Caspase remodeling of the spectrin membrane skeleton during lens development and aging

Terminal differentiation of lens fiber cells resembles the apoptotic process in that organelles are lost, DNA is fragmented, and changes in membrane morphology occur. However, unlike classically apoptotic cells, which are disintegrated by membrane blebbing and vesiculation, aging lens fiber cells are compressed into the center of the lens, where they undergo cell-cell fusion and the formation of specialized membrane interdigitations. In classically apoptotic cells, caspase cleavage of the cytoskeletal protein alpha-spectrin to approximately 150-kDa fragments is believed to be important for membrane blebbing. We report that caspase(s) cleave alpha-spectrin to approximately 150-kDa fragments and beta-spectrin to approximately 120- and approximately 80-kDa fragments during late embryonic chick lens development. These fragments continue to accumulate with age so that in the oldest fiber cells of the adult lens, most, if not all, of the spectrin is cleaved to discrete fragments. Thus, unlike classical apoptosis, where caspase-cleaved spectrin is short lived, lens fiber cells contain spectrin fragments that appear to be stable for the lifetime of the organism. Moreover, fragmentation of spectrin results in reduced membrane association and thus may lead to permanent remodeling of the membrane skeleton. Partial and specific proteolysis of membrane skeleton components by caspases may be important for age-related membrane changes in the lens.     

Ultracentrifugal analysis of the junction complexes of the red cell membrane cytoskeletal network: application to hereditary spherocytosis and metabolically depleted cells

A method has been developed for the assessment of the number of spectrin dimer units associated with each actin protofilament junction, in the membrane cytoskeletal network (i.e. the degree of branching) of the red cell. Ghosts are first exposed to elevated temperature at low ionic strength to dissociate some 65% of the spectrin tetramers (that link the network junctions) into dimers, without causing their release from the actin filaments. Non-ionic detergent is then added to solubilize the membrane itself with its intrinsic proteins, so as to liberate the cytoskeletal material, and the mixture is immediately examined in the analytical ultracentrifuge. The predominant components observed are isolated junctions (20 S), free spectrin dimers and the residual undissociated cytoskeletal material, with very minor components, probably corresponding to multiple junctions, linked by spectrin tetramers. The junction boundary is homogeneous within the accuracy of measurement and is taken to correspond to a complex containing six spectrin dimers, known to predominate in situ. About 17% of the total network is liberated in this form and 12% as free spectrin dimers. In hereditary spherocytosis both the size of the junction complex (as reflected by its sedimentation coefficient) and the proportion of the complex and of free spectrin liberated are indistinguishable from normal values. We conclude that the reported deficit of spectrin in hereditary spherocytosis is not reflected by a lower degree of branching of the network, and, if the membrane area is not correspondingly reduced, this must mean that the junctions are more widely spaced and the spectrin tetramers therefore more extended. In metabolically depleted cells, in which the cytoskeletal proteins are known to be extensively dephosphorylated, there is no change in the sedimentation pattern and thus no detectable loss of spectrin from the junctions or weakening in the cohesion of the cytoskeletal network.     

Fodrin CaM-binding domain cleavage by Pet from enteroaggregative Escherichia coli leads to actin cytoskeletal disruption

We have previously shown that the plasmid-encoded toxin (Pet) of enteroaggregative Escherichia coli produces cytotoxic and enterotoxic effects. Pet-intoxicated epithelial cells reveal contraction of the cytoskeleton and loss of actin stress fibres. Pet effects require its internalization into epithelial cells. We have also shown that Pet degrades erythroid spectrin. Pet delivery within the intestine suggests that Pet may degrade epithelial fodrin (non-erythroid spectrin). Here we demonstrate that Pet has affinity for alpha-fodrin (formally named alphaII spectrin) in vitro and in vivo and cleaves epithelial fodrin, causing its redistribution within the cells. When Pet has produced its cytoskeletal effects, fodrin is found in intracellular aggregates as membrane blebs. Pet cleaves recombinant GST-fodrin, generating two breakdown products of 37 and 72 kDa. Sequencing of the 37 kDa fragment demonstrated that the cleavage site occurred within fodrin's 11th repetitive unit between M1198 and V1199, in the calmodulin binding domain. Site-directed mutagenesis of these amino acids prevented fodrin degradation by Pet. Pet also cleaves epithelial fodrin from cultured Pet-treated cells. A mutant in the Pet serine protease motif was unable to cause fodrin redistribution or to cleave GST-fodrin. This is the first report showing cleavage of alpha-fodrin by a bacterial protease. Cleavage occurs in the middle of the calmodulin binding domain, which leads to cytoskeleton disruption.     

