Identification of the primary caspase 3 cleavage site in alpha II-spectrin during apoptosis.

Alpha II-spectrin is one of the major proteins responsible for maintaining the cytoskeletal integrity of the cell. The caspase 3-mediated cleavage of alpha II-spectrin during apoptotic cell death may play an important role in altering membrane stability and the formation of apoptotic bodies. In this study, we identified the primary caspase 3 cleavage site in alpha II-spectrin. We found that the transcriptional inhibitor, actinomycin D, induced caspase 3 activation and that caspase 3 activation is coincident with the cleavage of alpha II-spectrin protein at a primary cleavage site. Deletion analysis and site directed mutagenesis identified the primary cleavage site in alpha II spectrin at amino acid 1185 (DETD). The primary caspase 3 cleavage site in alpha II spectrin is conserved in immature and mature B cells. Our results indicate that alpha II-spectrin is initially cleaved at a caspase 3 consensus site and this primary event likely alters the structural conformation of the protein exposing subsequent cleavage sites and altering cytoskeletal integrity. Identification of the primary cleavage site for caspase 3 may help to elucidate the role of alpha II-spectrin in membrane stability and apoptosis as well as provide new insights into alpha II-spectrin autoantibody formation associated with the autoimmune disease, Sjögren's syndrome.

Spectrin oligomerization is cooperatively coupled to membrane assembly: a linkage targeted by many hereditary hemolytic anemias?

In the erythrocyte, ankyrin is the major adapter protein linking tetramers of band 3 to the spectrin-actin cytoskeleton. This linkage involves a direct interaction between ankyrin and the 14th-15th repeat unit of beta-spectrin. The spectrin cytoskeleton itself is stabilized by the self-association of spectrin heterodimers into tetramers and larger oligomers, a process mediated by the 17th repeat unit of beta-spectrin and a short NH(2) -terminal sequence in alpha-spectrin. The self-association of spectrin and its ankyrin-mediated membrane binding have generally been considered independent events. We now demonstrate that spectrin self-association, the binding of spectrin to ankyrin, and the binding of ankyrin to the 43-kDa cytoplasmic domain of band 3 (cdb3) are coupled in a positively cooperative way. In solution, [(125)I]-labeled ankyrin was found by ND-PAGE3 to enhance the affinity of spectrin self-association by 10-fold. The reciprocal process was also true, in that spectrin tetramers and oligomers bound ankyrin with enhanced affinity relative to dimer spectrin. Saturation of the beta-spectrin self-association site by an NH(2) -terminal 80-kDa alpha-spectrin peptide enhanced the affinity of spectrin dimer for ankyrin, indicating a direct relationship between ankyrin binding and the occupancy of the beta-spectrin self-association site. cdb3 accentuated these cooperative interactions. Several inherited spectrin mutations that cause hemolytic disease but that do not directly destabilize the self-association or ankyrin-binding sites can be explained by these results. Three classes of mutations appear to disrupt cooperative coupling between self-association and ankyrin binding: (i) mutation of the linker sequences that join helices C and A in repeat units that intervene between the two functional sites, mutations that presumably block repeat-to-repeat transfer of conformational information; (ii) mutations in alpha-spectrin repeats 4 to 6 that disrupt the ability of this region to trans-regulate ankyrin binding by the adjacent beta-spectrin repeats 14-15; and (iii) exon-skipping mutations that shorten alpha-spectrin and force repeats 4 to 6 to fall out-of-register with the ankyrin-binding motif in beta-spectrin. Collectively, these results demonstrate a molecular mechanism whereby a membrane receptor can directly promote cytoskeletal assembly.

Transforming growth factor beta induces caspase 3-independent cleavage of alphaII-spectrin (alpha-fodrin) coincident with apoptosis.

Transforming growth factor beta (TGF-beta) is a potent growth inhibitor and inducer of cell death in B-lymphocytes and is essential for immune regulation and maintenance of self-tolerance. In this report the mouse immature B cell line, WEHI 231, was used to examine the mechanisms involved in TGF-beta-mediated apoptosis. Induction of apoptosis is detected as early as 8 h after TGF-beta administration. Coincident with the onset of apoptosis, the cytoskeletal actin-binding protein, alphaII-spectrin (alpha-fodrin) is cleaved into 150-, 115-, and 110-kDa fragments. The broad spectrum caspase inhibitor (Boc-D-fmk (BD-fmk)) completely abolished TGF-beta-induced apoptosis and alphaII-spectrin cleavage. Caspase 3, although present in WEH1 231 cells, was not activated by TGF-beta, nor was its substrate, poly(ADP-ribose) polymerase. These results identify alphaII-spectrin as a novel substrate that is cleaved during TGF-beta-induced apoptosis. Our data provide the first evidence of calpain and caspase 3-independent cleavage of alphaII-spectrin during apoptosis and suggests that TGF-beta induces apoptosis and alphaII-spectrin cleavage via a potentially novel caspase. This report also provides the first direct evidence of caspase 3 activation in WEH1 231 cells and indicates that at least two distinct apoptotic pathways exist.

