A spectrin-like protein from mouse brain membranes: immunological and structural correlations with erythrocyte spectrin

The Spectrinome: The Interactome of a Scaffold Protein Creating Nuclear and Cytoplasmic Connectivity and Function

We provide a review of Spectrin isoform function in the cytoplasm, the nucleus, the cell surface, and in intracellular signaling. We then discuss the importance of Spectrin’s E2/E3 chimeric ubiquitin conjugating and ligating activity in maintaining cellular homeostasis. Finally we present spectrin isoform subunit specific human diseases. We have created the Spectrinome, from the Human Proteome, Human Reactome and Human Atlas data and demonstrated how it can be a useful tool in visualizing and understanding spectrins myriad of cellular functions.

Impact statement

Spectrin was for the first 12 years after its discovery thought to be found only in erythrocytes. In 1981, Goodman and colleagues1found that spectrin-like molecules were ubiquitously found in non-erythroid cells leading to a great multitude of publications over the next thirty eight years. The discovery of multiple spectrin isoforms found associated with every cellular compartment, and representing 2-3% of cellular protein, has brought us to today’s understanding that spectrin is a scaffolding protein, with its own E2/E3 chimeric ubiquitin conjugating ligating activity that is involved in virtually every cellular function. We cover the history, localized functions of spectrin isoforms, human diseases caused by mutations, and provide the spectrinome: a useful tool for understanding the myriad of functions for one of the most important proteins in all eukaryotic cells.

Subcortical cytoskeleton periodicity throughout the nervous system

Superresolution fluorescence microscopy recently revealed a ~190 nm periodic cytoskeleton lattice consisting of actin, spectrin, and other proteins underneath the membrane of cultured hippocampal neurons. Whether the periodic cytoskeleton lattice is a structural feature of all neurons and how it is modified when axons are ensheathed by myelin forming glial cells is not known. Here, STED nanoscopy is used to demonstrate that this structure is a commonplace of virtually all neuron types in vitro. To check how the subcortical meshwork is modified during myelination, we studied sciatic nerve fibers from adult mice. Periodicity of both actin and spectrin was uncovered at the internodes, indicating no substantial differences between unmyelinated and myelinated axons. Remarkably, the actin/spectrin pattern was also detected in glial cells such as cultured oligodendrocyte precursor cells. Altogether our work shows that the periodic subcortical cytoskeletal meshwork is a fundamental characteristic of cells in the nervous system and is not a distinctive feature of neurons, as previously thought.

Spectrin's chimeric E2/E3 enzymatic activity

In this minireview, we cover the discovery of the human erythrocyte α spectrin E2/E3 ubiquitin conjugating/ligating enzymatic activity and the specific cysteines involved. We then discuss the consequences when this activity is partially inhibited in sickle cell disease and the possibility that the same attenuation is occurring in multiple organ dysfunction syndrome. We finish by discussing the reasons for believing that nonerythroid α spectrin isoforms (I and II) also have this activity and the importance of testing this hypothesis. If correct, this would suggest that the nonerythroid spectrin isoforms play a major role in protein ubiquitination in all cell types. This would open new fields in experimental biology focused on uncovering the impact that this enzymatic activity has upon protein-protein interactions, protein turnover, cellular signaling, and many other functions impacted by spectrin, including DNA repair.

Microwave & magnetic (M2) proteomics reveals CNS-specific protein expression waves that precede clinical symptoms of experimental autoimmune encephalomyelitis

Central nervous system-specific proteins (CSPs), transported across the damaged blood-brain-barrier (BBB) to cerebrospinal fluid (CSF) and blood (serum), might be promising diagnostic, prognostic and predictive protein biomarkers of disease in individual multiple sclerosis (MS) patients because they are not expected to be present at appreciable levels in the circulation of healthy subjects. We hypothesized that microwave &magnetic (M(2)) proteomics of CSPs in brain tissue might be an effective means to prioritize putative CSP biomarkers for future immunoassays in serum. To test this hypothesis, we used M(2) proteomics to longitudinally assess CSP expression in brain tissue from mice during experimental autoimmune encephalomyelitis (EAE), a mouse model of MS. Confirmation of central nervous system (CNS)-infiltrating inflammatory cell response and CSP expression in serum was achieved with cytokine ELISPOT and ELISA immunoassays, respectively, for selected CSPs. M(2) proteomics (and ELISA) revealed characteristic CSP expression waves, including synapsin-1 and α-II-spectrin, which peaked at day 7 in brain tissue (and serum) and preceded clinical EAE symptoms that began at day 10 and peaked at day 20. Moreover, M(2) proteomics supports the concept that relatively few CNS-infiltrating inflammatory cells can have a disproportionally large impact on CSP expression prior to clinical manifestation of EAE.

