Role of spectrin in cross bonding of the red cell membrane

Membrane cross bonding--an adhesion between opposing areas of the cytoplasmic face of the red cell membrane--was achieved by treating red cells with heat, diamide, N-ethymaleimide, urea, or by ATP depletion in conjunction with cell shrinking. Membrane cross bonding could be recognized by the shape of the cells upon swelling. Quantitated by the percentage of cross-bonded red cells the effectivity of the treatments decreased in the order given above. Cross bonding was hardly reversible by reducing the diamide-induced S-S bonds with dithioerythritol. The effect of heat and urea treatment as well as ATP depletion was partly reversible. Transmission electron micrographs of the cross-bonded region showed basically parallel membranes. The distance between the respective phospholipid bilayers varied between 40 and 120 nm from cell to cell. Hb-free ghosts prepared from diamide-treated red cells could also be cross bonded. The following conclusions are drawn: spectrin provides the molecular cross link in membrane cross bonding. Aggregation and enrichment of spectrin in the cross-bonded region are probably involved in membrane cross bonding.     

Analysis of the self-association of human red cell spectrin

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

Actin-binding and dimerization domains of HeLa cell filamin

HeLa cell filamin is a linear, bivalent, homodimer of high molecular weight subunits (Mr 250,000 that may cross-link actin filaments in vivo into supramolecular structures such as networks and bundles. We used millimolar Ca protease from chicken breast muscle to cleave the subunit into smaller fragments that we mapped with respect to the overall structure of the dimer. The enzyme cleaves HeLa filamin into a larger (Mr 192,000) and a smaller (Mr 104,000) fragment; the smaller fragment is the precursor of a still smaller (Mr 92,000) fragment. Only the larger fragment bound to actin in a cosedimentation test, suggesting that it contains the actin-binding region of the subunit. Digestion of HeLa filamin that had been cross-linked with dimethyl adipimidate produced a good yield of the Mr 192,000 fragment but a poor yield of the Mr 104,000/92,000 fragments. Since native filamins are head-to-head dimers, it was expected that cross-linking would proceed most readily at the dimerization site and, therefore, it appears that the Mr 192,000 fragment is cleaved from cross-linked filamin because it is distal to the dimerization region, while the Mr 104,000/92,000 fragments are absent because they lie at the dimerization region and were cross-linked to a form that was not identifiable by sodium dodecyl sulfate electrophoresis.     

Role of laminin terminal globular domains in basement membrane assembly

Laminins contribute to basement membrane assembly through interactions of their N- and C-terminal globular domains. To further analyze this process, recombinant laminin-111 heterotrimers with deletions and point mutations were generated by recombinant expression and evaluated for their ability to self-assemble, interact with nidogen-1 and type IV collagen, and form extracellular matrices on cultured Schwann cells by immunofluorescence and electron microscopy. Wild-type laminin and laminin without LG domains polymerized in contrast to laminins with deleted alpha1-, beta1-, or gamma1-LN domains or with duplicated beta1- or alpha1-LN domains. Laminins with a full complement of LN and LG domains accumulated on cell surfaces substantially above those lacking either LN or LG domains and formed a lamina densa. Accumulation of type IV collagen onto the cell surface was found to require laminin with separate contributions arising from the presence of laminin LN domains, nidogen-1, and the nidogen-binding site in laminin. Collectively, the data support the hypothesis that basement membrane assembly depends on laminin self-assembly through formation of alpha-, beta-, and gamma-LN domain complexes and LG-mediated cell surface anchorage. Furthermore, type IV collagen recruitment into the laminin extracellular matrices appears to be mediated through a nidogen bridge with a lesser contribution arising from a direct interaction with laminin.     

Analysis of human red cell spectrin tetramer (head-to-head) assembly using complementary univalent peptides.