Brain and muscle express a unique alternative transcript of alphaII spectrin.

Alternative splicing of pre-mRNA transcripts of alpha and beta spectrin has emerged as an important generator of diversity in this gene family, yet the functional consequences and extent of this diversity remains unknown. We have cloned and characterized full-length alphaII spectrin cDNA from human fetal brain (GenBank and ). On the basis of the predicted amino acid sequence, 11 amino acid substitutions, presumably representing polymorphisms, have been identified that distinguish this alphaII spectrin from human lung fibroblast alphaII spectrin. In addition, human fetal brain spectrin displays a novel five amino acid insertion in repeat 15 that arises from alternative mRNA splicing and that distinguishes this spectrin from lung fibroblast alphaII++ spectrin. This discovery, together with two previously identified regions of alternative mRNA splicing in alphaII spectrin suggest that as many as eight different splice forms of the mature protein might exist if all combinations (at inserts 1, 2, and 3) of alternative mRNA splicing are utilized. To assess this possibility, the tissue distribution of alternative exon usage was investigated by semiquantitative PCR with intron-jumping primer sets. Tissues examined were from mouse and included heart, kidney, lung, liver, thymus, spleen, brain, ovary, testis, and skeletal muscle, as well as mouse embryonic tissue. Transcripts both with and without insert 1, representing a 60 bp insertion within alphaII spectrin repeat 10, were identified in all tissues. In contrast, transcripts with insert 2, the novel 15 bp insertion reported here, were only expressed in brain, heart, skeletal muscle, and embryonic tissue. In all tissues examined only transcripts positive for insert 3, an 18 bp insertion in repeat 21, were amplified, even under conditions in which a 30% level of insert 3 negative transcript could be easily detected in artificially prepared control samples. All combinations of insert 1 and insert 2 were identified together in individual transcripts, verifying at least four distinct isoforms of alphaII spectrin. These have been named alphaIISigma1 through alphaIISigma4, in accord with current spectrin naming conventions. Dynamic molecular modeling of the 15th repeat unit incorporating insert 2 predicts that the spliced sequence forms a loop between helices A and B, and suggests that this insert might constitute a novel protein interaction site. The presence of this sequence in alphaIISigma3 and alphaIISigma4 spectrin suggests a specialized and heretofore unanticipated function for the 15th repeat of this molecule.

Site-directed mutagenesis of alpha II spectrin at codon 1175 modulates its mu-calpain susceptibility.

Intracellular proteolysis by the calpains, a family of Ca2+ activated cysteine proteases, is a ubiquitous yet poorly understood process. Their action is implicated in an array of cellular and pathologic processes, including long-term potentiation, synaptic remodeling, protein kinase C and steroid receptor activation, ischemic cellular injury, and apoptosis. Unlike most proteases, the calpains display unusually strict substrate specificity, often cleaving only one or two bonds in proteins with hundreds of potential sites. Studies of synthetic peptides have defined sequences that modulate their specificity, but little data exist in the context of a bona fide protein. A prominent substrate for mu-calpain is alpha II spectrin (fodrin, brain spectrin), which is cleaved between Tyr1176 and Gly1177 within spectrin's 11th structural repeat unit. We have cloned and characterized human fetal brain alpha II spectrin (GenBank no. U26396) and identified a new Thr1300 to Ile polymorphism. From this clone, recombinant GST-fusion proteins representing repeat units 8-14 have been prepared and used to systematically explore the in vitro determinants of mu-calpain sensitivity. Twenty different amino acids were substituted by site-directed mutagenesis for wild-type Val1175, the penultimate (P2) residue flanking the major calpain cleavage site in alpha II spectrin. Gly, Pro, and Asp, and to a lesser extent Phe and Glu, substantively inhibited the susceptibility of this site to mu-calpain; other substitutions yielded lesser effects. Dynamic molecular modeling of the 11th structural repeat of human alpha II spectrin incorporating the various mutations suggests that the calpain cleavage site with its flanking calmodulin binding domain interrupts helix C of alpha II spectrin's 11th repetitive unit without significantly disrupting the repeat's triple-helical motif. This model predicts that the critical Tyr1176-Gly1177 bond occurs in a highly exposed loop juxtaposed between helix C and the calmodulin binding domain and that mutations at the P2 position subtly alter the conformation about this site. We conclude that secondary and tertiary conformational features surrounding the cleavage site, rather than the linear sequence itself, dominate the determinants that define alpha II spectrin's mu-calpain susceptibility.

Alpha 1(E)-catenin is an actin-binding and -bundling protein mediating the attachment of F-actin to the membrane adhesion complex.