The effect of free fatty acids on spectrin organization in lymphocytes.

Previous studies have shown that cis unsaturated free fatty acids (uFFAs) are able to cause alterations in the normal distribution pattern of certain cytoskeletal proteins in lymphocytes, including tubulin, actin, alpha-actinin, and myosin. The cytoskeletal protein spectrin naturally possesses a marked heterogeneity of distribution among resting T and B lymphocytes isolated from all murine lymphoid organs. In some cells, spectrin is observed in a ring-like staining pattern at the periphery of the cell, reflecting a likely association with the cell membrane; in other cells, spectrin is found within the cytoplasm as a large single aggregate or in several smaller aggregates. Addition of uFFA to freshly isolated murine lymphocytes causes disruption in the latter pattern of spectrin organization. Following short-term incubation (15 min) of tissue-derived lymphocytes (from spleen, thymus, and lymph node) and 1 microgram/mL uFFA (oleic [18:1 cis], linoleic [18:2 cis, cis], arachidonic [20:4], or elaidic [18:1 trans] acid) there is a loss of cytoplasmic aggregates of spectrin and a concomitant increase in cells in which spectrin is diffusely distributed. This effect is not seen when two saturated FFAs (sFFAs) were used. When using DO11.10 cells, a T-cell hybridoma in which nearly all cells constitutively express a cytoplasmic aggregate of spectrin, a similar effect was observed, but greater concentrations (10-20 micrograms/mL) of FFA were needed to obtain the same effect. Addition of calcium to the incubation buffer substantially blocks spectrin reorganization. In several disease states, serum levels of FFA are observed to be excessively high; our data support the hypothesis that cytoskeletal reorganization in lymphocytes may be related to the altered immune function frequently observed in these conditions.     

Band 3 and ankyrin homologues are present in eye lens: evidence for all major erythrocyte membrane components in same non-erythroid cell

Although immunological homologues of erythrocyte membrane proteins have been individually discovered in a wide variety of tissues and cultured cells, the major structural components of the membrane have not yet been demonstrated simultaneously in the same cell type. Thus, considerable uncertainty continues to exist concerning whether the red cell homologues form elements of a structure which is similar to or unique from the framework which supports the erythrocyte membrane. Because the red cell cytoskeletal proteins, spectrin, actin and band 4.1, have been previously found in the superficial cortex of the lens, we decided to determine whether the corresponding membrane anchoring components of band 3 and ankyrin also occur in this cell type. Using antiserum specific for band 3 and ankyrin, we report the existence of immunologically cross-reactive proteins of similar molecular weight. Because these anchoring proteins appear and disappear coordinately with the aforementioned cytoskeletal proteins during the intermediate stages of lens cell maturation, it is conceivable that an erythrocyte-like membrane structural organization may occur transiently in the eye lens.     

Spectrin-actin associations studied by electron microscopy of shadowed preparations

By shadowing specimens dried onto mica sheets we have obtained clear images of actin crosslinked by spectrin, an actin-binding protein found in erythrocytes. We conclude that spectrin dimers possess a single binding site for F actin. Tetramers formed by head-to-head association of two dimers possess two actin binding sites, one at each tail. Polymerizing G actin in the presence of spectrin tetramers or mixing preformed F actin with spectrin tetramer plus band 4.1 results in an extensively crosslinked network of actin filaments. When G actin is polymerized in the presence of spectrin at spectrin:actin mole ratios close to that present on the erythrocyte membrane, large amorphous protein networks are formed. These networks are clusters of spectrin around 25 nm diameter structures which may be actin protofilaments. These networks are similar to the cytoskeletal network seen after erythrocyte membranes are extracted with detergent, and may represent the first in vitro assembly of a cytoskeletal complex resembling that of the native cell both biochemically and structurally.     

