Abstract
The cells in animals face unique demands beyond those encountered by their unicellular eukaryotic ancestors. For example, the forces engendered by the movement of animals places stresses on membranes of a different nature than those confronting free-living cells. The integration of cells into tissues, as well as the integration of tissue function into whole animal physiology, requires specialisation of membrane domains and the formation of signalling complexes. With the evolution of mammals, the specialisation of cell types has been taken to an extreme with the advent of the non-nucleated mammalian red blood cell. These and other adaptations to animal life seem to require four proteins—spectrin, ankyrin, 4.1 and adducin—which emerged during eumetazoan evolution. Spectrin, an actin cross-linking protein, was probably the earliest of these, with ankyrin, adducin and 4.1 only appearing as tissues evolved. The interaction of spectrin with ankyrin is probably a prerequisite for the formation of tissues; only with the advent of vertebrates did 4.1 acquires the ability to bind spectrin and actin. The latter activity seems to allow the spectrin complex to regulate the cell surface accumulation of a wide variety of proteins. Functionally, the spectrin–ankyrin–4.1–adducin complex is implicated in the formation of apical and basolateral domains, in aspects of membrane trafficking, in assembly of certain signalling and cell adhesion complexes and in providing stability to otherwise mechanically fragile cell membranes. Defects in this complex are manifest in a variety of hereditary diseases, including deafness, cardiac arrhythmia, spinocerebellar ataxia, as well as hereditary haemolytic anaemias. Some of these proteins also function as tumor suppressors. The spectrin–ankyrin–4.1–adducin complex represents a remarkable system that underpins animal life; it has been adapted to many different functions at different times during animal evolution.
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Discovery of the spectrin–ankyrin–4.1–adducin system
Mammalian red blood cells have no nuclei or other internal organelles; thus, they have no major biosynthetic repair mechanisms. Despite this, they survive in circulation for about 120 days. This implies that their membranes have some adaptation that allows them to survive for this length of time—an unsupported lipid bilayer would be unable to endure the rigours of circulation.
Spectrin
Membranes can be isolated from human erythrocytes by hypotonic lysis (Dodge et al. 1963): since they retain the “ghostly” outline of the original cell, these are usually referred to as ghosts. Ghosts, however, become unstable when they are exposed to very low ionic strength, slightly alkaline solutions: for example, incubation of ghosts at 37° for 30 min in a solution of 0.1 mM sodium phosphate pH 8 results in rapid fragmentation of the membranes and the formation of inside–out vesicles (Steck et al. 1970). Among the proteins that are released from red cell membranes under these conditions are a pair of high molecular weight polypeptides named spectrin (Marchesi and Steers 1968; Tillack et al. 1970; another word for a ghost is a spectre, hence spectrin). These high molecular weight peptides are referred to now as α- and β-spectrins (280 and 246 kDa based on their sequences), although other literature named them band 1 and band 2, respectively, because they were represented in the two highest molecular mass proteins on sodium dodecyl sulphate (SDS) polyacrylamide gels (Fairbanks et al. 1971).
Analysis of the 37°C extract of red cell membranes indicated that α- and β-spectrins formed a dimer (Gratzer and Beaven 1975; Ralston 1975; Shotton et al. 1978; Ungewickell and Gratzer 1978; Ralston and Dunbar 1979). However, if the extraction was done at 4°, spectrin was recovered predominantly as a tetramer comprising two dimers. Careful analysis of the chemical equilibrium between dimers and tetramers revealed that tetramers were the most abundant physiological form of spectrin; however, at 37°C, when spectrin was diluted by being removed from the membrane, the tetramers rapidly dissociated to dimers (e.g. Ungewickell and Gratzer 1978). Higher-order oligomers could also form; thus, in whole red cells, the highly concentrated nature of spectrin attached to the membrane means that there is an equilibrium between dimers, tetramers, hexamers and so on, with the tetramer apparently most abundant (Morrow and Marchesi 1981; Shahbakhti and Gratzer 1986).
Ankyrin—a linker between spectrin and the membrane
Spectrin seems to be important to the integrity of the red cell membrane, since its loss from the membrane results in fragmentation. How is it attached to the membrane? Bennett and Branton (1977) conducted a pioneering series of experiments in which they demonstrated that, in physiological salt solutions, spectrin can bind to the cytoplasmic face of inside–out vesicles. The “spectrin receptor” was a protein since it was susceptible to proteolysis and present at approximately one per tetramer (Bennett and Stenbuck 1979a). This receptor was identified as the protein ankyrin (Bennett and Stenbuck 1979a, 1980b; Yu and Goodman 1979). Ankyrin itself could be removed from membranes with concentrated salt solutions and thus was a peripheral protein. An “ankyrin receptor” was identified as Band 3, an anion (HCO -3 /Cl-) exchanger essential in carbon dioxide transport processes (Bennett and Stenbuck 1979b, 1980a). More recently, it has become clear that ankyrin binds a number of other transmembrane proteins including the Rhesus complex which probably functions as a transporter for small neutral substrates (Nicolas et al. 2003).
4.1, adducin and the actin junctional complex
Along with spectrin, some other proteins are released from the membrane in very low salt solutions. Among these is actin (Tilney and Detmers 1975). Mature human erythrocytes contain essentially only β-actin (Pinder et al. 1978b). Does spectrin bind actin? Early data indicated that spectrin could interact with actin although the mode was unclear (Pinder et al. 1975; Tilney and Detmers 1975; Kirkpatrick 1976; Sheetz et al. 1976) and the affinity was very weak (Ohanian et al. 1984). Furthermore, spectrin could act as a bridge between cytoplasmic actin and the membrane (Cohen et al. 1978; Cohen and Foley 1980; Fowler et al. 1981). The weak affinity prompted a number of workers to investigate whether there were factors that modulated the interaction with F-actin. Among the other proteins present in the red cell membrane low ionic strength extract is protein 4.1, which appears on SDS gels as a closely spaced doublet of bands at approximately 80 kDa (Yu et al. 1973). Protein 4.1 binds to spectrin (Tyler et al. 1980) and promotes the binding of spectrin to actin (Ungewickell et al. 1979; Fowler and Taylor 1980). Ohanian and coworkers (1984) quantified the interactions: in the absence of 4.1, the spectrin–F-actin interaction was characterised by a Ka approximately 1 × 103 M-1; in its presence, a ternary complex formed with an affinity around 1012 M-2.
Two further polypeptides present in the low salt extract had apparent molecular masses around 110 kDa. These were found to represent subunits of a calmodulin-binding phosphoprotein that contained a spectrin–actin-binding activity (Palfrey and Waseem 1985; Gardner and Bennett 1986; Ling et al. 1986; Mische et al. 1987). These were named α- and β-adducin because they can “adduce” (Latin adducere: ad-, to bring to + ducere, to lead) the formation of a spectrin–actin complex (Gardner and Bennett 1987). The protein is primarily a heterotetramer, and the interaction of the two subunits is required for high-affinity spectrin/actin binding (Matsuoka et al. 2000). The calmodulin-binding activity is confined to a basic 22 amino acid sequence near the C-terminal which has close sequence similarity to the calmodulin-binding region of myristoylated alanine-rich C-kinase substrate (MARCKS; Matsuoka et al. 1996). Its protein interactions are also regulated by protein kinase C, protein kinase A and by rho-kinase (Matsuoka et al. 1996, 1998; Waseem and Palfrey 1988, 1990; Kimura et al. 1998).
Further actin-binding proteins identified in the low salt extract protein include 4.9 (also known as dematin; Beaven et al. 1985a; Siegel and Branton 1985; Husain-Chishti et al. 1989), tropomyosin (Fowler and Bennett 1984) and tropomodulin (Fowler 1990).
The triton-resistant cytoskeleton and the state of erythrocyte actin
Further evidence for the presence of complexes between spectrin, ankyrin, 4.1, F-actin and other proteins came from extraction of red cell membranes with the detergent Triton X-100. The Triton X-100 insoluble residue represents a cytoskeletal structure, which retains the core cytoskeletal proteins plus a number of transmembrane proteins (Yu et al. 1973). Fractions of, for example, the anion exchanger band 3 (Yu et al. 1973; Sheetz 1979), glycophorin C (Reid et al. 1990) and Rhesus complex (Bruce et al. 2003) are retained in the detergent cytoskeleton: these can be removed by washing with concentrated salt solutions in the presence of detergent, a treatment which also removes ankyrin. The resulting high salt cytoskeleton, or shell, retains spectrin, 4.1, adducin and proteins of the actin complex (Sheetz 1979).
Electron microscopy of cytoskeletons or shells revealed a more or less hexagonal network of long spectrin filaments (mainly, tetramers, plus hexamers and higher-order oligomers) interconnected by junction points (Byers and Branton 1985; Beaven et al. 1985b; Liu et al. 1990a; Ursitti and Fowler 1994). Ankyrin-based complexes sat near to the sites where spectrin dimers formed tetramers (Liu et al. 1987), consistent with the electron microscopy of purified spectrin–ankyrin complexes (Tyler et al. 1979). Actin as well as its other binding partners was found at junction points where spectrin molecules come together (Ursitti and Fowler 1994).
An unusual aspect of the actin junction points is that no long actin filaments were visible in intact preparations (Tilney and Detmers 1975; Byers and Branton 1985). This is not because erythrocyte actin is incapable of forming long filaments: limited proteolysis releases constraints on actin polymerisation, and long filaments are then readily formed (Tilney and Detmers 1975). Pinder and Gratzer (1983) investigated the nature of actin in red cell membranes and concluded that it was restricted to short filaments (12 to 16 monomers) that would be of the right length to accommodate a single tropomyosin. The minus-ends of the filaments are blocked by tropomodulin (Fowler 1990). Whether the plus-ends were capped depended on whether the ghosts were prepared in the presence of Mg2+: the plus-end was uncapped in the absence of Mg2+; the presence of 2 mM Mg2+ in the lysis buffer was found to preserve the actin filaments in a capped state (Kuhlman 2000). The plus-end capping was found to be attributable to adducin, which was released from the membranes in the absence of Mg2+.
Several factors probably contribute to keeping the actin filaments short in the junctional complex. The plus-end capping activity of adducin together with tropomodulin may cap the filaments in red cells (Kuhlman et al. 1996). Spectrin and 4.1 together have an F-actin severing and capping activity (Pinder et al. 1984). In addition, the ubiquitous capping protein capZ is present in red cells (Kuhlman and Fowler 1997). However, capZ appears to be displaced from the end of actin filaments by adducin, and in mature cells, it is only cytoplasmic (Kuhlman and Fowler 1997).
In summary, we now have a picture of a red cell cytoskeleton that forms a roughly hexagonal array on the cytoplasmic face of the membrane. Spectrin filaments are cross-linked by actin-containing junction points. Ankyrin forms an adaptor between spectrin and the membrane; ankyrin cross-links links with transporters that include the Rhesus complex and the anion exchanger. In addition, as will be described below, the actin junctions are also linked to the plasma membrane via transmembrane complexes. Moreover, spectrin and protein 4.1 bind PIP2 (An et al. 2005a, 2006b). Spectrin also binds to some aminophospholipids including phosphatidylserine (Haest et al. 1978; Mombers et al. 1979; Cohen et al. 1986; Michalak et al. 1993; An et al. 2004). The interaction of spectrin with aminophospholipids modulates membrane stability (Manno et al. 2002). A minority of β-spectrin is palmitoylated in red cells, and this seems to strengthen its association with the membrane (Mariani et al. 1993).