The mass-driven assembly of spectrin dimers to form tetramers involves two equal head-to-head alpha-beta associations and requires at least 30 degrees C for interconversion to occur readily. In this paper, the properties of tetramer formation were investigated using two complementary univalent peptides (the alpha I domain and beta monomers). Since the alpha I domain lacks an essential nucleation site required for side-to-side (lateral) heterodimer assembly [Speicher et al. (1992) J. Biol. Chem. 267, 14775-14782], these two peptides can only assemble head-to-head at a single site. This head-to-head assembly readily occurs at lower temperatures, indicating the temperature barrier for dimer-tetramer interconversion is caused by a conformational constraint of the dimer. This constraint, a closed hairpin loop, is released when the laterally associated partner is removed. The univalent alpha I-beta binding affinity at 37 degrees C (Ka = 1.4 x 10(5) M-1) is similar to the dimer-tetramer association constant at the same temperature. As the temperature is decreased from 37 to 0 degrees C, the alpha I-beta binding affinity increases about 32-fold. In contrast with head-to-head associations involving dimers, the second-order rate constants of two complementary univalent peptides (i.e., alpha I and beta) are dramatically higher, and the estimated activation energy (about 50 kJ mol-1) is about 5-fold lower. An open dimer conformation is an obligatory high-energy intermediate required for dimer-tetramer interconversion, and opening the dimer hairpin loop contributes about 190 kJ mol-1 to the activation energy for tetramer association.(ABSTRACT TRUNCATED AT 250 WORDS)     

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

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

Properties of normal and mutant polypeptide fragments from the dimer self-association sites of human red cell spectrin

We have examined the properties and interactions of expressed polypeptide fragments from the N-terminus of the α-chain and the C-terminus of the β-chain of human erythroid spectrin. Each polypeptide comprises one complete structural repeating unit, together with the incomplete repeat that interacts with its partner when spectrin tetramers are formed. The shared repeat thus generated is made up of two helices from the C-terminal part of the β-chain and one helix from the N-terminus of the α-chain. Three mutant β-chain fragments with amino acid substitutions in the incomplete terminal repeat were also studied. The α- and β-chain fragments were both substantially monomeric, as shown by sedimentation equilibrium. Circular dichroism analysis and thermal denaturation profiles revealed that the complete repeat present in each fragment had entered the stable tertiary fold. Unexpectedly, the conformational stability of the folded β-chain repeat was found to be grossly perturbed by the mutations, all of them well beyond its C-terminal boundary; possible explanations for this phemomenon are considered. Sedimentation equilibrium showed that in equimolar mixtures the wild-type α- and β-chain peptides formed a 1:1 complex. Mixing curves, observed by circular dichroism, revealed that association was accompanied by an increase in α-helicity. From continuous-variation profiles an association constant in the range 1–2×10⁶ M^–1 was inferred. The association was unaffected by the apparently unstructured anionic tail of 54 residues, found at the C-terminus of the spectrin β-chain. Of the three mutations in the β-chain fragment, one (an Ala→Val replacement in the A helix segment of the incomplete repeat) had a relatively small effect on the association with the α-chain fragment, whereas Trp→Arg mutations in the A and in the remote B helix segments were much more deleterious. These observations are consistent with the relative severities of the haemolytic conditions associated with the mutations. Received: 10 August 1998 / Revised version: 13 October 1998 / Accepted: 13 October 1998     

Role of receptor tyrosine kinase transmembrane domains in cell signaling and human pathologies

Receptor tyrosine kinases (RTKs) conduct biochemical signals via lateral dimerization in the plasma membrane, and their transmembrane (TM) domains play an important role in the dimerization process. Here we present two models of RTK-mediated signaling, and we discuss the role of the TM domains within the framework of these two models. We summarize findings of single-amino acid mutations in RTK TM domains that induce unregulated signaling and, as a consequence, pathological phenotypes. We review the current knowledge of pathology induction mechanisms due to these mutations, focusing on the structural and thermodynamic basis of pathogenic dimer stabilization.     