Characterization of lens fiber cell triton insoluble fraction reveals ERM (ezrin, radixin, moesin) proteins as major cytoskeletal-associated proteins

To understand lens fiber cell elongation- and differentiation-associated cytoskeletal remodeling, here we identified and characterized the major protein components of lens fiber cell Triton X-100 insoluble fraction by mass spectrometry and immunoblot analysis. This analysis identified spectrin, filensin, vimentin, tubulin, phakinin, and β-actin as major cytoskeletal proteins in the lens fibers. Importantly, ezrin, radixin, and moesin (ERM), heat-shock cognate protein 70, and β/γ-crystallins were identified as major cytoskeletal-associated proteins. ERM proteins were confirmed to exist as active phosphorylated forms that exhibited intense distribution in the organelle free-zone fibers. Furthermore, ERM protein phosphorylation was found to be dramatically reduced in Rho GTPase-targeted transgenic mouse lenses. These data identify the ERM proteins, which cross-link the plasma membrane and actin, as major and stable cytoskeletal-associated proteins in lens fibers, and indicate a potential role(s) for the ERMs in fiber cell actin cytoskeletal and membrane organization.     

Protein 4.1 in forebrain postsynaptic density preparations: enrichment of 4.1 gene products and detection of 4.1R binding proteins.

4.1 Proteins are a family of multifunctional cytoskeletal components (4.1R, 4.1G, 4.1N and 4.1B) derived from four related genes, each of which is expressed in the nervous system. Using subcellular fractionation, we have investigated the possibility that 4.1 proteins are components of forebrain postsynaptic densities, cellular compartments enriched in spectrin and actin, whose interaction is regulated by 4.1R. Antibodies to each of 4.1R, 4.1G, 4.1N and 4.1B recognize polypeptides in postsynaptic density preparations. Of these, an 80-kDa 4.1R polypeptide is enriched 11-fold in postsynaptic density preparations relative to brain homogenate. Polypeptides of 150 and 125 kDa represent 4.1B; of these, only the 125 kDa species is enriched (threefold). Antibodies to 4.1N recognize polypeptides of approximately 115, 100, 90 and 65 kDa, each enriched in postsynaptic density preparations relative to brain homogenate. Minor 225 and 200 kDa polypeptides are recognized selectively by specific anti-4.1G antibodies; the 200 kDa species is enriched 2.5-fold. These data indicate that specific isoforms of all four 4.1 proteins are components of postsynaptic densities. Blot overlay analyses indicate that, in addition to spectrin and actin, postsynaptic density polypeptides of 140, 115, 72 and 66 kDa are likely to be 4.1R-interactive. Of these, 72 kDa and 66 kDa polypeptides were identified as neurofilament L and alpha-internexin, respectively. A complex containing 80 kDa 4.1R, alpha-internexin and neurofilament L was immunoprecipitated with anti-4.1R antibodies from brain extract. We conclude that 4.1R interacts with the characteristic intermediate filament proteins of postsynaptic densities, and that the 4.1 proteins have the potential to mediate the interactions of diverse components of postsynaptic densities.     

Isolation and characterization of sea urchin egg spectrin: calcium modulation of the spectrin-actin interaction

Sea urchin egg spectrin has been purified from a homogenate of unfertilized Strongylocentrotus purpuratus eggs using standard biochemical procedures. SDS-PAGE analysis of the molecule revealed a closely spaced, high molecular weight doublet at 237/234 kDa (present in an equimolar ratio). Rotary shadowed images of egg spectrin revealed a double-stranded, elongate, flexible rod-shaped contour, measuring 210 nm in length and approximately 4-8 nm in width. Additionally, this molecule is shown to be immunologically related to avian erythroid spectrin, since it crossreacts with antibodies prepared against the chicken erythrocyte alpha-spectrin/240 kDa subunit. The interaction of egg spectrin with actin was examined by sedimentation and falling-ball viscometry assays. The binding and cross linking properties of spectrin to actin demonstrate a unique Ca++-sensitive regulation at micromolar Ca++ concentrations. This observation provides new insight into the way Ca++ may regulate spectrin-actin interactions in vitro and further suggests possible structural and modulatory roles for egg spectrin in the developing sea urchin embryo.     