Genes and proteins
Spectrins
The sequences of human α- and β-spectrin from red blood cells were first obtained by direct protein sequencing (Speicher et al. 1983; Speicher and Marchesi 1984) and, subsequently, by cDNA cloning (Linnenbach et al. 1986; Cioe et al. 1987; Winkelmann et al. 1988, 1990a; Sahr et al. 1989, 1990;). More recently, the sequences of spectrin genes from many different organisms have been revealed by genomics.
Mammals have seven spectrin genes: two α-genes (SPTA1 and SPTAN1 encoding αI- and αII-spectrins, respectively), four “conventional” β-genes (SPTB, SPTBN1, SPTBN2 and SPTBN4 encoding βI to βIV, respectively) and SPTBN5 encoding one β-heavy (βV)-spectrin. Invertebrates have a single α-, “conventional” β- and βV-spectrin genes. During the evolution of the invertebrates, there were two rounds of whole genome duplication (the 2R hypothesis), i.e. for each ancestral gene, vertebrates could have up to four paralogues (Kasahara 2007). The expectation of four paralogues seems to be met by the conventional β-genes, but not by the α- or βV-genes, which are clearly not advantageous when retained in full complement. Moreover, the duplication of α genes that we see represented in mammalian genomes is a late evolutionary event. The genomes of amphibia, birds and reptiles only contain single α-spectrin genes, and it seems that the duplication of α occurred with the advent of the mammals since it is found in all three branches of the mammalia (Salomao et al. 2006). In the lineage leading to the bony fish, a further round of duplication occurred (Van de Peer 2004), but it does not seem to have been advantageous to retain function of all the duplicates: for example, a duplicate of the α-gene is present in zebra fish as a non-expressed pseudogene (Salomao et al. 2006).
Spectrins can be defined by their domain structure. The bulk of the polypeptide comprises successive repeating units of approximately 106 amino acids (Speicher and Marchesi 1984; Fig. 1a,c). These repeating units are now referred to as spectrin repeats: these are folded as triple helical bundles (Yan et al. 1993; Pascual et al. 1996). Typically, α-spectrin contains about 20 complete repeats, conventional β16 and β-heavy about 29. In spectrin chains, successive triple helices connect through the junction of helix C of one repeat to helix A of the next in an uninterrupted helix (see Fig. 1; e.g. Kusunoki et al. 2004). In addition, as explained more fully below, partial triple helices define the sites where spectrin dimers self-associate.
At the N-terminus of β, there is a pair of calponin homology (CH) domains which together form an actin-binding domain (ABD; Karinch et al. 1990; Carugo et al. 1997; Banuelos et al. 1998). The ABD also binds 4.1, and the formation of a three-way complex between 4.1, spectrin and actin effectively strengthens the interaction of spectrin with actin (An et al. 2005a). The ABD also binds the lipid PIP2, and this promotes 4.1 binding (An et al. 2005a; Fig. 1b).
In α-spectrins, there is an SH3 domain inserted between repeats 9 and 10 (Musacchio et al. 1992). At the C-terminus is a calmodulin-like domain which contains four EF hands, of which two bind calcium (Trave et al. 1995). These have recently been reported to bind erythrocyte protein 4.2 (Korsgren et al. 2009).
To form a dimer, α- and β-spectrin chains interact via two repeats close to the C-terminus of α (repeats 20 and 21) and the N-terminus of β (repeats 1 and 2; see Fig. 1 and Ursitti et al. 1996; Viel et al. 1998). This forms an anti-parallel dimer, with the calmodulin-like domain opposed to the ABD.
To form a tetramer, at the other end of the dimer, the partial repeats in both α (repeat 1) and β (repeat 17) can interact with the corresponding partial repeats in another dimer to form a tetramer (Tse et al. 1990; Kotula et al. 1993; Cherry et al. 1999; Ipsaro et al. 2010). Thus, the tetramer is formed by “reconstituting” a full triple helix from the pair of partial triple helices (Fig. 1f).
Repeats 14 and 15 of the conventional β-spectrins bind ankyrin (Kennedy et al. 1991; Davis et al. 2008; Ipsaro et al. 2009; Stabach et al. 2009). Because there are two β-spectrins in each tetramer, each tetramer potentially binds two ankyrins: there is evidence of cooperativity between ankyrins in binding to spectrin (Cianci et al. 1988; Fig. 1d).
In α, the region between repeats 9 and 11 (which includes the SH3 domain) contains a plethora of binding sites. These include sites for binding the lipid phosphatidylserine (An et al. 2005b). The proteins that interact here include the non-receptor tyrosine kinase src (Nicolas et al. 2002; Nedrelow et al. 2003), a low molecular weight tyrosine phosphatase (Nicolas et al. 2002), tes and evl (Rotter et al. 2005; Bournier et al. 2006) and e3b1 (Ziemnicka-Kotula et al. 1998). These interactions of the SH3 domain may be linked to the control of cell motility (Merilainen et al. 1993). In addition, a differentially spliced sequence binds calmodulin in αII-spectrin (Simonovic et al. 2006).
The C-terminal region of β-spectrins can be subject to differential messenger ribonucleic acid (mRNA) splicing, which regulates both membrane binding and regulatory properties (Winkelmann et al. 1990b; Hayes et al. 2000). The ancestral β-spectrin common to all eumetazoans contained a C-terminal pleckstrin homology domain which binds to PIP2 via its head group IP3 (Macias et al. 1994; Zhang et al. 1995; Fig. 1e). This domain, additionally, seems to have a role in sorting spectrins in polarised cells (Das et al. 2008). In mammalian βI- and βII-spectrins, splicing can eliminate the PH domain and replace it with a short, relatively unstructured region containing phosphorylation sites (Winkelmann et al. 1990b; Hayes et al. 2000; Tang and Speicher 2004; Bignone et al. 2007). These short C-termini seem to have arisen independently after the duplication events encompassed in the 2R hypothesis, and certainly, the sequences, gene structures and phosphorylation sites in these regions are quite different from each other (Bignone et al. 2007). The function of phosphorylation of the short βI-spectrin C-terminal region is not known; it does not appear to regulate the formation of tetramers (Ungewickell and Gratzer 1978; Shahbakhti and Gratzer 1986), but it seems to be linked to the mechanical properties of red cell membranes (Manno et al. 1995). On the other hand, phosphorylation of the short βII-spectrin has a functional correlate, namely, regulation of the interaction of formation of spectrin tetramers (Bignone et al. 2007). Phosphorylation of the short C-terminal region by protein kinase A leads to a reduction in the affinity of αII and βII at the site where tetramers form. This phosphorylation appears to occur during neurite outgrowth.
Although there are multiple vertebrate spectrin polypeptides, detailed biochemical and biophysical comparisons between them remain incomplete. The best characterised polypeptides in those terms are the two mammalian α-spectrins (αI- and αII-spectrins) and βI- and βII-spectrins.
When spectrin was isolated from red cells at 37°C, it was recovered as a dimer (Ungewickell and Gratzer 1978). On the other hand, when spectrin was isolated from the brain, primarily, it was a tetramer (Bennett et al. 1982a; Glenney et al. 1982d; Davis and Bennett 1983). This is because the principal constituents of each (αI–βI from red cell; αII–βII from brain) vary in their relative affinity at the site were tetramers form. Experiments with fragments of spectrin containing the binding sites indicated that as monomers, αI and βI associate with K D approximately 800 nM (Kotula et al. 1993; Nicolas et al. 1998; Cherry et al. 1999; Bignone and Baines 2003). By comparison, equivalent fragments of αII- and βII-spectrins associated with K D approximately 10 nM (Bignone and Baines 2003). The affinity is primarily dictated by the partial repeats (one helix from α and two from β) that directly associate to recapitulate a full triple helix. In addition, experiments with chimeras revealed that the adjacent full triple helical repeat affected affinity as well (Bignone and Baines 2003).
The relatively low affinity of the red cell spectrin tetramer raises the question of whether or not spectrin tetramers—- even though they are highly concentrated on red cell membranes—- dissociate during circulation. Mohandas and co-workers (An et al. 2002) have investigated this by sealing into ghosts fragments of spectrin that contain the partial repeats. They found that at 37°, the partial repeats became incorporated into the membrane, i.e. they associated at the ends of spectrin dimers. As a result, the fragments acted as dominant negative inhibitors of the formation of tetramers. Furthermore, these fragments acted to destabilise the red cell membrane, and their affinity was reflected in their potency in this respect. Fragments of αI-spectrin were two orders of magnitude less potent in terms of destabilising red cell membranes against shear stress than fragments of αII-spectrin (Salomao et al. 2006).
In evolution, αI-spectrin arose by duplication of the pre-existing α-spectrin gene at about the same time as non-nucleated mammalian red cells appeared (Salomao et al. 2006). Evidently, it has been neo-functionalised to support the rapid making and breaking of spectrin tetramers in non-nucleated red cells undergoing shearing forces in circulation.
The biophysical properties of αI- and αII-spectrins vary. Experiments to measure the thermal denaturation of fragments of spectrin polypeptides revealed that, in general, the triple helical repeats in αII-spectrin denature at a higher temperatures than those of αI-spectrin (An et al. 2006a, c). In particular, in αI and βI, some repeats in the centre of the molecule are probably on the edge of being unfolded even at 37°. αI repeats 4, 6, 8, 11 and 12 all had mid-points of thermal denaturation below 37°. Experiments on a construct of βI-spectrin repeats 5–9 showed substantial loss of α-helicity even below 37°. Even more strikingly, in this construct, two repeats lost resistance to pulling in the atomic force microscope at or below 33°, indicating that, physiologically, they are probably in a relatively unfolded state.
To test the state of these repeats in whole membranes, Johnson et al. (2007b) investigated the accessibility of cysteine residues. In the linker region between βI-spectrin repeats 8 and 9, cysteine 1167 is occluded in the folded structure (PDB: 1 S35; Fig. 1c). When red cell membranes were subjected to a shear stress, this cysteine became available to a chemical reagent. In all, at least six cysteines became available for chemical modification upon shearing the cell membranes. The implication here is that spectrin responds to the shearing forces encountered in circulation by at least partially unfolding and acting to some extent as a spring. In this sense, spectrin has the potential to act as a sensor for mechanical forces acting on a cell membrane. Mutations that affect folding also have an effect on red cell stability. The mutation Q471P in αI-spectrin is in the linker between repeats 4 and 5. The effect of this mutation is to destabilise the folding of spectrin; this manifests itself in the hereditary haemolytic anaemia elleptocytosis (Johnson et al. 2007a).