Absence of subunits in high-molecular weight proteins (spectrin) of red cell membranes

It is shown that the high-molecular weight proteins (spectrin), which make up a large part of the total protein of the red cell membrane, are single polypeptide chains. They do not generate smaller subunits on treatment with dilute acid: it is shown that recent observations of the appearance of electrophoretic components of low molecular weight, following incubation in acid solution, and interpreted in terms of a subunit structure for the spectrin chains, can be attributed to degradation by endogenous proteases. It is shown that the experimental conditions used favour such degradation.     

Analysis of the spectrin binding domains of globin

This study describes the results of binding studies between human spectrin and peptides obtained by trypsin digestion of human globin. The globin digest when passed through an affinity column of spectrin-coupled sepharose retained one peptide from both alpha and beta chains of globin. The absorbed peptides were eluted with 4 M guanidine hydrochloride and separated on a reverse phase column by high pressure liquid chromatography. Their amino acid sequence was determined and their position located in the globin molecule.     

Properties of human red cell spectrin heterodimer (side-to-side) assembly and identification of an essential nucleation site.

The antiparallel side-to-side association of spectrin alpha and beta monomers is a two-step process which occurs in seconds even at 0 degrees C and at low concentrations. Assembly involves initial contact of complementary nucleation sites on each subunit, which are located near the actin binding end of the long, flexible heterodimer rod. The minimum nucleation sites are comprised of approximately four contiguous 106-residue homologous segments or repeats. Three repeats in the nucleation site contain an 8-residue insertion and have the highest homology to the four spectrin-like repeats in alpha-actinin. The adjacent actin binding domain on the beta subunit and the adjacent EF hand motifs on the alpha subunit are not required for heterodimer assembly. The nucleation sites probably have a specific lock and key structure which defines the unique side-to-side pairing of the many homologous segments in both subunits. Assembly of spectrin heterodimers is probably most analogous to a zipper. After initial nucleation site binding, the remainder of the subunits quickly associate along their full lengths to reconstitute a normal dimer by supercoiling around each other to form a rope-like, flexible rod. Assembly is terminated if either polypeptide is interrupted by a protease cleavage. Heterozygotic mutations involving either nucleation site are predicted to affect allele incorporation into the mature membrane skeleton.     

Structural analysis of homologous repeated domains in alpha-actinin and spectrin

The amino acid sequences of chick and slime mould alpha-actinin each contain four repeats of approximately 122 residues. These repeats are homologous to the 18-22 repeats, each of approximately 106 residues, found in the alpha and beta subunits of spectrin and fodrin, and to the multiple repeats of approximately 110 residues found in the Duchenne muscular dystrophy protein (dystrophin). The repeats correspond to the elongated rod-like portion of these molecules. We present a multiple sequence alignment of 21 repeats from this superfamily (8 alpha-actinin and 13 spectrin/fodrin), based on optimal pairwise alignments, from which a characteristic consensus pattern of amino acid types is deduced. Trp 46 is invariant in all but one repeat, and physicochemical classes of amino acids are conserved at 25 other positions. Secondary structure prediction on both the alpha-actinin and spectrin repeats taken together with the distribution of proline residues in the sequences, strongly suggest that each repeated domain consists of a four-helix structure. Our predictions differ significantly from previous three-helix models based on analyses of fewer sequences. To determine possible interdomain regions, sites of limited proteolysis of the native chick alpha-actinin dimer were determined and located in the amino acid sequence. The majority of these sites were in corresponding positions in different repeats within a segment predicted as a long helix. We propose a model, consistent with the overall dimensions of the rod-like portions of the molecules, in which these long, probably interrupted helices, link adjacent domains.     