Glycosylation of erythrocyte spectrin and its modification in visceral leishmaniasis

Using a lectin, Achatinin-H, having preferential specificity for glycoproteins with terminal 9-O-acetyl sialic acid derivatives linked in α2-6 linkages to subterminal N-acetylgalactosamine, eight distinct disease-associated 9-O-acetylated sialoglycoproteins was purified from erythrocytes of visceral leishmaniaisis (VL) patients (RBC(VL)). Analyses of tryptic fragments by mass spectrometry led to the identification of two high-molecular weight 9-O-acetylated sialoglycoproteins as human erythrocytic α- and β-spectrin. Total spectrin purified from erythrocytes of VL patients (spectrin(VL)) was reactive with Achatinin-H. Interestingly, along with two high molecular weight bands corresponding to α- and β-spectrin another low molecular weight 60 kDa band was observed. Total spectrin was also purified from normal human erythrocytes (spectrin(N)) and insignificant binding with Achatinin-H was demonstrated. Additionally, this 60 kDa fragment was totally absent in spectrin(N). Although the presence of both N- and O-glycosylations was found both in spectrin(N) and spectrin(VL), enhanced sialylation was predominantly induced in spectrin(VL). Sialic acids accounted for approximately 1.25 kDa mass of the 60 kDa polypeptide. The demonstration of a few identified sialylated tryptic fragments of α- and β-spectrin(VL) confirmed the presence of terminal sialic acids. Molecular modelling studies of spectrin suggest that a sugar moiety can fit into the potential glycosylation sites. Interestingly, highly sialylated spectrin(VL) showed decreased binding with spectrin-depleted inside-out membrane vesicles of normal erythrocytes compared to spectrin(N) suggesting functional abnormality. Taken together this is the first report of glycosylated eythrocytic spectrin in normal erythrocytes and its enhanced sialylation in RBC(VL). The enhanced sialylation of this cytoskeleton protein is possibly related to the fragmentation of spectrin(VL) as evidenced by the presence of an additional 60 kDa fragment, absent in spectrin(N) which possibly affects the biology of RBC(VL) linked to both severe distortion of erythrocyte development and impairment of erythrocyte membrane integrity and may provide an explanation for their sensitivity to hemolysis and anemia in VL patients.     

Relationship between membrane lipid mobility and spectrin distribution in lymphocytes.

We have previously established that T and B lymphocytes in situ are remarkably heterogeneous with respect to the cytoskeletal protein spectrin. Since in erythrocytes spectrin is known to play an important role in the regulation of membrane fluidity, lipid organization and lateral mobility of membrane proteins, we have sought to determine if the heterogeneous patterns of spectrin distribution that we have observed are related to possible differences in membrane lipid organization in these various subsets. To this end, we have utilized a fluorescent pyrene-labelled phospholipid as a probe of the lipid lateral mobility and have examined two related T cell systems maintained in vitro, DO.11.10 cells and a spontaneously arising variant, DO.11.10V. In these (and other cloned in vitro systems) we have previously observed that the cells homogeneously express one of the kinds of spectrin distribution patterns observed in situ. Thus the uniformity of staining of these systems permits us to address whether the various patterns of spectrin distribution may be predictive of differences in membrane lipid properties. Here we show that in cells in which there is little or nor spectrin at the plasma membrane (DO.11.10) that the lipids in the plasma membrane are considerably less mobile than in its related variant in which spectrin is diffusely distributed within the cell and at the plasma membrane. From this and previous results, we conclude that differences in the distribution of the cytoskeletal protein spectrin among lymphocytes may be a useful parameter in helping to predict the status of membrane lipid organization.     