Spectrin Breakdown Products (SBDPs) as Potential Biomarkers for Neurodegenerative Diseases

The world's human population ages rapidly thanks to the great advance in modern medicine. While more and more body system diseases become treatable and curable, age-related neurodegenerative diseases remain poorly understood mechanistically, and are desperately in need of preventive and therapeutic interventions. Biomarker development consists of a key part of concerted effort in combating neurodegenerative diseases. In many chronic neurodegenerative conditions, neuronal damage/death occurs long before the onset of disease symptoms, and abnormal proteolysis may either play an active role or be a companying event of neuronal injury. Increased spectrin cleavage yielding elevated spectrin breakdown products (SBDPs) by calcium-sensitive proteases such as calpain and caspases has been established in conditions associated with acute neuronal damage such as traumatic brain injury (TBI). Here we review literature regarding spectrin expression and metabolism in the brain, and propose a potential use of SBDPs as biomarkers for neurodegenerative diseases such as Alzheimer's diseases.

Co-localization of the myelin-associated glycoprotein and the microfilament components, F-actin and spectrin, in Schwann cells of myelinated nerve fibres

The myelin-associated glycoprotein (MAG) is an intrinsic membrane protein that is specific for myelinating cells. MAG has been proposed to function in the PNS as an adhesion molecule involved in Schwann cell-axon contact and maintenance of cytoplasmic channels within the myelin sheath. In this report we show that the microfilament components, F-actin and spectrin, co-localize with MAG in periaxonal membranes, Schmidt-Lanterman incisures, paranodal myelin loops, and inner and outer mesaxons of myelinating Schwann cells. F-actin was localized light microscopically by rhodamine-labelled phallicidin binding. Spectrin and MAG were localized by light microscopic and ultrastructural immunocytochemistry. The findings indicate that plasma membrane linkage of F-actin in Schwann cells is likely to occur via spectrin, and raise the possibility that microfilaments interact with the cytoplasmic domain of MAG. An interaction between MAG and microfilaments would be consistent with the proposed function of MAG as an adhesion molecule.

Spectrin synthesis in the preimplantation mouse embryo

The preimplantation mouse embryo expresses two polypeptides, Mr 240,000 and Mr 235,000, that are immunologically cross-reactive with antibody to the alpha and beta subunits of mouse brain spectrin. We investigated the synthesis of the spectrin subunits in the Triton-soluble and Triton-insoluble fractions of fertilized eggs, two-cell embryos, compacted morulae, and blastocysts labeled with L-[35S]methionine. Synthesis of embryonic spectrin began in the Triton-soluble fraction with significant levels of alpha-spectrin synthesis first detected in the morula stage and significant levels of beta-spectrin synthesis detected in the blastocyst stage. Incorporation of newly synthesized alpha- and beta-spectrin into the cytoskeletal fraction took place in the blastocyst when equal amounts of both subunits were assembled. Previous studies have shown Triton-insoluble spectrin to be concentrated in regions of cell-cell contact in the embryo (J. S. Sobel and M. A. Alliegro, 1985, J. Cell Biol. 100, 333-336). The temporal and spatial correlation between the assembly of newly synthesized spectrin and its concentration in regions of cell apposition is consistent with the hypothesis that cell contact may influence the assembly of embryonic spectrin.

Spectrin and related molecules

This review begins with a complete discussion of the erythrocyte spectrin membrane skeleton. Particular attention is given to our current knowledge of the structure of the RBC spectrin molecule, its synthesis, assembly, and turnover, and its interactions with spectrin-binding proteins (ankyrin, protein 4.1, and actin). We then give a historical account of the discovery of nonerythroid spectrin. Since the chicken intestinal form of spectrin (TW260/240) and the brain form of spectrin (fodrin) are the best characterized of the nonerythroid spectrins, we compare these molecules to RBC spectrin. Studies establishing the existence of two brain spectrin isoforms are discussed, including a description of the location of these spectrin isoforms at the light- and electron-microscope level of resolution; a comparison of their structure and interactions with spectrin-binding proteins (ankyrin, actin, synapsin I, amelin, and calmodulin); a description of their expression during brain development; and hypotheses concerning their potential roles in axonal transport and synaptic transmission.

Immunological detection of high molecular weight proteins by gel and blot overlay

The sensitivity and specificity of the gel overlay and western blot methods of immunodetection are compared for spectrins, typical high molecular weight proteins. The gel overlay method is more sensitive and specific for the immunodetection of brain spectrin (240/235) and rbc spectrin. As the western blot technique will remain the method of choice for many applications because of its relative speed, we discuss methods for optimizing its sensitivity and selectivity.