Insights into the domains required for dimerization and assembly of human alphaB crystallin

Protein pin array technology was used to identify subunit-subunit interaction sites in the small heat shock protein (sHSP) alphaB crystallin. Subunit-subunit interaction sites were defined as consensus sequences that interacted with both human alphaA crystallin and alphaB crystallin. The human alphaB crystallin protein pin array consisted of contiguous and overlapping peptides, eight amino acids in length, immobilized on pins that were in a 96-well ELISA plate format. The interaction of alphaB crystallin peptides with physiological partner proteins, alphaA crystallin and alphaB crystallin, was detected using antibodies and recorded using spectrophotometric absorbance. Five peptide sequences including 37LFPTSTSLSPFYLRPPSF54 in the N terminus, 75FSVNLDVK82)(beta3), 131LTITSSLS138 (beta8) and 141GVLTVNGP148 (beta9) that form beta strands in the conserved alpha crystallin core domain, and 155PERTIPITREEK166 in the C-terminal extension were identified as subunit-subunit interaction sites in human alphaB crystallin using the novel protein pin array assay. The subunit-subunit interaction sites were mapped to a three-dimensional (3D) homology model of wild-type human alphaB crystallin that was based on the crystal structure of wheat sHSP16.9 and Methanococcus jannaschi sHSP16.5 (Mj sHSP16.5). The subunit-subunit interaction sites identified and mapped onto the homology model were solvent-exposed and had variable secondary structures ranging from beta strands to random coils and short alpha helices. The subunit-subunit interaction sites formed a pattern of hydrophobic patches on the 3D surface of human alphaB crystallin.     

Role of protein kinases of human red cell membrane in deformability and aggregation changes

The proteomic analysis has showed that red cell membrane contains several kinases and phosphatases. Therefore the aim of this study was to investigate the role of protein kinases of human red cell membrane in deformability and aggregation changes. Exposure of red blood cells (RBCs) to some chemical compounds led to change in the RBC microrheological properties. When forskolin (10 microM), an adenylyl cyclase (AC) and a protein kinase A (PKA) stimulator was added to RBC suspension, the RBC deformability (RBCD) was increased by 20% (p < 0.05). Somewhat more significant deformability rise appeared after RBC incubation with dB-AMP (by 26%; p < 0.01). Red cell aggregation (RBCA) was significantly decreased under these conditions (p < 0.01). Markedly less changes of deformability was found after RBC incubation with protein kinase stimulator C (PKC)--phorbol 12-myristate 13-acetate (PMA). This drug reduced red cell aggregation only slightly. It was inhibited red cell tyrosine phosphotase activity by N-vanadat and was obtained a significant RBCD rise and RBCA lowering. The similar effect was found when cells were incubated with cisplatin as a tyrosine protein kinase (TPK) activator. It is important to note that a selective TPK inhibitor--lavendustin eliminated the above mention effects. On the whole the total data clearly show that the red cell aggregation and deformation changes were connected with an activation of the different intracellular signaling pathways.     

Properties of red cell membrane proteins: mechanism of spectrin and band 4.1 interaction

Interactions between human red cell's band 4.1 and spectrin were studied by fluorescence resonance energy transfer and batch microcalorimetry techniques. The association constant (Ka = 8.6 X 10(7) M-1), the stoichiometry (one molecule of band 4.1 to one molecule of spectrin), the reversibility, and the enthalpy (delta H = -6 kcal/mol) were determined. A proton uptake was observed to take place as a result of the spectrin-band 4.1 complex formation. In addition to the protonation of the reaction products, the entropic contribution (-T delta S) has been observed to be responsible for approximately 50% of the binding free energy. We concluded that the environment plays a significant role in the stabilization of the complex. Since band 4.1 has been required for the maintenance of the cytoskeletal stability, small alterations of the binding energies or the degree of interaction could have a pronounced effect on the structure of the erythrocyte membrane.     