Spectrin polypeptides can also form “mixed” tetramers. This was indicated first by the observation that chicken epithelial spectrin has a common α-subunit, but two β-subunits (i.e. basolateral βII and apical TW-260/βV; Glenney et al. 1982a). In vitro, the subunits of native spectrin tetramers can readily be separated by the use of moderate concentrations of urea, followed by hydroxyapatite chromatography (Yoshino and Marchesi 1984). After separation, they could reform tetramers once returned to physiological salt solutions. Davis and Bennett (1983) showed that the separated subunits of spectrin purified from brain (i.e. mostly αII- and βII-spectrin) could form hybrid tetramers with erythrocyte αI- and βI-spectrins. In many tissues, multiple-spectrin genes are expressed: can they form mixed tetramers? Clark et al. (1995) showed by immunoprecipitation that spectrin from cerebellum could contain hybrid tetramers in which two different spectrin β-subunits could co-exist.
Ankyrins
Vertebrates have three ankyrin genes (ANK1-3) encoding ankyrin-R, ankyrin-B and ankyrin-G, respectively. Ankyrin-R is the mammalian erythrocyte ankyrin (Lux et al. 1990; Otto et al. 1991; Peters et al. 1995; Kordeli et al. 1995). Invertebrates generally have a single ankyrin, but in the lineage from which arthropods descend, a gene duplication occurred, thus they have two ankyrins (Hortsch et al. 2002; Hopitzan et al. 2006).
Ankyrins are subject to regulation by extensive differential mRNA splicing, but their canonical forms (about 200–250 kDa) have a common domain structure (Fig. 2). An N-terminal region contains 24 ank repeats, short helix–loop–helix structures which form ligand-binding sites (Michaely et al. 2002; Fig. 2a and b). Ank repeats are widespread in evolution, and very commonly, groups of 2–4 sequential ank repeats can bind ligands with high affinity (Li et al. 2006; Stumpp and Amstutz 2007; Lowe et al. 2008). Because canonical ankyrins contain 24 repeats, they have the potential to cross-link more than one membrane protein: as an example of this, in heart, ankyrin-B forms a complex with the Na/Ca exchanger (NCX1), IP3 receptor and the Na/K-ATPase (Mohler et al. 2003).
More centrally, a ZU5 domain binds spectrin (Ipsaro et al. 2009, 2010; Fig. 2c). This domain was originally defined as common to ZO-1 and Unc5-like netrin receptors (Interpro: IPR000906). It is about 150 amino acids in length and is folded with a core containing two β-sheets; two short helices abut one face of the sheets, the whole structure being connected by a series of solvent-exposed loops (Ipsaro et al. 2009). A death domain, a bundle of six α-helices, which forms another site for protein–protein interactions, is found more towards the C-terminus (Mohler et al. 2002; Del Rio et al. 2004; Fig. 2d).
Beyond these common elements of structure in the canonical forms, there is tremendous sequence variation via differential mRNA splicing. For example, some forms lack the ank repeats in part or in whole (e.g. Peters et al. 1995; Gagelin et al. 2002; Hopitzan et al. 2005). In the case of some small isoforms found in muscle saroplasmic reticulum (ank1.5, 17.5 kDa), a short N-terminal transmembrane segment anchors it to the membrane, but it lacks all the canonical domains (Bagnato et al. 2003; Kontrogianni-Konstantopoulos et al. 2003; Porter et al. 2005). However, some muscle ankyrins contain a 76 amino acid domain that binds obscurin and (possibly) titin (OTBD; Hopitzan et al. 2006; Borzok et al. 2007). In giant ankyrins, differentially spliced inserts raise the size to over 400 kDa: in the case of the giant ankyrin-G found at nodes of Ranvier, the insert is thought to be extended, potentially allowing this polypeptide to communicate between the plasma membrane and deep into the interior of the axon (Kordeli et al. 1995).
Protein 4.1
Protein 4.1, like spectrin and ankyrin, appeared early in animal evolution; single copies characterise all known invertebrate eumetazoan genomes (Hoover and Bryant 2000). As with spectrin and ankyrin, vertebrates have more copies of 4.1 genes. All four have been retained: the gene EPB41 encodes 4.1R; EPB41L1 encodes 4.1N; EPB41L2 encodes 4.1G; EPB41L3 encodes 4.1B (Conboy et al. 1986; Parra et al. 1998, 2000; Tran et al. 1999; Walensky et al. 1999). Protein 4.1R is so named because it is the abundant red cell 4.1, although it is expressed in many other cell types. The other three are essentially absent from red cells, but expressed widely in other cell types (Taylor-Harris et al. 2005a).
The four vertebrate proteins have a common domain structure (Fig. 3). Two of these domains—the 4.1 protein, ezrin, radixin and moesin (FERM) domain (Chishti et al. 1998) and the C-terminal domain (CTD; Scott et al. 2001)—can bind transmembrane proteins, and one—the spectrin–actin-binding (SAB) domain (Correas et al. 1986a, b; Discher et al. 1993, 1995)—provides the cytoskeletal linkage. Protein 4.1N is an exception to the last of these: its SAB is so divergent that it does not bind spectrin–actin (Gimm et al. 2002). Adjacent to the FERM domain is a FERM-adjacent (FA) domain (Baines 2006).
The FERM domain is so named because it is common to 4.1 (four-point-one), ezrin, moesin and radixin (Chishti et al. 1998). The fold consists of three globular units of approximately 100 amino acids each arranged as a cloverleaf-like structure (Han et al. 2000a). The N-terminal lobe (lobe A) has a ubiquitin-like fold, the central lobe (lobe B) has an α-helical fold like acyl-CoA-binding protein, and the C-terminal lobe (lobe C) has a fold like a pleckstrin homology domain (Han et al. 2000b). Since the determination of the structures of prototypical FERM domains, it has become apparent that FERM domains are widespread in evolution, and can be very divergent in sequence, while retaining the same fold (Tepass 2009).
Interspersed between the common domains are unconserved regions that show far less sequence identity between the individual proteins. These regions, U1, U2 and U3, are generally not well understood in terms of their functions. In 4.1R, the U1 region binds calmodulin (Leclerc and Vetter 1998) and the centrosomal P4.1-associated protein (CPAP; Hung et al. 2000). This region has also been reported to modulate nuclear import of 4.1R (Gascard et al. 1998, 1999; Luque and Correas 2000), suggesting regulation of protein 4.1 properties and function through intramolecular interactions between functional domains. Protein kinase C-dependent phosphorylation of a Ser residue within the FA region has been established to modulate interactions of adjacent FERM and SAB domains with selected binding partners (Manno et al. 2005). The U2 region has also been recently reported to confer upon 4.1B its anti-proliferative properties (Robb et al. 2005). As yet, no function has been assigned to the U3 region.
In the case of 4.1R, the major 80 kDa erythrocyte form appears as two closely spaced bands on SDS gels, known as a and b forms. They are related by deamidation of two asparagine residues, a process that occurs progressively as red cells age (Inaba et al. 1992). In this sense, the 4.1Ra: 4.1Rb ratio is a marker for red cell age (Inaba et al. 1992).
One of the common aspects of the 4.1 proteins is that they are subject to extensive tissue- and development-specific mRNA splicing. This is best established for 4.1R, where of the >20 exons of the gene, more than half are subject to splicing (Conboy 1999). This regulates cytoskeletal interaction and intracellular targeting (Conboy 1999; Gascard et al. 1999; Luque et al. 1999; Luque and Correas 2000). In the kidney (Ramez et al. 2003; Gascard et al. 2004) and heart (Taylor-Harris et al. 2005b), all the 4.1 proteins are subject to splice regulation, and this now appears to be common to most, if not all, tissues (Parra et al. 2004).
The FERM domain represents a site where numerous regulatory pathways converge. It has binding sites for calmodulin (Nunomura and Takakuwa 2006), phosphatidylserine (An et al. 2001) and PIP2 (An et al. 2006b); phosphorylation affects its activities (Manno et al. 2005), as noted above; and the U1 region, which is alternatively spliced, regulates its activities (Nunomura et al. 2009). As we shall see below, the FERM domain contains distinct binding sites for several membrane proteins, and these are differentially regulated by these factors. The FERM domain itself can also be spliced: the N-terminal lobe can be lost if initiation of translation is begun in exon 8 (Gascard et al. 1998; Luque et al. 1998). The 4.1 FERM domain therefore represents a most unusual nexus of regulation in response to signals regulating gene expression, signalling through protein kinases and Ca2+ and via the availability of phosphorylated lipids.
Adducin
Vertebrates have three adducin genes (ADD1–3, encoding α, β and γ polypeptides, respectively; in bony fish, some duplicates of these genes exist; Joshi et al. 1991; Lin et al. 1995; Tisminetzky et al. 1995; Katagiri et al. 1996; Citterio et al. 1999); invertebrates have just one adducin gene (e.g. the hu-li tai shao gene in Drosophila melanogaster; Yue and Spradling 1992).
Vertebrate adducin is a heterotetramer of α–β or α–γ polypeptides (Matsuoka et al. 2000). Each polypeptide comprises three regions: an N-terminal globular head region that is resistant to limited proteolysis and has an aldolase-like fold (aldolase-II superfamily), a short interconnecting (neck) region; and a protease-sensitive tail which contains a MARKS-like domain that binds calmodulin and can be phosphorylated by protein kinase C (Fig. 4).
The tail domain seems to provide multiple protein–protein interactive sites including those for spectrin and actin. However, it appears to require dimerisation/oligomerisation to be functional: this is driven by the neck domain (Matsuoka et al. 2000). Calmodulin and protein kinase C are negative regulators of adducin interactions with spectrin and actin (Matsuoka et al. 1996, 1998).
Adducin is an F-actin plus-end capping protein (Kuhlman et al. 1996), and it promotes the binding of spectrin to actin (Gardner and Bennett 1987; Li et al. 1998). The regulation of adducin’s plus-end capping activity may be of relevance in motile cells and tissue development, since Ca2+ signals would be predicted to expose the plus-ends of actin filaments. Adducin associates with the sides and plus-ends of actin filaments, both alone and with enhanced affinity in the presence of spectrin (Li et al. 1998). Thus, a major mode of association of adducin and spectrin is in a ternary complex at the plus-ends of actin filaments.
In D. melanogaster, hu-li tai shao (hts) mutations give rise to sterile females (Yue and Spradling 1992; Whittaker et al. 1999; Petrella et al. 2007). In oogenesis, mitotic germ cells contain a specialised organelle, the fusome. Post-mitotic cells lose the fusome as F-actin-rich ring canals form. Hts mutants affect both the fusome and ring canals. Surprisingly, the fly adducin encodes a polyprotein (Ovhts) which is cleaved to yield products that associate with the ring canal late in the oogenesis process (Ov-hts-RC) or the fusome (Ovhts-fus) earlier. Hts mutations result do not accumulate F-actin, and ring canal development is arrested.