Synthesis and assembly of spectrin during avian erythropoiesis: Stoichiometric assembly but unequal synthesis of α and β spectrin

The synthesis and assembly of spectrin was investigated in erythroid cells during chicken embryo development. Immunoprecipitation of Triton X-100-soluble and -insoluble cytoskeletal fractions with α- and β-spectrin antisera show that, at steady state, α and β spectrin are present in stoichiometric amounts, and exclusively, in the cytoskeleton. However, pulse labeling of cells and in vitro translation of total erythroid cell RNA reveal that α spectrin is synthesized in a two to three fold excess over β spectrin. Pulse-chase experiments show that newly synthesized α and β spectrin are present in both the cytoskeletal and soluble fractions, and that stoichiometric amounts are stably assembled in the cytoskeleton. On the other hand, there is a severalfold excess of α relative to β spectrin in the soluble fraction, both of which turn over with a half-life of 50 min. In cells from 4 day old embryos, more than 80% of the newly synthesized β spectrin, but only 10% of the α spectrin, are present in the cytoskeleton. Thus, early in development, the association of α and β spectrin with the membrane-cytoskeleton may be rate-limited by the amount of β spectrin synthesized. Later on in erythroid development, progressively lesser proportions of newly synthesized β spectrin are present in the cytoskeleton, suggesting that during development, the rate of association of β spectrin with the membrane-cytoskeleton becomes limited by some other membrane-cytoskeletal component.     

The effect of free fatty acids on spectrin organization in lymphocytes

Previous studies have shown thatcis unsaturated free fatty acids (uFFAs) are able to cause alterations in the normal distribution pattern of certain cytoskeletal proteins in lymphocytes, including tubulin, actin, α-actinin, and myosin. The cytoskeletal protein spectrin naturally possesses a marked heterogeneity of distribution among resting T and B lymphocytes isolated from all murine lymphoid organs. In some cells, spectrin is observed in a ring-like staining pattern at the periphery of the cell, reflecting a likely association with the cell membrane; in other cells, spectrin is found within the cytoplasm as a large single aggregate or in several smaller aggregates. Addition of uFFA to freshly isolated murine lymphocytes causes disruption in the latter pattern of spectrin organization. Following short-term incubation (15 min) of tissue-derived lymphocytes (from spleen, thymus, and lymph node) and 1 μg/mL uFFA (oleic [18:1cis], linoleic [18:2cis, cis], arachidonic [20:4], or elaidic [18:1trans] acid) there is a loss of cytoplasmic aggregates of spectrin and a concomitant increase in cells in which spectrin is diffusely distributed. This effect is not seen when two saturated FFAs (sFFAs) were used. When using DO11.10 cells, a T-cell hybridoma in which nearly all cells constitutively express a cytoplasmic aggregate of spectrin, a similar effect was observed, but greater concentrations (10–20 μg/mL) of FFA were needed to obtain the same effect. Addition of calcium to the incubation buffer substantially blocks spectrin reorganization. In several disease states, serum levels of FFA are observed to be excessively high; our data support the hypothesis that cytoskeletal reorganization in lymphocytes may be related to the altered immune function frequently observed in these conditions.     

Polarization of NK cell cytoskeleton upon conjugation with sensitive target cells

We studied the cytoskeletal changes in natural killer (NK) cells during conjugate formation, i.e., when NK cells make contact with sensitive vs resistant target cells. F-actin and vinculin were seen to polarize at the contact sites upon conjugation with sensitive K562 cells, whereas in conjugates with resistant Raji target cells such an orientation was an infrequent finding. Myosin and two other cytoskeletal proteins, spectrin and vimentin, on the other hand, showed a random distribution in conjugating NK cells regardless of the target cell type. Hence the cytoskeletal redistribution associated with conjugation seems to be different from the receptor capping phenomenon, which is accompanied by clustering of actin, myosin, vimentin, and spectrin. On the basis of these results it seems probable that the lytic conjugate formation in NK-mediated cytotoxicity is associated with the formation of a specific type of junction that involves actin and vinculin. This cytoskeletal reorganization precedes and could be a prerequisite for the polarization of the cellular secretory apparatus and may be functionally responsible for the required cytokinetic movements.     

p103 and A60: novel proteins of the neuronal membrane-associated cytoskeleton.