Postnatal development of immunohistochemically localized spectrin-like protein (calspectin or fodrin) in the rat visual cortex: its excessive expression in developing cortical neurons

Postnatal development of the expression and localization of a membrane-associated cytoskeletal protein, calspectin (fodrin or brain spectrin), in the visual cortex, was immunohistochemically studied in newborn to adult rats, by using an anti-calspectin antibody. At birth, calspectin-immunoreactivity was already present at the plasma membrane and in the cytoplasm of neurons which were mostly pyramidal cells located in the upper part of the cortical subplate. Immature neurons located in the cortical plate were not stained by the antibody, suggesting that calspectin is expressed only in neurons which have differentiated or are differentiating. At postnatal days 2 to 7, immunoreactive neurons were dramatically increased in layers V and VI and very intense labelling was seen in the apical dendrites of layer V pyramidal cells. Most of the stained processes of these and other neurons showed signs of rapid dendritic growth, i.e. non-terminal as well as terminal growth cones and filopodia. At days 10 to 17, dendrites of pyramidal cells in layers II and III became clearly detectable, although still slender. At days 24 to 34, the basal dendrites of pyramidal cells in layers II, III and V became intensely immunoreactive and dendritic spines were visualized by the antibody. In the adult, however, the calspectin immunoreactivity became very weak and spines were not recognizable. At all the ages, axons and neuroglia were unstained. Also, most of the neurons in layer IV of the cortex were not immunoreactive. These results suggest that calspectin is most abundantly expressed in growing parts of the dendrites and spines. A hypothesis that calspectin may play a role in synaptic plasticity in the developing visual cortex is discussed.

Gelation and fodrin purification from rat brain extracts

Extracts from rat brain tissue have been shown to give rise to a gel which exhibits the following features. It is mainly enriched in actin and in a high-molecular-weight protein with polypeptide chains of 235 and 240 kDa, which we identified as fodrin. Tubulin is also a major component of the gel but it appears to be trapped non-specifically during the gelation process. Gelation is pH-, ionic strength- and Ca2+-concentration-dependent, and is optimal under the conditions which promote the interaction between polymerized actin and fodrin. In a similar way to that described for the purification of rat brain actin (Levilliers, N., Péron-Renner, M., Coffe, G. and Pudles, J. (1984) Biochimie 66, 531-537), we used the gelation system as a selective means of recovering fodrin from the mixture of a low-ionic-strength extract from whole rat brain and a high-ionic-strength extract of the particulate fraction. From this gel, fodrin was purified with a good yield by a simple procedure involving gel dissociation in 0.5 M KCl and depolymerization in 0.7 M KI, Bio-Gel A-15m chromatography, followed by ammonium sulfate precipitation.

Brain spectrin(240/235) and brain spectrin(240/235E): two distinct spectrin subtypes with different locations within mammalian neural cells

Adult mouse brain contains at least two distinct spectrin subtypes, both consisting of 240-kD and 235-kD subunits. Brain spectrin(240/235) is found in neuronal axons, but not dendrites, when immunohistochemistry is performed with antibody raised against brain spectrin isolated from enriched synaptic/axonal membranes. A second spectrin subtype, brain spectrin(240/235E), is exclusively recognized by red blood cell spectrin antibody. Brain spectrin(240/235E) is confined to neuronal cell bodies and dendrites, and some glial cells, but is not present in axons or presynaptic terminals.

Changes in the distribution of a spectrin-like protein during development of the preimplantation mouse embryo

The mouse blastocyst expresses a 240,000-mol-wt polypeptide that cross-reacts with antibody to avian erythrocyte alpha-spectrin. Immunofluorescence localization showed striking changes in the distribution of the putative embryonic spectrin during preimplantation and early postimplantation development. There was no detectable spectrin in either the unfertilized or fertilized egg. The first positive reaction was observed in the early 2-cell stage when a bright band of fluorescence delimited the region of cell-cell contact. The blastomeres subsequently developed continuous cortical layers of spectrin and this distribution was maintained throughout the cleavage stages. A significant reduction in fluorescence intensity occurred before implantation in the apical region of the mural trophoblast and the trophoblast outgrowths developed linear arrays of spectrin spots that were oriented in the direction of spreading. In contrast to the alterations that take place in the periphery of the embryo, spectrin was consistently present in the cortical cytoplasm underlying regions of contact between the blastomeres and between cells of the inner cell mass. The results suggest a possible role for spectrin in cell-cell interactions during early development.