The nature of red cell membrane–cytoskeleton complexes
Ankyrin-based complex
An interaction between ankyrin and the red cell membrane was first discovered by Bennett and Stenbuck (1979b): they found that ankyrin co-immunoprecipitated from red cell membrane extracts with the anion exchanger. Bruce and coworkers (2003) analysed the nature of the ankyrin-based complex using immunoprecipitation and also compared the protein complexes in human disease conditions characterised by mutations in one or other of the genes concerned. They concluded that ankyrin coordinates the formation of a complex that they termed a metabolon for carbon dioxide transport (see Fig. 5a, b). This metabolon is hypothesised to contain transporters both for carbon dioxide and the product of the carbonic anhydrase reaction, HCO -3 , as well as carbonic anhydrase itself. Ankyrin binds to the large N-terminal cytoplasmic domain of the anion exchanger (Bennett and Stenbuck 1980a, b). Nicolas et al. (2003) suggest it binds directly to the Rhesus complex as well, but Satchwell et al. (2009) consider that the interaction is indirect via protein 4.2 and CD47 (see below).
Linkage to ankyrin is required for the efficient sorting of these membrane proteins during maturation of red cells: at enucleation, in the absence of ankyrin-attachment, the anion exchanger and Rh complex are missorted to the nuclear remnant (Salomao et al. 2010). It has been suggested that the Rhesus complex is a transporter for small neutral molecules. In the kidney, it appears that the Rhesus complex has a major role in ammonia transport, and in erythrocytes, it transports ammonia and methylamine (Kustu and Inwood 2006; Ripoche et al. 2006). Endeward and co-workers (2008) suggest that Rhesus-null individuals have a reduction of about 50% in carbon dioxide transport capacity, indicating that carbon dioxide is a substrate for transport by the Rhesus complex. On the other hand, Missner et al. (2008) and Ripoche et al. (2006) consider it highly unlikely that the Rh complex (or indeed any other channel) act as physiological CO2 transporters.
The anion exchanger binds carbonic anhydrase II in its C-terminal region (Vince and Reithmeier 1998; Adachi et al. 2009). Thus, carbon dioxide entering the cell, potentially via the Rhesus complex, would be close to carbonic anhydrase, the product of this reaction being immediately available for transport out of the cell in exchange for Cl-. (This description refers to red cells passing through actively metabolising tissues; the reverse process would apply in lung tissue).
In addition to the transporters, other transmembrane proteins are present. Glycophorin A is type 1 transmembrane protein, which has a chaperone-like activity for band 3 during trafficking through the secretory pathway and remains in complex with it in the mature red cell (e.g. Hassoun et al. 1998; Williamson and Toye 2008). CD47, a marker-of-self that is suggested to prevent clearance by macrophages in circulation, is also present in the complex (Bruce et al. 2002, 2003; Dahl et al. 2004; Satchwell et al. 2009). Protein 4.2, another peripheral membrane protein, can bind to the cytoplasmic domain of the anion exchanger as well as CD 47 (Satchwell et al. 2009).
The other substrate for carbonic anhydrase is water. Aquaporin is present in the red cell membrane (Preston and Agre 1991; Preston et al. 1992). It is suggested that in addition to water transport, it provides carbon dioxide transport capacity that is not accounted for by the Rhesus complex (Nakhoul et al. 1998; Prasad et al. 1998; Blank and Ehmke 2003; Endeward et al. 2006), although as with the Rh complex, this has been disputed (e.g. Ripoche et al. 2006; Missner et al. 2008). Whether or not CO2 is appreciably transported via AQP1 in erythrocytes remains a topic characterised by opposing views.
Complexes between the actin-based junction and the membrane
A large number of proteins are currently suggested to be associated with the junctional complex; some of these are indicated schematically in Fig. 5c. Protein 4.1-deficient human red cells were noted two decades ago to be lacking in glycophorin C, indicating a requirement for protein 4.1R in stable membrane accumulation of this type 1 protein (Reid et al. 1990; Gascard and Cohen 1994). Further analysis of corresponding knockout mice revealed reductions in additional proteins including the Rhesus polypeptide Rh, Plasmodium falciparum receptor Duffy and putative transporter XK (Salomao et al. 2008). Although band 3 was not lost from these membranes, an alteration to its conformation was suggested by the observation that cell surface exposure of band 3 antigens was altered (Salomao et al. 2008). Protein 4.1 binds to the cytoplasmic N-terminal domain of band 3 (Pasternack et al. 1985; Jons and Drenckhahn 1992). Since there are multiple (approximately 6) 4.1 proteins per junctional complex (Pinder and Gratzer 1983), the junctional complex has the capacity to cross-link a large number of membrane proteins.
The activities of 4.1R in binding membrane proteins are differentially regulated by the presence or absence of the differentially spliced U1 headpiece and by PIP2 binding. This has been analysed carefully for interaction with band 3 and glycophorin C: these bind to lobes A and B of the FERM domain, respectively (Han et al. 2000a). In general, each signal tends to have opposite effects on FERM domain interaction with the two membrane proteins. Thus, PIP2 promotes binding to glycophorin C, but inhibits binding to band 3 (An et al. 2006b). U1 promotes binding to band 3, but inhibits glycophorin C binding (Nunomura et al. 2009). The U1 headpiece contains a Ca2+/calmodulin-binding site (Leclerc and Vetter 1998; Nunomura et al. 2009); in the presence of Ca2+/calmodulin, neither band 3 nor glycophorin C bind to 4.1R containing the headpiece. In mature circulating red cells, PIP2 is present on the cytoplasmic leaflet of the membrane, and little of the isoforms of 4.1R that contain the headpiece are retained: the net effect is to promote glycophorin C interaction with 4.1R and to inhibit binding to band 3. But in erythropoiesis, the U1-containing isoform of 4.1R is more abundant; thus, it might be suggested that the band 3 interaction is more important during this stage (Chasis et al. 1996; Nunomura et al. 2009). This is supported by experiments in zebra fish which demonstrated a requirement for the 4.1R binding site in band 3 for mitosis during erythropoiesis (Paw et al. 2003).
The haematological phenotypes of mice deficient in either dematin or adducin are surprisingly mild (Gilligan et al. 1999; Muro et al. 2000; Robledo et al. 2008). Partly, this may be due to compensating up-regulation of γ-adducin in the case of β-adducin knockout, although α-adducin knockouts lack all adducin in erythrocytes. But crossing the two strains gave a strong spherocytosis phenotype. Chen and co-workers (2007) and Khan et al. (2008) have identified an interaction of dematin and adducin together with the glucose transporter Glut1 in humans. Mouse membranes have a much lower level of Glut1 than human, and it is suggested that in mouse erythrocytes, adducin and dematin may bind to other solute transporters.
A further linkage between the junctional complex and the membrane has been revealed by Low and co-workers (Anong et al. 2009). They have identified binding between the anion exchanger band 3 and adducin. Moreover, protein 4.2, which binds to band 3, has recently been found to bind the C-terminal region of α-spectrin in the EF-hand region (Korsgren et al. 2009). This part of spectrin is close to the junctional complex and forms yet another potential linkage to the membrane. Significantly, mice with a spectrin mutation that disrupts this interaction (strain sph(1J)/sph(1J) have very fragile red cells (Korsgren et al. 2009).
In all, it appears that the actin-based junctional complex coordinates membrane linkages to a large range of membrane proteins. Some of these appear to have roles in red cell stability -—for example, rupture of the adducin-band 3 linkage is reported to weaken red cell membranes (Anong et al. 2009) and the combined loss of adducin and dematin alters cell shape and membrane stability (Khan et al. 2008). On the other hand, only the domain of protein 4.1 that binds to spectrin and actin is required for red cell membrane stability (Discher et al. 1993); thus, it seems likely that the function of 4.1-transmembrane protein complexes is to ensure that transmembrane proteins are trapped at the cell surface after their synthesis, thus ensuring the cell surface display of antigens.
Physiological consequences of mutations in red cell membrane proteins
Two broad classes of phenotypes arise from mutations in membrane–cytoskeletal proteins (Tse and Lux 1999; An and Mohandas 2008). One of these classes causes the cells to lose surface area and so become progressively smaller and relatively spherical. These give rise to the condition hereditary spherocytosis (Eber and Lux 2004). The second class of mutations gives rise to shape changes, and in particular, they reduce the ability of the cell to reform a round biconcave disc after passage through narrow capillaries. These mutations are characteristic of the condition hereditary elliptocytosis (Gallagher 2004).
Mutations of the former class are typically associated with loss of interaction with the ankyrin-based complex (Eber and Lux 2004). They include mutations close to the ankyrin binding site in spectrin that destabilise the folding structure in that region, presumably weakening the interaction when the cells are subjected to shearing forces in circulation (although it should be pointed out that in vitro purified fragments of spectrin that contain these mutations interact with ankyrin with nearly normal affinity). Mutations in ankyrin itself are common in human spherocytosis, as are mutations in transmembrane proteins of the ankyrin-based complex, e.g. band 3, or loss of Rhesus proteins (the Rhesus-null phenotype), or protein 4.2. These are sometimes described as the “vertical” interactions in red cell membranes.
Elliptocytogenic mutations are associated with “horizontal” interactions, i.e. in the formation of the network that lines the membrane (Gallagher 2004). Typically, these are associated with the formation of spectrin tetramers, or in the spectrin–actin-binding activity or abundance of protein 4.1. In the most severe cases of elliptocytosis, membrane fragmentation can occur; these aggravated cases are sometimes described as hereditary pyropoikilocytosis because the cells become unstable in the warm.
Alterations in the red cell membrane cytoskeleton in malaria
Malaria remains one of the most deadly human diseases. The malaria parasite P. falciparum is widely regarded as one of the strongest forces for evolution of the human genome since the emergence of our species. Since the parasite spends part of its life cycle within the red blood cell, is the erythrocyte cytoskeleton involved in this process?
A key element of the intra-erythrocytic stage of the parasite’s life cycle is that the infected cells are sequestered within the vascular system, thus avoiding the spleen where they would be more likely to be removed from circulation. Recent data indicates that several proteins exported from P. falciparum can bind to the membrane cytoskeleton and by altering its properties contribute to pathogenesis. The parasite has evolved mechanisms that make the red blood cells sticky (i.e. they have increased adhesiveness to vascular walls) and they become more rigid and less deformable. Conceptually, the latter could be associated with alterations to the spectrin system.
A protein that has been associated with alteration to the erythrocyte’s cytoskeleton apparatus is the ring-infected erythrocyte surface antigen (RESA). RESA is exported from the parasite and binds to repeat 16 of β-spectrin (Pei et al. 2007a). This is directly adjacent to the site where β-spectrin interacts with α to form tetramers. An active fragment of RESA stabilises spectrin tetramers in vitro and also in situ in whole red cell membranes. This is accompanied by increased rigidity of the cells and also resistance to thermal degradation. Resealed red cell ghosts containing the RESA fragment within them also display resistance to further invasion by P. falciparum merozoites; thus, RESA confers two advantages on the parasite: first in stiffening the cells so that they are retained within narrow blood vessels, and second in preventing further invasion of the infected cell by other parasites, as well as possibly protecting the cells against the high temperatures encountered during febrile crises.
Later in the parasite’s development, the red blood cell membrane becomes weakened to enable the escape of the parasites. A protein potentially implicated in this is P. falciparum erythrocyte membrane protein 3 (PfEMP3). PfEMP3 binds to the C-terminal region of α-spectrin, a site close to the point where spectrin attaches to actin and protein 4.1R (Pei et al. 2007b). An active peptide of PfEMP3 reduces the formation of the spectrin–actin–4.1R ternary complex in vitro. Erythrocyte ghosts resealed with an active fragment of PfEMP3 within reveal an extensive reduction in shear resistance. Since PfEMP3 is expressed in the later stages of the parasite development, it might be hypothesised that it contributes to the release of the parasite.