Associated with the neuronal plasma membrane are cytoskeletal proteins which probably control the specialization of the membrane into axonal and dendritic domains. Specialized isoforms of the proteins spectrin and ankyrin are located in each region and provide molecular mechanisms for locating specific transmembrane proteins at required points. However, spectrin and ankyrin were defined by extensions of the model for the erythrocyte membrane, an analogy unlikely to provide a complete account of the neuronal membrane skeleton. We have defined two new proteins of the neuronal membrane skeleton, designated p103 and A60. p103 is enriched in post-synaptic densities and binds with high affinity to integral membrane proteins--we suggest that it may have a role in linking the cytoskeleton to synaptic glycoproteins. A60 is a 60 kDa axonal protein, which appears to form a lining to the axolemma. It is almost exclusively axonal, although some neurons (such as Purkinje cells) appear to contain it in the cell body and initial dendrite segment. A60 binds both ankyrin and neurofilaments, and may have a role in transmitting information critical to axonal morphology to the membrane.     

Asymmetric distribution of phospholipids in spectrin-poor erythrocyte vesicles

We have investigated by electron spin resonance, at 37 degrees C, the outside-inside passage and the equilibrium distribution of spin-labeled phospholipids, respectively, in ATP-containing ghosts, in heat-treated erythrocytes, and in heat-induced vesicles. The heat-treated vesicles were spectrin depleted to approximately 25% of the original content and had lost almost 100% of the other cytoskeletal proteins. Yet the vesicles, as long as they contained ATP, were capable of translocating the aminophospholipids with the same efficiency as the heat-treated erythrocytes, and almost with the same efficiency as ATP-containing ghosts. In the vesicles, sphingomyelin and phosphatidylcholine analogues underwent a very slow transverse diffusion as in native cells. We conclude that spectrin and other cytoskeleton proteins are not major factors for the establishment and maintenance of phospholipid asymmetry in human erythrocytes, which may be chiefly due to the aminophospholipid translocase activity.     

The elasticity of spectrin-actin gels at high protein concentration

Human erythrocyte spectrin of high purity was studied alone and mixed with rabbit skeletal actin by dynamic rheometry as a function of protein concentration at pH 7.4 and 24 degrees C. Pure spectrin had a very low storage modulus, G', increasing slightly with increase in protein concentration (approximately 3 dynes/cm at 25 mg/ml). In contrast, unpurified cytoskeletal extracts containing spectrin, actin, and band 4.1 showed a marked concentration dependence for G', increasing to 150 dynes/cm at 20 mg/ml. Mixtures of purified spectrin and skeletal actin at a weight ratio of 4:1 also showed G' markedly dependent on concentration (approximately 150-200 dynes/cm at 20 mg/ml). Maximum elasticity of spectrin-actin gels occurred at a molar ratio of actin monomers to spectrin tetramers of 14:1. We conclude that the reconstituted in vitro spectrin-actin network consists of actin fibers cross-linked by spectrin tetramers at regular intervals. The gel is rapidly reformed after mechanical disruption or thermal collapse, indicating that the polymer fibers are in equilibrium with the constituent monomers.     

Characterization of the bovine lens plasma membrane substrates for cAMP-dependent protein kinase