Calcium-dependent homotypic cell-cell adhesion, mediated by molecules such as E-cadherin, guides the establishment of classical epithelial cell polarity and contributes to the control of migration, growth, and differentiation. These actions involve additional proteins, including alpha- and beta-catenin (or plakoglobin) and p120, as well as linkage to the cortical actin cytoskeleton. The molecular basis for these interactions and their hierarchy of interaction remain controversial. We demonstrate a direct interaction between F-actin and alpha (E)-catenin, an activity not shared by either the cytoplasmic domain of E-cadherin or beta-catenin. Sedimentation assays and direct visualization by transmission electron microscopy reveal that alpha 1(E)-catenin binds and bundles F-actin in vitro with micromolar affinity at a catenin/G-actin monomer ratio of approximately 1:7 (mol/mol). Recombinant human beta-catenin can simultaneously bind to the alpha-catenin/actin complex but does not bind actin directly. Recombinant fragments encompassing the amino-terminal 228 residues of alpha 1(E)-catenin or the carboxyl-terminal 447 residues individually bind actin in cosedimentation assays with reduced affinity compared with the full-length protein, and neither fragment bundles actin. Except for similarities to vinculin, neither region contains sequences homologous to established actin-binding proteins. Collectively these data indicate that alpha 1 (E)-catenin is a novel actin-binding and -bundling protein and support a model in which alpha 1(E)-catenin is responsible for organizing and tethering actin filaments at the zones of E-cadherin-mediated cell-cell contact.

Diagnostic tests for choreoacanthocytosis.

Two patients with striatal atrophy and a clinical syndrome consistent with choreoacanthocytosis had normal dried blood smears but their red cells demonstrated an abnormal sensitivity to various conditions known to promote discocyte-echinocyte transformation. Dilution in normal saline, in vitro aging, and contact with glass caused a great proportion of these patients' red cells to develop multiple spiny or rounded projections. Under identical conditions, such shape changes did not occur in normal patients or in those with Huntington's disease. Scanning electron microscopy showed that the age-induced increase in acanthocytic-appearing cells could be reversed with chlorpromazine. These data suggest that the red cells from these patients with striatal degeneration are deficient in their ability to preserve normal shape in the face of echinocytic stress and that this observation has diagnostic and, possibly, pathophysiologic significance.

Ankyrin links fodrin to the alpha subunit of Na,K-ATPase in Madin-Darby canine kidney cells and in intact renal tubule cells.

In nonerythroid cells the distribution of the cortical membrane skeleton composed of fodrin (spectrin), actin, and other proteins varies both temporally with cell development and spatially within the cell and on the membrane. In monolayers of Madin-Darby canine kidney (MDCK) cells, it has previously been shown that fodrin and Na,K-ATPase are codistributed asymmetrically at the basolateral margins of the cell, and that the distribution of fodrin appears to be regulated posttranslationally when confluence is achieved (Nelson, W. J., and P. I. Veshnock. 1987. J. Cell Biol. 104:1527-1537). The molecular mechanisms underlying these changes are poorly understood. We find that (a) in confluent MDCK cells and intact kidney proximal tubule cells, Na,K-ATPase, fodrin, and analogues of human erythrocyte ankyrin are precisely colocalized in the basolateral domain at the ultrastructural level. (b) This colocalization is only achieved in MDCK cells after confluence is attained. (c) Erythrocyte ankyrin binds saturably to Na,K-ATPase in a molar ratio of approximately 1 ankyrin to 4 Na,K-ATPase's, with a kD of 2.6 microM. (d) The binding of ankyrin to Na,K-ATPase is inhibited by the 43-kD cytoplasmic domain of erythrocyte band 3. (e) 125I-labeled ankyrin binds to the alpha subunit of Na,K-ATPase in vitro. There also appears to be a second minor membrane protein of approximately 240 kD that is associated with both erythrocyte and kidney membranes that binds 125I-labeled ankyrin avidly. The precise identity of this component is unknown. These results identify a molecular mechanism in the renal epithelial cell that may account for the polarized distribution of the fodrin-based cortical cytoskeleton.

Phosphorylation of ankyrin down-regulates its cooperative interaction with spectrin and protein 3.

Ankyrin mediates the primary attachment between beta spectrin and protein 3. Ankyrin and spectrin interact in a positively cooperative fashion such that ankyrin binding increases the extent of spectrin tetramer and oligomer formation (Giorgi and Morrow: submitted, 1988). This cooperative interaction is enhanced by the cytoplasmic domain of protein 3, which is prepared as a 45-41-kDa fragment generated by chymotryptic digestion of erythrocyte membranes. Using sensitive isotope-ratio methods and nondenaturing PAGE, we now demonstrate directly (1) the enhanced affinity of ankyrin for spectrin oligomers compared to spectrin dimers; (2) a selective stimulation of the affinity of ankyrin for spectrin oligomer by the 43-kDa cytoplasmic domain of protein 3; and (3) a selective reduction in the affinity of ankyrin for spectrin tetramer and oligomer after its phosphorylation by the erythrocyte cAMP-independent membrane kinase. The phosphorylation of ankyrin does not affect its binding to spectrin dimer. Ankyrin also enhances the rate of interconversion between dimer-tetramer-oligomer by 2-3-fold at 30 degrees C, and in the presence of the 43-kDa fragment, ankyrin stimulates the rate of oligomer interconversions by nearly 40-fold at this temperature. These results demonstrate a long-range cooperative interaction between an integral membrane protein and the peripheral cytoskeleton and indicate that this linkage may be regulated by covalent protein phosphorylation. Such interactions may be of general importance in nonerythroid cells.