Many other parasite proteins probably interact with the membrane skeleton. Among them, Pf332 binds actin (Waller et al. 2010) and mature parasite-infected erythrocyte surface antigen (MESA) binds protein 4.1R (Waller et al. 2003). The challenge for the future is to understand the full repertoire of parasite proteins that interact with the red cell cytoskeleton and how their expression relates to alterations in the key parameters that allow effective invasion of cells (presumably the cytoskeleton has to be penetrated), parasitised cells to escape immune surveillance and the release of parasites when they are fully mature. In principle, these interactions should be targets for drug discovery.
Some mutations in red cell cytoskeleton proteins have been selected in populations within malaria-endemic regions. In South East Asia, ovalocytosis arises from band 3 mutations that give stiffer membrane (Liu et al. 1990b; Mohandas et al. 1992). These have a protective effect on cerebral malaria. Analysis of populations in Benin, West Africa, has revealed high levels of hereditary elliptocytosis, associated with mutations in αI- and βI-spectrins (Glele-Kakai et al. 1996).
Discovery of spectrin outside red cells (“non-erythroid” spectrins)
It was clear in the1970s that some nucleated cells could contain spectrin-like proteins. Pinder et al. (1978a) showed that the nucleated erythrocytes of some invertebrates contained immunologically cross-reactive proteins. However, initial surveys of cultured mammalian cells failed to reveal spectrins (Hiller and Weber 1977).
This changed with the advent of sensitive immunoblotting methods and immunofluorescence in the late 1970s and early 1980s. Spectrin was discovered independently by several investigators and variously termed brain (or non-erythroid) spectrin (Goodman et al. 1981; Bennett et al. 1982b; Burridge 1982; Lazarides and Nelson 1982), fodrin (Levine and Willard 1981; Glenney et al. 1982a) or calspectin (Kakiuchi et al. 1982).
The term fodrin still occasionally use today, and it is generally taken to refer to polypeptides termed here αII- and βII-spectrin. Spectrin identified in embryonic liver was termed “embryonic liver fodrin” or ELF (Mishra et al. 1999).
The identification of spectrin-related proteins in many tissues strongly implies that spectrin is not simply an erythrocyte protein but has descended from a lineage of animal proteins that arose before the advent of erythrocytes.
Gene cloning technology has revealed some of the evolutionary history of spectrin, ankyrin, 4.1 and adducin, and since it sheds light on their functions, it is relevant here to consider a little of this.
The spectrin-associated cytoskeleton in evolution
The evolution of animals required the emergence of adaptations for, e.g. cell differentiation and polarisation, the assembly of signalling and cell adhesion systems, as well as systems that provide the cell with resilience to the forces engendered by animal motility. Some of these, surprisingly, arose even before the emergence of metazoa. For example, in choanoflagellates, colonial protozoa that are thought to represent a lineage from which metazoa diverged (King 2005), there are a surprising number of signalling and cell adhesion systems (King et al. 2003). This suggests that some of the systems that were prerequisite for the ultimate appearance of animals actually had functions at a simpler stage of evolution.
Annotation of the genome of the choanoflagellate Monosiga brevicollis revealed a protein very similar to spectrin (King et al. 2008). This genome predicted α-, β- and βV-spectrin chains, although the β-spectrin does not obviously have an ankyrin-binding site (Baines 2009). It seems likely that in choanoflagellates, the functions of spectrin that are required for the formation of tissues had not yet evolved. However, the presence of an ABD in the choanoflagellate spectrin, as well as the potential for the protein to form tetramers, suggests that the fundamental actin-cross-linking activity of spectrin may have evolved very early (Baines 2009).
The genomes of other simple animals are now available: for example, the placozoan Trichoplax adherens (Srivastava et al. 2008) and sea anemone Nematostella vectensis (cnidarian; Putnam et al. 2007). Both of these have spectrin genes (α, β and β-heavy) although only Nematostella has an ankyrin with the potential to bind spectrin. It appears that spectrin–ankyrin interactions evolved at a similar time to the appearance of complex tissues. A protein 4.1 gene is also present in Nematostella, although it lacks the spectrin–actin-binding domain. This indicates that protein 4.1 probably evolved independently of a requirement to bind spectrin; indeed, the spectrin–actin-binding domain is a late evolutionary development—Pfam (Bateman et al. 2002) indicates that this domain probably evolved with the vertebrates.
The spectrin–ankyrin–4.1 system shows a remarkable gain of function in evolution: the formation of tissues may well have required an interaction between spectrin and ankyrin, and the gain of size of the vertebrates seems to have coincided with the strengthening of the spectrin–actin junction by the gain of spectrin–actin-binding activity of 4.1.
The protein accumulator model
Both ankyrin and protein 4.1 appear to be necessary for the stable accumulation of certain membrane proteins at the cell surface. It was noted above that they are required for the accumulation of the anion exchanger, Rh complex, Duffy and others in the mature erythrocyte membrane (e.g. Salomao et al. 2008, 2010): in their absence, they are lost being missorted during erythroid maturation. There are also many examples outside mammalian erythrocytes of a requirement for these proteins in the correct acculation of proteins at requisite points on cell surfaces. As will be detailed further below, ankyrin and 4.1 are required in many different cell types for the stable accumulation of a wide variety of transmembrane proteins.
Observations from worms and flies indicate that one of the functions of spectrin and ankyrin, at least, is to stabilise cell–cell junctions (e.g. Dubreuil et al. 1996; Hammarlund et al. 2000; Moorthy et al. 2000; Norman and Moerman 2002), particularly, those based around cell adhesion molecules of the L1 family. Ankyrin binds to such cell adhesion molecules and seems to be required for strengthening cell adhesions against the forces generated by the movement of animals (Davis and Bennett 1994; Dubreuil et al. 1996; Chen et al. 2001). One possibility is that ankyrin recruits spectrin to sites of activated L1 thereby cross-linking them: since spectrin tetramers each contain two ankyrin-binding sites, spectrin has the potential to cross-link L1 molecules. Individual spectrin tetramers might be joined together via F-actin, creating a cross-linked “Velcro-like” adhesion. Weakness of cell junctions in the absence of spectrin was indicated observations that Caenorhabditis elegans deficient in β-spectrin was paralysed in part because muscles pull away from the body wall (Hammarlund et al. 2000; Moorthy et al. 2000).
In skeletal muscle, there is a role for both ankyrin-B and ankyrin-G in the organisation and stability of the costameres, sites inking the internal cytoskeleton to the stress-resilient extracellular matrix. Here, β-dystroglycan and the dystrophin–glycoprotein complex require ankyrins for stable targeting to the plasma membrane (Ayalon et al. 2008). β-dystroglycan is a type I transmembrane protein and binds ankyrin-G. Dystrophin, a giant actin-binding protein that is part of the spectrin superfamily, binds ankyrin-B. In the absence of ankyrin-B, both β-dystroglycan and dystrophin remain intracellular and seem to require ankyrin-B for delivery to the cell surface. Both proteins require ankyrin-G for retention at the costamere. β-dystroglycan and dystrophin are key elements in the pathogenesis of muscular dystrophy. A Becker muscular dystrophy mutation E3335N reduced binding of both ankyrin-G and ankyrin-B to dystrophin.
These observations on cell adhesion also suggest mechanisms for targeting and accumulating membrane proteins at points on the cell surface specified by cell adhesions. Again, since spectrin tetramers bivalent for ankyrin, it should be possible for spectrin to cross-link ankyrin-bound cell adhesion molecules to different types of membrane protein also bound to ankyrin. One such membrane protein might be the sodium pump. In fruit flies, β-spectrin is required for accurate targeting of the sodium pump to the plasma membrane of copper cells in the gut. One hypothesis is that spectrin can cross-link the ankyrin-bound pump to cell adhesion molecules that specify its requisite position (Pinder and Baines 2000). In the absence of cross-linking to spectrin, the pump does not receive “permission” to remain at the cell surface.
Protein 4.1 also binds to cell adhesion molecules. Among these, proteins of the neurexin family in both mammals and invertebrates bind protein 4.1 (e.g. Baumgartner et al. 1996; Menegoz et al. 1997; Poliak et al. 1999; Biederer and Sudhof 2001; Denisenko-Nehrbass et al. 2003; Horresh et al. 2008; Laprise et al. 2009). The CTD binds a number of receptors including ionotropic glutamate receptors (Shen et al. 2000; Coleman et al. 2003) and certain G-protein coupled receptors (e.g. Binda et al. 2002; Lu et al. 2004a). There is clearly the potential for protein 4.1 to cross-link receptors to cell adhesion molecules. It is interesting to note that the spectrin–actin-binding domain of protein 4.1 is a late evolutionary adaptation of protein 4.1. Indeed, in fruitflies, coracle, the fly 4.1, is clearly not associated with spectrin (Fehon et al. 1994). The FERM and CTDs are common to all 4.1 proteins; thus, it seems likely that cross-linking membrane proteins, rather than cytoskeleton–membrane interactions is the fundamental role of protein 4.1.
A cartoon summarising the “protein accumulator” model is shown in Fig. 6.
A table of some of the transmembrane proteins known to interact with ankyrin or 4.1 is given in Table 1.
Physiology of the spectrin–ankyrin–4.1–adducin system
In the following section, some elements of the functions of the spectrin–ankyrin–4.1–adducin complex are discussed in relation to the physiology of some key cell and tissue types. The focus is on epithelia, nerve and cardiac muscle. These have each been the subject of intense investigation for 2–3 decades and reveal many principles underlying the function of the spectrin complex. In the space available in this review, it is not possible to cover function in all tissues; thus, these have simply been chosen as exemplars. Nevertheless, the reader should be aware that the proteins of the spectrin complex are present in all animal cells.
A role for spectrin, ankyrin, adducin and protein 4.1 in the polarisation of function in epithelial cells
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(a)
Basolateral domain
Since proteins of the spectrin complex arose coincidentally with the formation of tissues, they might be predicted to have roles in the formation of apical or basolateral domains. However, proposals that spectrin is required for the formation of all polarised cells were not supported by knockdown experiments in C. elegans. Elimination of worm β-spectrin resulted in a variety of phenotypic alterations—most strikingly in muscle and nerve—nevertheless, epithelia appeared to polarise normally and the process of secretion appeared unaffected since the cuticle was deposited normally (Hammarlund et al. 2000; Moorthy et al. 2000). Similarly, mutations in fruit fly alpha-spectrin indicated that, although the epithelia formed, spectrin-stabilised cell–cell junctions are critical to cell shape and tissue organisation (Lee et al. 1993). However, in mammalian systems, clear evidence has been found for a requirement for βII-spectrin, ankyrin and protein 4.1 in the formation of lateral membranes.