Purification of a high molecular weight actin filament gelation protein from Acanthamoeba that shares antigenic determinants with vertebrate spectrins

I have purified a high molecular weight actin filament gelation protein (GP-260) from Acanthamoeba castellanii, and found by immunological cross-reactivity that it is related to vertebrate spectrins, but not to two other high molecular weight actin-binding proteins, filamin or the microtubule-associated protein, MAP-2. GP-260 was purified by chromatography on DEAE-cellulose, selective precipitation with actin and myosin-II, chromatography on hydroxylapatite in 0.6 M Kl, and selective precipitation at low ionic strength. The yield was 1-2 micrograms/g cells. GP-260 had the same electrophoretic mobility in SDS as the 260,000-mol-wt alpha-chain of spectrin from pig erythrocytes and brain. Electron micrographs of GP-260 shadowed on mica showed slender rod-shaped particles 80-110 nm long. GP-260 raised the low shear apparent viscosity of solutions of Acanthamoeba actin filaments and, at 100 micrograms/ml, formed a gel with a 8 microM actin. Purified antibodies to GP-260 reacted with both 260,000- and 240,000-mol-wt polypeptides in samples of whole ameba proteins separated by gel electrophoresis in SDS, but only the 260,000-mol-wt polypeptide was extracted from the cell with 0.34 M sucrose and purified in this study. These antibodies to GP-260 also reacted with purified spectrin from pig brain and erythrocytes, and antibodies to human erythrocyte spectrin bound to GP-260 and the 240,000-mol-wt polypeptide present in the whole ameba. The antibodies to GP-260 did not bind to chicken gizzard filamin or pig brain MAP-2, but they did react with high molecular weight polypeptides from man, a marsupial, a fish, a clam, a myxomycete, and two other amebas. Fluorescent antibody staining with purified antibodies to GP-260 showed that it is concentrated near the plasma membrane in the ameba.

Brain spectrin: a review

Red blood cell spectrin, along with actin and several other proteins, forms a skeletal meshwork on the cytoplasmic surface of the erythrocyte plasma membrane. This structure is thought to maintain red blood cell shape, membrane structural stability, and cellular elasticity, as well as controlling the lateral mobility of integral membrane proteins and the transbilayer movement of phospholipids. It is now clearly established that spectrin-related molecules are ubiquitous structural elements subjacent to the plasma membrane of mammalian and avian nonerythroid cells. In this review, we present the current knowledge concerning brain spectrin. Brain spectrin is an approximately 11S, approximately 1,000,000 molecular weight (alpha beta)2 tetramer containing subunits of 240,000 (alpha) and 235,000 (beta) molecular weight. It is present in the cortical cytoplasm of all neuronal cell bodies and processes, and to a lesser extent in glial cells. Its involvement in the actin-membrane interaction, as well as other proposed functions in the nervous system is discussed.

Normal content of brain spectrin-like protein in sph/sph mice

In the erythrocytes of WBB6F1-sph/sph mice spectrin constitutes only approximately 1% of the total sph/sph membrane protein compared to approximately 23% in WBB6F1-+/+ controls. No increase in proteolytic degradation of spectrin in sph/sph erythrocyte membranes could be detected with antibodies directed against mouse erythrocyte spectrin or mouse brain spectrin-like protein. As attachment of normal spectrin to the erythrocyte membrane of these animals appeared to be normal, and as spectrin is not detected when whole sph/sph erythrocytes are solubilized in SDS for SDS PAGE, the deficient erythrocyte spectrin was probably due to diminished production. Brain spectrin-like protein, a nonerythroid spectrin analogue, is antigenically, morphologically and functionally related to erythrocyte spectrin, but appears by peptide mapping analysis to be a distinct gene product. It was found by protein- and antibody-staining of brain membranes to be present in normal concentrations in sph/sph animals. Indirect immunofluorescence of mouse brain tissue with anti-brain spectrin-like protein IgG or anti-erythrocyte spectrin IgG indicated that the distribution of brain spectrin-like protein was normal in sph/sph brain. Therefore the mutation causing diminished production of sph/sph erythrocyte spectrin does not affect the expression of this nonerythroid spectrin analogue.

Identification and location of brain protein 4.1

Protein 4.1 is a membrane skeletal protein that converts the low-affinity interaction between spectrin and actin into a high-affinity ternary complex of spectrin, protein 4.1, and actin that is essential to the structural stability of the erythrocyte. Pig brain was shown to contain an 87-kilodalton immunoreactive analog of protein 4.1 that has partial sequence homology with pig erythrocyte protein 4.1 and the same location as spectrin in the cortical cytoplasm of neuronal and glial cell types of the cerebellum.