythrocytes from various vertebrate species and inside-out and right-side-out impermeable sheep erythrocyte vesicles. This investigation detected immunologically reactive external and potentially transmembranal determinant(s) of the sheep erythrocyte spectrin "assembly." Parallel studies using anti-sheep and anti-human spectrin antibodies, as well as 125I surface-labelling studies of intact sheep and human erythrocytes, indicated that this particular membrane orientation of spectrin was evident in sheep but not in human erythrocytes. Antisera containing antibodies to the external portion of this spectrin "assembly" demonstrated external fluorescence to a variable degree on some, but not all, vertebrate erythrocytes surveyed, confirming that the sheep erythrocyte was not the only exception. It is suggested that there may be subtle species variability in the intermolecular associations of the spectrin "assembly" with(in) the erythrocyte membrane not requiring alterations of the spectrin molecule itself.