Nelson and co-workers identified detergent-resistant complexes between spectrin, ankyrin, E-cadherin and the Na/K-ATPase that formed during kidney cell polarisation (Nelson and Veshnock 1987; Morrow et al. 1989; Nelson and Hammerton 1989; Nelson et al. 1990).
Over-expression of fragments of spectrin gave disruption of Caco-2 cell epithelial morphology, indicating a fundamental role for spectrin in epithelial biogenesis (Hu et al. 1995). Knockdown of βII-spectrin, ankyrin or 4.1R in monoloayers of human bronchial epithelial cells results in loss of lateral membrane and an apparent collapse of these cells (Kizhatil and Bennett 2004; Kizhatil et al. 2007b; Yang et al. 2009). The role of 4.1, in particular, is conserved in evolution since the fruit fly 4.1, coracle, promotes basolateral membrane stability (Laprise et al. 2009), although this implies spectrin independence of its function. Interaction of ankyrin with spectrin is clearly required since a mutant ankyrin-G that does not bind spectrin cannot participate in lateral membrane biogenesis (Kizhatil et al. 2007b).
Spectrin, protein 4.1 and ankyrin participate in the formation of cadherin-based junctions. Ankyrin-G links βII-spectrin to E-cadherin, and this interaction was found to be required required for exit of E-cadherin from the Golgi apparatus and for accumulation of E-cadherin at sites of cell–cell contact in embryonic cells and cultured epithelia (Kizhatil et al. 2007a, b; Kizhatil and Bennett 2004). In 4.1R knockout mice, histological examination revealed impairment of cell–cell junctions in the stomach epithelia, and the gastric glands were disorganised (Yang et al. 2009). Protein 4.1R binds to the adherens junction protein β-catenin (Yang et al. 2009). α-Catenin binds (αII–βII)-spectrin (Pradhan et al. 2001) at a site close to the N-terminal of αII-spectrin, i.e. closely adjacent to the site in βII-spectrin in a spectrin tetramer that binds actin. All these data indicate an important role for (αII–βII)-spectrin, ankyrin-G and 4.1R in connecting the cadherin/β-catenin complex to the internal cytoskeleton and in ensuring the formation and integrity of adherens junctions.
Adducin seems to have a role in stabilising epithelial junctions once they have formed. Early observations on adducin in epithelial cells revealed that it was recruited to sites of E-cadherin cell adhesions (Kaiser et al. 1989). Knockdown and rescue experiments suggest it stabilises junctions once they have formed. Interaction of adducin with sites of cell adhesion was dependent on spectrin, but the presence of adducin increased detergent resistance of spectrin (Abdi and Bennett 2008). In the absence of adducin, the basal surface area was found to expand, and E-cadherin diffusion was increased (Abdi and Bennett 2008).
The delivery of membrane proteins to apical or basolateral domains in epithelial cells is of central importance to their function. As well as E-cadherin, other membrane proteins in epithelia that require ankyrin linkage for passage through the secretory pathway and delivery to the basolateral surface include the Na/K-ATPase (Nelson and Veshnock 1987; Morrow et al. 1989; Hu et al. 1995; Kizhatil and Bennett 2004). A 25 amino acid cytoplasmic sequence within the pump has been found to bind to ankyrin. When this sequence was used to replace the cytoplasmic domain of the VSV G protein, it conferred ankyrin-R dependence on passage of the chimera through the Golgi. The Na/K-ATPase also requires a Golgi form of 4.1B for passage through the secretory pathway (Kang et al. 2009). These data indicate functions for 4.1 and ankyrin proteins in a fundamental process, trafficking of transmembrane proteins, required in all eukaryotic cells, not just epithelia. Whether this represents an adaptation of the trafficking apparatus to fit the needs of vectorial delivery of membrane cargoes in polarised metazoan cells or whether the function of ankyrin/4.1 has been adapted to play a more fundamental role in membrane trafficking remains to be seen.
If the spectrin/ankyrin/4.1 complex is damaged in some way, polarisation might be lost. Several workers have suggested that this is the case in kidney epithelia after ischemia (Doctor et al. 1993; Alejandro et al. 1995; Woroniecki et al. 2003). In ischemic tissues, cytoplasmic Ca2+ concentrations rise, activating the protease calpain. Spectrin, ankyrin and 4.1 are all calpain substrates, but a site in αII-spectrin, in particular, close to the centre of the polypeptide is exquisitely sensitive to calpain. In ischemic cells, the spectrin–ankyrin linkage was found to be lost, even though ankyrin remained bound to the pump. Breaking of the linkage coincided with loss of the polarised distribution of the pump (Woroniecki et al. 2003).
It has been speculated that calpain cleavage of spectrin is important in physiological modelling of tissues during development. However, mice with a spectrin knock-in that render them resistant to calpain cleavage develop normally and have no major phenotypes (Meary et al. 2007), arguing against such roles.
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(b)
Apical domain
A role for spectrin in the apical domain of epithelial cells was suggested by the work of Glenney and co-workers (1982b) who isolated a spectrin-related protein from chicken intestinal terminal web: they named this protein TW-260/240. In the terminal web, it appeared to span the actin filaments that emerged from the microvilli. The contour length of the protein was about 263 nm, much greater than that of spectrin tetramers (approximately 190 nm; Glenney et al. 1982c). The protein appeared to be a tetramer of elongated subunits and generally resembled spectrin. The α-subunit (TW-240) by immunological analysis and peptide mapping seemed to be identical to the α-subunit of brain spectrin (Glenney et al. 1982c; Glenney and Glenney 1984), i.e. it was αII-spectrin. Comparison of the contour length of the intact TW-260/240 molecule with spectrin indicated that the size of the β-subunit was probably of the order of 1.7 times greater than that of red cell β-spectrin (Glenney et al. 1982c). The sequence of βV-spectrin (or βH-spectrin) contains approximately 1.7 times more amino acids than that of erythrocyte β-spectrin (Stabach and Morrow 2000); thus, it is likely that TW-260 actually represents a β-heavy (βH)-subunit (although the author can find no evidence in the public databases that TW-260 has been sequenced to date). The protein did not seem to be linked to membranes in the same way as red blood cell spectrin, and correspondingly, the β-subunit (TW-260) did not bind ankyrin (Howe et al. 1985). Nor, indeed, was its interaction promoted by protein 4.1 (Coleman et al. 1987), although βV-spectrin in cochlear outer hair cells apparently forms a complex with protein 4.1G (Legendre et al. 2008).
A spectrin-related gene was identified in the karst locus in fruit flies (Thomas et al. 1998). This gene encoded a high molecular mass β-heavy subunit: correspondingly, it is referred to as βH. The equivalent gene in C. elegans is SMA-1 (McKeown et al. 1998).
Karst mutations are largely larval lethal, although there are adult escapers with rough eyes (many of which lacked photoreceptor R7), bent wings, tracheal defects and infertility (Thomas et al. 1998). In the mid-gut, immunological analysis revealed that βH-spectrin was a terminal web protein, indicating its relationship to chicken TW-260 (Thomas et al. 1998). Absence of βH-spectrin was accompanied by the breakup of the zonula adherens during mid-oogenesis in follicle cells (Thomas et al. 1998; Zarnescu and Thomas 1999). It also prevented stable recruitment of α-spectrin to the apical domain, although it did not result in loss of apical–basal polarity (Thomas et al. 1998; Zarnescu and Thomas 1999). The fly β-spectrin interacted with the crumbs protein, an apical transmembrane protein required in the assembly of the zonula adherens, as well as for apical–basal polarity (Medina et al. 2002). A complex of crumbs, discs lost, moesin and βH-spectrin was immunoprecipitated from fly embryos, indicating the existence of a multi-protein complex (Medina et al. 2002). As with the role of β-spectrin in the basal domain, the role of apical βH seems to be related to stabilising a region of cell adhesion. In the retina, the cell adhesion molecule roughest is required in refinement of the retinal lattice (Lee et al. 2010). Over-expression of a fragment of βH-spectrin disrupted the zonula adherens and displaced roughest (Lee et al. 2010). Combining karst and roughest mutations gave catastrophic effects on retinal development, indicating that apical spectrin links to both zonula adherens assembly and roughest morphogenesis (Lee et al. 2010).
In C. elegans, the βH-spectrin SMA-1 was also required for morphogenetic events. SMA-1 mutants elongated more slowly than wild-type embryos, and SMA-1 was first expressed in epithelia (McKeown et al. 1998). It appeared to have a role in the apical domain of epidermal cells, where it was required to maintain the association between actin and the apical membrane (McKeown et al. 1998; Praitis et al. 2005). Similarly, in flies, βH-spectrin was required in wound healing in the software in which an injured epithelial sheet closes its whole via a “purse-string” mechanism (Campos et al. 2010). SMA-1 was also required for morphogenesis of the lumen of epithelial tubes (Gobel et al. 2004).
In the brush border, βH-spectrin was also found to be required for maintenance of Rab5 endosomes, and an apical proton vacuolar-ATPase was lost from both the brush border and Rab5 endosomes (Phillips and Thomas 2006). βH-spectrin probably has a role in protein sorting in the endocytic pathway. Interestingly, a possibly parallel relationship to protein sorting occurs in mammals where transient receptor potential channel protein TRPC4 interacts with βV- and αII-spectrin, and this interaction is required for intracellular sorting (Odell et al. 2008).
Mechanistically, it is suggested that β-spectrin and βH-spectrin act in an antagonistic way to balance apical and basolateral domains (Chen et al. 2009). Epithelial polarity is generally considered to be governed by three protein complexes: the apical polarity complexes (par3/par6/aPKC and crumbs/pals1/patj) and the lateral complex (scribble/dlg/lgl; Assemat et al. 2008). As noted above, βH-spectrin in flies interacts with crumbs. Interestingly, human 4.1R binds tothe human homologue of the Drosophila discs large tumor suppressor (hdlg; Lue et al. 1994), providing a link to the lateral polarity complex. A topic for the future will be to understand better the mechanistic links between the spectrin cytoskeleton and the polarity complexes, not only in epithelia but also in additional polarised cells, including nerve cells.
Spectrin, ankyrin and protein 4.1 in nerve cells
Nervous tissue was one of the earliest sources of material for investigation of spectrin, ankyrin, adducin and protein 4.1 outside red blood cells.
Purification of spectrin from brain revealed that it had an actin-binding activity (Bennett et al. 1982a; Burridge 1982; Glenney et al. 1982d; Burns et al. 1983), although unlike erythrocyte spectrin, it could bind actin with high affinity even in the absence of protein 4.1; but protein 4.1 still promoted the binding of brain spectrin to F-actin (Burns et al. 1983).
An ankyrin was also purified from brain and this was termed ankyrin-B (B for brain; Davis and Bennett 1984a, b). This could bind to brain spectrin at a site equivalent to the ankyrin-binding site in erythrocyte β-spectrin. Brain ankyrin itself was found to bind to protein sites on brain membranes stripped of peripheral membrane proteins by treatment with concentrated potassium iodide solutions (Davis and Bennett 1986; Davis et al. 1989). The most abundant binding sites for ankyrin on brain membranes were identified as polypeptides of the neurofascin/L1 family (Davis and Bennett 1993, 1994), but it was clear that brain ankyrin bound to other proteins as well including voltage-gated sodium channels (Srinivasan et al. 1988; Lambert et al. 1997; Zhou et al. 1998; Garrido et al. 2003).