cAMP-dependent protein kinase, derived from either calf lens or bovine heart, promotes the phosphorylation of three lens plasma membrane proteins of molecular mass 28 kDa, 26 kDa and 18 kDa. Correlation of the maximal level of phosphorylation of these components with the Coomassie blue staining intensity of fractionated lens membranes suggests that the phosphorylation of the 28 kDa and 18 kDa components may be approximately stoichiometric. The protein kinase substrates could be dephosphorylated by a cardiac sarcoplasmic-reticulum-bound protein phosphatase activity. The 26 k Da component comigrated with MP26, the major lens membrane component that has been localized to the lens fiber cell junction. Treatment of phosphorylated lens membranes with chymotrypsin did not suggest that any of the three major phosphorylated components was derived from the partial proteolysis of a larger phosphoprotein. After electrophoretic separation of phosphorylated proteins, treatment with N-chlorosuccinimide confirmed that there was little similarity in the structure of the three phosphoproteins. Chymotrypsin did, however, reveal a cryptic phosphorylation site in a 22 kDa fragment that appeared to be derived from MP26. Treatment of phosphorylated membranes with reducing agents resulted in the disappearance of the 28 kDa phosphorylated component and the appearance of a new phosphorylated component of 18 kDa; neither MP26 nor the original 18 kDa component was affected by such treatment. It is not clear whether the original 18 kDa phosphoprotein, present in unreduced samples, is the same as that generated with reducing agents from the 28 kDa phosphorylated lens membrane component.     

Development and Maintenance of the Neuronal Cytoskeleton in Aggregated Cell Cultures of Fetal Rat Telencephalon and Influence of Elevated K+ Concentrations

Serum-free aggregating cell cultures of fetal rat telencephalon were examined by biochemical and immunocytochemical methods for their development-dependent expression of several cytoskeletal proteins, including the heavy- and medium-sized neurofilament subunits (H-NF and M-NF, respectively); brain spectrin; synapsin I; beta-tubulin; and the microtubule-associated proteins (MAPs) 1, 2, and 5 and tau protein. It was found that with time in culture the levels of most of these cytoskeletal proteins increased greatly, with the exceptions of the particular beta-tubulin form studied, which remained unchanged, and MAP 5, which greatly decreased. Among the neurofilament proteins, expression of M-NF preceded that of H-NF, with the latter being detectable only after approximately 3 weeks in culture. Furthermore, MAP 2 and tau protein showed a development-dependent change in expression from the juvenile toward the adult form. The comparison of these developmental changes in cytoskeletal protein levels with those observed in rat brain tissue revealed that protein expression in aggregate cultures is nearly identical to that in vivo during maturation of the neuronal cytoskeleton. Aggregate cultures deprived of glial cells, i.e., neuron-enriched cultures prepared by treating early cultures with the antimitotic drug cytosine arabinoside, exhibited pronounced deficits in M-NF, H-NF, MAP 2, MAP 1, synapsin I, and brain spectrin, with increased levels of a 145-kDa brain spectrin breakdown product. These adverse effects of glial cell deprivation could be reversed by the maintenance of neuron-enriched cultures at elevated concentrations of KCl (30 mM). This chronic treatment had to be started at an early developmental stage to be effective, a finding suggesting that sustained depolarization by KCl is able to enhance the developmental expression and maturation of the neuronal cytoskeleton.     

Spectrin-like proteins in green algae (Desmidiaceae)

Immunochemical detection of actin as well as spectrin-like proteins have been carried out in the green algae Micrasterias denticulata, Closterium lunula, and Euastrum oblongum. In these algae, actin is detected on Western blots at 43 kDa with antibodies to actin from higher plant and animal origin. By use of antibodies to human and chicken erythrocyte spectrin a cross-reactivity with desmid proteins is found at about the molecular mass of 220 kDa, where also human erythrocyte spectrin is detected. Additional bands are present at 120 kDa and 70 kDa, which are probably breakdown products. An antibody against chicken alpha-actinin, a small protein of the spectrin superfamily, recognizes bands at 90 kDa, where it is expected, and 70 kDa, probably the same breakdown product as mentioned for spectrin. Isoelectric focusing provides staining at pI 4.6 with antibodies against spectrin. Immunogold labelling of spectrin and alpha-actinin antigens on high-pressure frozen, freeze-substituted Micrasterias denticulata cells with the same antibodies exhibits staining, especially at membranes of different populations of secretory vesicles, at dictyosomes, and the plasma membrane. However, no clear correlation to the growth pattern of the cell could be observed. Taken together, our results demonstrate the presence of spectrin-like proteins in desmid cells which are probably functional in exocytosis.