Role of protein kinases of human red cell membrane in deformability and aggregation changes

The proteomic analysis has shown that the red cell membrane contains several kinases and phosphatases. Therefore the aim of this study was to investigate the role of protein kinases of human red cell membrane in deformability and aggregation alterations. The exposure of red blood cells (RBCs) to some chemical compounds has led to a change in the RBC microrheological properties. When forskolin (10 μM), an adenylyl cyclase (AC) and a protein kinase A (PKA) stimulator were added to RBC suspension, the RBC deformability (RBCD) was increased by 20% (p<0.05). Somewhat more significant deformability rise appeared after RBC incubation with dB-AMP (by 26%; p<0.01). The red cell aggregation (RBCA) was significantly decreased under these conditions (p<0.01). Markedly less changes of deformability were found after RBC incubation with protein kinase stimulator C (PKC)—phorbol 12-myristate 13-acetate (PMA). This drug reduced the red cell aggregation only slightly. The red cell tyrosine phosphotase activity was changed by N-vanadat and a significant RBCD rise and RBCA lowering were obtained. The similar effect was found when the cells were incubated with cisplatin as a tyrosine protein kinase (TPK) activator. It is important to note that a selective TPK inhibitor—lavendustin eliminated the above mentioned effects.     

Interaction of calmodulin with the red cell and its membrane skeleton and with spectrin

The binding of calmodulin to red cell membrane cytoskeletons and to purified spectrin from red cells and bovine brain spectrin (fodrin) has been examined. Under physiological solvent conditions binding can be measured by ultracentrifugal pelleting assays. The membrane cytoskeletons contained a single class of binding sites, with a concentration similar to that of spectrin dimers and an association constant of 1.5 X 10(5) M-1. Binding is calcium dependent and is suppressed by the calmodulin inhibitor trifluoperazine. The binding showed a marked dependence on ionic strength, with a maximum at 0.05 M, and a steep dependence on pH, with a maximum at pH 6.5. It was unaffected by 5 mM magnesium. An azidocalmodulin derivative, under the conditions of our experiments, did not label the spectrin-containing complex, although it could be used to demonstrate binding to fodrin. Binding of calmodulin to spectrin tetramers and fodrin in solution could be demonstrated by a pelleting assay after addition of F-actin. Calculations (which are necessarily rough) suggest that at the free calcium concentration prevailing in a normal red cell about 1 in 20 of the calmodulin binding sites in spectrin will be occupied; this proportion will rise rapidly with increasing intracellular calcium. To determine whether inhibition of calmodulin binding to red cell proteins disturbs the control of cell shape, as has been suggested, calcium ions were removed from the cell by addition of an ionophore and of ethylene glycol bis(beta-aminoethyl ether)-N,N,N',N'-tetraacetic acid to the external medium. This did not affect the discoid shape. Trifluoperazine still induced stomatocytosis, exactly as in untreated cells.(ABSTRACT TRUNCATED AT 250 WORDS)     

Molecular recognition in dimerization between PB1 domains

The PB1 (Phox and Bem 1) domain is a recently identified module that mediates formation of a heterodimeric complex with other PB1 domain, e.g. the complexes between the phagocyte oxidase activators p67phox and p40phox and between the yeast polarity proteins Bem1p and Cdc24p. These PB1 domains harbor either a conserved lysine residue on one side or an acidic OPCA (OPR/PC/AID) motif around the other side; the lysine of p67phox or Bem1p likely binds to the OPCA of p40phox or Cdc24p, respectively, via electrostatic interactions. To further understand molecular recognition by PB1 domains, here we investigate the interactions mediated by proteins presenting both the lysine and OPCA on a single PB1 domain, namely Par6, atypical protein kinase C (aPKC), and ZIP. Par6 and aPKC form a complex via the interaction of the Par6 lysine with aPKC-OPCA but not via that between the aPKC lysine and Par6-OPCA, thereby localizing to the tight junction of epithelial cells. aPKC also uses its OPCA to interact with ZIP, another protein that has a PB1 domain presenting both the lysine and OPCA, whereas aPKC binds via the conserved lysine to MEK5 in the same manner as ZIP interacts with MEK5. In addition, ZIP can form a homotypic complex via the conserved electrostatic interactions. Thus the PB1 domain appears to be a protein module that fully exploits its two mutually interacting elements in molecular recognition to expand its repertoire of protein-protein interactions.