The significance of βII-spectrin to mammalian tissue development has been addressed in mice. βII-spectrin knockout mice die in utero, with major defects in the formation of the brain, heart and other organs (Tang et al. 2003). By comparison, mice of the βI-spectrin mutant strain ja/ja, while extremely anaemic from loss of erythrocyte spectrin, survive till a few days after birth (Bodine et al. 1984); this indicates that βI-spectrin is probably not required for the formation of major brain structures.
Axon outgrowth
Analysis of C. elegans in which spectrin has been knocked down revealed that, among other phenotypic anomalies leading to the animal’s paralysis, axons did not find their targets; they were described as “wandering” (Hammarlund et al. 2000; Moorthy et al. 2000). Subsequent analysis using time-lapse microscopy revealed that the axons were able to form normally and exhibited growth cones, but the axons broke frequently. After breakage of the first axon outgrowth, more axons formed, seemingly at random over the nerve cell body, and, where they extended, they were not guided precisely (Hammarlund et al. 2007). It seems likely that spectrin is required for maintenance of axon integrity in the face of the forces generated by the movement of the animal. To that extent, these data reveal a common theme in the function of spectrin in both nerve cells and erythrocytes.
In mammals, there is evidence for a requirement for spectrin function, as well as that of ankyrin, in initiation of axon outgrowth. Knockdown of ankyrin in rat primary nerve cells blocked axon outgrowth; this was rescued by transfection with human ankyrin-GFP, but not by a mutant that cannot bind spectrin (Nishimura et al. 2003). It is suggested that ankyrin recruits spectrin to sites where cell adhesion molecules are engaged with cell adhesion molecules that permit axon outgrowth; spectrin would therefore be hypothesised to be recruited to such sites and, in turn, linked to actin. This would stabilise treadmilling filaments so that growth at their plusends push out the leading edge of the cell. It is notable in this context that αII-spectrin interacts with a number of proteins of the motility apparatus of crawling cells (Ziemnicka-Kotula et al. 1998; Rotter et al. 2005; Bournier et al. 2006): this is a topic that remains to be explored further.
Further evidence for involvement of spectrin in axon (neurite) outgrowth comes from experiments with the model cell line PC12. Upon serum starvation and exposure to nerve growth factor, these rat pheochromocytoma cells cease proliferating and differentiate into a sympathetic nerve cell type which extend axon-like neurites (Greene and Tischler 1976). Transfection of these cells with fragments of βII-spectrin (which act as dominant negative inhibitors of tetramer formation) blocked NGF-induced neurite outgrowth (Bignone et al. 2007). Interestingly, a mutant resembling a phosphorylated spectrin fragment that was able to bind α-spectrin only weakly did not block axon outgrowth; a non-phosphoryatable mutant that bound α-spectrin strongly (and hence was a strong inhibitor of spectrin function) was a strong inhibitor of axon outgrowth. The mutation was at a site recognised by both protein kinase A and protein kinase CKII: protein kinase A has attracted much attention in regulation of nerve axon outgrowth, and it is tempting to speculate that spectrin is one of its key substrates in this respect.
Assembly of the signalling systems that transmit action potentials
Nodes of ranvier
The observation in the late 1980s that ankyrin could bind to voltage-gated Na+ channels (Srinivasan et al. 1988) indicated a role for the spectrin–ankyrin system in nerve cell signalling. Subsequently, it became clear that a specialised giant ankyrin, ankyrin-G 480, which has a large insertion in the C-terminal region, was enriched at nodes of Ranvier (Kordeli et al. 1995). Ankyrins also bind the nodal Kv3.1 and KCNQ K+ channels (Devaux et al. 2003, 2004; Pan et al. 2006; Xu et al. 2007). Both the K+ and voltage-gated Na+ channels require ankyrin-G to assemble at nodes (Pan et al. 2006). Both groups of vertebrate channels contain similar ankyrin-binding motifs that appear to have evolved subsequent to the appearance of vertebrates, at a similar evolutionary point to the appearance of myelin (Hill et al. 2008). Furthermore, several other key elements of the node—the Na/K-ATPase, Na/Ca exchanger and L1/neurofascin cell adhesion molecules—also bind ankyrin (Lambert et al. 1997).
The most abundant spectrin at nodes comprises αII–βIV polypeptides (Berghs et al. 2000; Jenkins and Bennett 2002; Komada and Soriano 2002; Dzhashiashvili et al. 2007; Uemoto et al. 2007). Mice lacking βIV-spectrin had a quivering phenotype (qv/qv strain) with auditory and motor neuropathies, presumably caused by mislocalised channels that depend on the ankyrin–spectrin complex (Parkinson et al. 2001; Komada and Soriano 2002).
In the paranodal and juxtaparanodal regions, the abundant spectrins are αII–βII; thus, there is microscale compartmentation of spectrins with the nodal region (Ogawa et al. 2006; Voas et al. 2007). The targeting mechanisms and functional selectivities of the different spectrin populations have yet to be clearly established.
Proteins 4.1 are also present in nodes of Ranvier at paranodes and juxtaparanodes. Protein 4.1B bound CASPR1 and CASPR2, two cell adhesion molecules of the NCP (neurexin/paranodin/CASPR) family at juxtaparanodes (Gollan et al. 2002; Denisenko-Nehrbass et al. 2003). Protein 4.1B also colocalised with Kv1 (Shaker type) K+ channels at juxtaparanodes (Poliak et al. 2001; Horresh et al. 2010). It is thought that 4.1B forms part of a scaffold that controls the targeting and retention of these membrane proteins at that point. Interestingly, CASPR2 seemed to be actively retrieved from plasma membrane in somatodendritic compartments, and this was required for its axon targeting: interaction with 4.1B seemed essential for this (Bel et al. 2009).
An evolutionary correlate of this has been drawn with the fruit fly 4.1 coracle. Coracle is enriched in pleated septate junctions in flies which are the functional equivalent of the vertebrate tight junctions. Coracle and a group of transmembrane proteins—the cell adhesion molecules neurexin and neuroglian (an L1/neurofascin family member) and the Na/K-ATPase—formed an interdependent complex (Genova and Fehon 2003).
A further component of the paranode/juxtaparanode is β-adducin (Ogawa and Rasband 2009). This polypeptide colocalised with CASPR2, Kv1.2 and βII-spectrin. However, it is hard to be sure of the functional significance of β-adducin at these points since mice deficient in β-adducin showed no obvious developmental defects: perhaps, as in erythrocytes (Gilligan et al. 1999), γ-adducin compensates.
In summary, the major transmembrane protein complexes at nodes of Ranvier, as well as paranodes and juxtaparanodes that dictate both the ion fluxes underpinning action potential transmission, as well as the cell adhesions that provide tight association between the axonal plasma membrane and myelinating cells, are closely linked to the spectrin–ankyrin–4.1–adducin complex. It is likely that these interactions converged in evolution as a prerequisite to the appearance of salutatory conduction of action potentials.
Axon initial segment
Nerve cells are highly polarised cells, with a single axon and multiple dendrites. A key region in determining this polarity is the axon initial segment (AIS), which acts as a diffusion barrier between the somatodendritic compartment and the axon (Ogawa and Rasband 2008). Here, transmembrane proteins that are responsible for initiating action potentials are clustered together with molecules that specify adhesion to other cells and are linked to the underlying cytoskeleton, in an array conceptually similar to that described above for the node of Ranvier. Indeed, the AIS is also characterised by βIV-spectrin and ankyrin-G (Jenkins and Bennett 2001).
The key role of ankyrin-G in assembling the AIS is mediated via its mutually interdependent interactions with cell adhesion molecules that include the neurofascin/L1 family member Nf186 and the neuron glia-related CAM (NrCAM; Ango et al. 2004; Dzhashiashvili et al. 2007; Hedstrom et al. 2007). These interactions are required for the establishment of the AIS diffusion barrier that separates axonal and dendritic compartments and clusters the channels required for action potentials (Lemaillet et al. 2003; Boiko et al. 2007; Nishimura et al. 2007; Song et al. 2009).
Ankyrin-G binds AIS Na+ and K+ channels and seems to be intimately involved in generating the clusters required for action potential firing (Bouzidi et al. 2002; Garrido et al. 2003; Xu and Shrager 2005; Chung et al. 2006; Rasmussen et al. 2007; Van Wart et al. 2007; Hedstrom et al. 2008). The importance of these interactions has recently been emphasised by the observation that both βIV-spectrin and ankyrin-G are targets for the Ca2+-activated protease calpain (Schafer et al. 2009). Calpain-catalysed proteolysis of these proteins is observed in AIS of injured nerves and is associated with loss of neuronal polarity and clusters of Na+ channels. These observations are consistent with findings on ankyrin-G-deficient cerebellar nerve cells: these lose polarity and develop sproutings on their axons resembling dendritic spines in their morphology, in the presence of dendritic protein markers and in forming contacts with presynaptic glutamatergic boutons (Sobotzik et al. 2009).
Similar data have been obtained for small interfering RNA silencing of ankyrin-G in hippocampal cultures in vitro: these cells also develop spine-like structures and synapses on their axons. Somatodenditic markers, such as the K+/Cl- cotransporter KCC2 and the microtubule-associated protein MAP2, enter the axon (Hedstrom et al. 2008).
Synaptic structure and stability
A role for spectrin in the function of synapses was suggested by early observations that brain spectrin was a major calmodulin-binding component of the post-synaptic density (Carlin et al. 1983). Post-synaptic spectrin interacts with an extensive PSD cytoskeletal scaffold and directly with certain receptors including ionotropic glutamate receptors (Wechsler and Teichberg 1998). In fruit flies, α-spectrin and β-spectrin are required for normal synaptic development and organisation (Pielage et al. 2006).
Recent genetic screens in fruit flies have identified α-spectrin, β-spectrin and ankyrin-2 as essential components for normal synaptic stability, with a presynaptic function. A giant ankyrin-2 (ank2-L: 4,083 amino acids) was distinguished in neuromuscular junctions, where it was organised in a presynaptic lattice on the membrane (Pielage et al. 2008). This protein contains a large insert in the C-terminal region. Ank2-L was required for synaptic stability: in its absence, the homophilic cell adhesion molecule fasiclin II was disorganised, and the presynaptic nerve ending appeared to disassemble. Correspondingly, electrophysiological analysis indicated major defects in synaptic transmission. In the absence of ank2-L, the presynaptic microtubule lattice became disorganised. Interestingly, one of the early observations on the activities of non-erythroid ankyrins was that they bound microtubules (Bennett and Davis 1981): this seems to be the functional correlate of this.
It should be noted that there are several other isoforms of Drosophila ank2 that are spatially segregated. Ank2-short (137 kDa) was only found in neuronal cell bodies, while Ank2-long isoforms (also described at ank2-M: about 400 kDa) were present in axons (Hortsch et al. 2002).
Spectrin/ankyrin/4.1 and the regulation of heart beating
One of the first tissues in which spectrin was discovered was the heart muscle cells (cardiomyocytes; Goodman et al. 1981). Spectrin appeared in striated muscles to be concentrated in regular plasma membrane accumulations named costameres (Craig and Pardo 1983; Pardo et al. 1983a, b; Craig and Pardo 1983), aligned with the Z-line and linked to the internal contractile apparatus via intermediate filament complexes. Actin is present in costameres, but unlike the contractile apparatus which contains α-actin, costameres contain γ-actin (Craig and Pardo 1983). Externally, they are linked to the stress-tolerant extracellular matrix via cell adhesion molecules that include integrins (Hilenski et al. 1992). Since they link the extracellular matrix to internal actin-rich structures, they are often likened conceptually to focal adhesions (Samarel 2005). Costameres represent sites of biomechanical signal transmission, and altered signalling via costameres is associated with hypertrophy (Sussman et al. 2002).
αI-, αII-, βI- and βII-spectrins are present on cardiomyocyte plasma membranes (Isayama et al. 1993; Flick and Konieczny 2000; Hayes et al. 2000; Bennett et al. 2004; Baines and Pinder 2005). These proteins are strikingly compartmentalised: both α-spectrins were present at lateral plasma membranes and close to T-tubules, but only αII-spectrin was present at intercalated discs (ID; Baines and Pinder 2005; Bennett et al. 2006). These are the sites where contractile forces are transmitted between cells. The relatively stiff αII-spectrin polypeptide might be hypothesised to be fitted for a role in maintaining plasma membrane structure at IDs; the relatively springy αI-spectrin might supplement αII-spectrin on lateral membranes to accommodate the membrane distortions that take place on contraction. In addition, αII-spectrin was found to be aligned with the terminal sarcomere in cardiomyocyte myofibrils, suggesting a mechanism for direct communication between intercalated disc and contractile apparatus (Bennett et al. 2006).
βI-spectrin is also present on the plasma membrane; thus, a proportion of the cardiomyocyte spectrin therefore presumably is similar to the erythrocyte protein. The βI-spectrin isoform that is dominant is the long, muscle-specific form that contains the PH domain. βI-spectrin has a potential link to cardiomyopathy and heart failure in that it binds to muscle LIM protein (MLP; Arber et al. 1997; Flick and Konieczny 2000). MLP binds triple helical repeat 7 of βI-spectrin (Flick and Konieczny 2000).
βII-spectrin is present in two isoforms: the long C-terminal (βIIΣ1) and the short C-terminal (βIIΣ2) forms. The plasma membrane form is primarily long; the short form is mainly internal and associated with Z-disks and M-lines. αII-spectrin is also a component of the Z-disk structure as judged by immunoelectron microscopy; thus, Z-disks probably contain (αII-βIIΣ2)2 tetramers. On the other hand, at the M-line, there is apparently no α-spectrin; there have been a number of reports of α-less β-spectrins in muscles, but the functional significance of these is unknown (and indeed whether or not there are other proteins that block the α-binding sites in these β-spectrins).
Ankyrins in heart: ankyrin-linked cardiomyopathies associated with loss of channel targeting
Ankyrin-B (Mohler et al. 2003) and ankyrin-G (Mohler et al. 2004b) were found to be expressed in heart, where immunofluorescence placed them close to T-tubules and intercalated discs, although relatively little of both was observed at lateral plasma membranes. Ankyrin-B seemed to join NCX1, the Na/K-ATPase and IP3 receptor in a complex that linked between the plasma membrane/T-tubule and an internal membrane compartment possibly linked to the sarcoplasmic reticulum (Mohler et al. 2005). Ankyrin-B mice were haploid-insufficient. Even in the heterozygous state, ankyrin-B +/- mice had an arrhythmia and an extended period in the electrocardiogram (ECG) equivalent to the human QT interval. The arrhythmia phenotype was exacerbated by exercise. Adrenergic stimulation with exercise led to occasions of sudden deaths. In this sense, this appeared to be a long QT syndrome and was originally classified as long QT syndrome type 4 (Mohler et al. 2003). However, more recently, it has been referred to as “ankyrin-B syndrome” (Mohler and Bennett 2005). Several channels, including the NCX1, the Na/K-ATPase and the IP3 receptor, were not correctly located in these mice (Tuvia et al. 1999; Chauhan et al. 2000; Mohler et al. 2003).
In a human pedigree with an inactivating mutation (E1425G) in ankyrin-B, a remarkably similar arrhythmia has been found, characterised by bradycardia, atrial fibrillation, cardiac conduction disease and increased risk for catecholaminergic sudden death. Ankyrin-B also had a role in sinus node disease (SND). In the sinoatrial node, NCX1, Na/K-ATPase and inositol trisphosphate (IP3) receptor all required ankyrin-B for correct localisation, as did the voltage-gated calcium channel α-subunit Cav1.3 (Hund and Mohler 2008; Le Scouarnec et al. 2008). Ankyrin-B therefore has a critical role in cardiac pacing via its transporter-targeting activity. One possibility is that ankyrin-B-mediated connection between these proteins is essential for the efficient extrusion of calcium from the cell and that the defects in ankyrin-B syndrome arise from dysregulation of intracellular calcium homeostasis (Mohler and Bennett 2005).
A second ankyrin-related condition is a variant of Brugada syndrome, in which the inactivating mutation E1053K in the voltage-gated Na+ channel Nav1.5 eliminates interaction with ankyrin-G (Mohler et al. 2004b). This channel is the principal voltage-gated sodium channel in the heart, and ankyrin binds to it via an intracellular loop between domains two and three of the channel (Garrido et al. 2003; Lemaillet et al. 2003). Ankyrin-G is required for targeting and expression of the channel.
The function of ankyrin in heart clearly demonstrates its requirement in targeting and localisation pathways for multiple membrane proteins. These heart complexes are analogous to those described above in brain; indeed, complexes of ankyrin-B, NCX1, IP3 receptor and αII–βII-spectrin can be imunoprecipitated from brain (Lencesova et al. 2004).
Protein 4.1R and control of heartbeat
All four 4.1 genes are expressed in heart. Of these, 4.1R has been localised to plasma membrane (including intercalated discs) and striated structures that are probably T-tubules (Taylor-Harris et al. 2005b). Homozygous mice deficient in protein 4.1R had a bradycardia and an extended interval in the ECG equivalent to the QT period (Stagg et al. 2008). In this sense, they resembled ankyrin-deficient mice. Analysis of their physiology revealed defects in multiple ion transport processes including, among others, a reduction in the current density for sodium/calcium exchange, elongation of the period of the action potential and increase in the persistent sodium current density. The latter was probably associated with a failure to inactivate Nav1.5 fully. Analysis of the protein content of the mouse revealed a reduction in the total content of Nav1.5 as well as a (presumably compensating) up-regulation of protein 4.1G. It seems very likely that protein 4.1 and ankyrin have an overlapping spectrum of roles in the heart in control of the cellular accumulation and localisation of diverse membrane proteins. As yet, no human correlate of the mouse data exists. It will be interesting in the future to establish if mutations in 4.1R can be associated with human cardiac conditions.
Summary and perspectives
In this review, numerous examples have been cited, which indicate a very fundamental role for the proteins spectrin, ankyrin, 4.1 and adducin in the distinctive functions of cells in animals. We have also seen that there is good evidence that these proteins arose with the animals and that their interactions evolved as animals gained tissues, as well as subsequently during the evolution of the vertebrates. The implication is that these proteins are very likely to be essential to all animal life. As a consequence, defects in these proteins caused by mutation or by modifications, such as proteolysis, are associated with numerous disease states ranging from hereditary anaemia to heart disease.
Since their disease associations are so diverse, we can expect to find new mutations associated with diseases related to membrane function that have not been expected until now. The 4.1 proteins are enigmatic in their relationship to human diseases: while a link to heart disease is suggested by the mouse 4.1R model (Stagg et al. 2008), to the author’s knowledge, thus far, no single nucleotide polymorphism (SNP) analysis links any of the 4.1 genes to inherited heart disease. Indeed, the only clearly 4.1-linked condition is hereditary anaemia (Gallagher 2004).
An emerging issue is the relationship between the spectrin complex and progression through the cell cycle and, therefore, a potential involvement in cancer. Since the cell cycle is governed by mechanisms common to all eukaryotic cells, it might not be expected that animal-specific proteins would have a major role in such a fundamental process. But knockdown experiments have recently revealed a requirement for αII-spectrin in progression through G1 in WM-266 human melanoma cells (Metral et al. 2009). The precise implications of this are not clear at present, since, for instance, fruit flies with α-spectrin mutations survive until first instar larvae and then die from defects in tissue organisation (Lee et al. 1993). Both 4.1R (Robb et al. 2003) and 4.1B (Tran et al. 1999; Gutmann et al. 2000) have both been implicated as human tumor (carcinoma) suppressors. Given their functions in the biogenesis and maintenance of cell adhesions, this is perhaps not surprising. But in addition, 4.1R is associated with the mitotic spindles and centrosomes as well as interphase microtubules of mammalian cells (Correas and Avila 1988; Mattagajasingh et al. 1999; Perez-Ferreiro et al. 2001, 2004; Delhommeau et al. 2002; Krauss et al. 2004), and the D. melanogaster orthologue coracle is required for imaginal cell proliferation (Ward et al. 2001).
One of the problems with investigating the structural/functional relationships in these proteins is that some of the most powerful genetic tools are unavailable because of the animal basis of their function; thus, high throughput tools using bacteria or yeast are, at present, not usable. However, the availability of genomewide screens in, for instance, fruit flies will make identification of further candidate roles for these proteins faster.
Are these proteins candidates for drug discovery directly? In principle, one might imagine that these proteins might be interesting candidates for drug discovery because of their important roles in establishing signalling systems. Historically, however, the pharmaceutical industry had little success with developing medicines based on protein–protein interaction. It seems rather unlikely that direct drug discovery will follow from this work (although the author would be delighted to be proved wrong!).
On the other hand, there are potential applications for these proteins that so far have not been explored. For example, both ankyrin and protein 4.1 are required for the cellular accumulation and intracellular targeting (as well as full activity) of many membrane proteins, including G protein-coupled receptors and voltage-gated sodium channels. These are important targets for pharmaceutical discovery. In programmes for discovering new medicines, the first step is often to express the target protein of interest in a recombinant animal cell. A consideration that must emerge from the work reviewed here is that the ankyrin/4.1 content of such cells must be considered in relation to establishing high-level expression of fully active and regulated target protein. Likewise, the production of pharmaceutical proteins from animal cells in culture typically requires large-scale culture under conditions of quite high shear stress. It may be possible to engineer animal cells, for production purposes, whose membranes are fitted to withstand shear forces, taking advantage of knowledge of the spectrin system.
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The authors are grateful to Dr. Marie-Christine Lecomte and Dr. Ekaterini Kordeli (INSERM, Paris) for their comments on the manuscript.
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Baines, A.J. The spectrin–ankyrin–4.1–adducin membrane skeleton: adapting eukaryotic cells to the demands of animal life. Protoplasma 244, 99–131 (2010). https://doi.org/10.1007/s00709-010-0181-1
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DOI: https://doi.org/10.1007/s00709-010-0181-1