Structure and composition of the cytoskeleton of nucleated erythrocytes: III. Organization of the cytoskeleton of Bufo marinus erythrocytes as revealed by freeze-dried platinum-carbon replicas and immunofluorescence microscopy

The mouse synemin gene encodes three intermediate filament proteins generated by alternative exon usage and different open reading frames

We have previously cloned and characterized the human synemin gene, which encodes two intermediate filament proteins (IFPs). We now show that the mouse synemin gene encodes three different synemin isoforms through an alternative splicing mechanism. Two of them, synemin H and M are similar to human alpha and beta synemin, and the third isoform, L synemin, constitutes a new form of IFP. It has a typical rod domain and a short tail (49 residues) with a novel sequence that is produced by a different open reading frame. The synthesis of H/M synemins starts in the embryo, whereas the synemin L isoform is present in adult muscles. The H/M isoforms are bound to desmin or vimentin in the muscle cells of wild-type mice. Using desmin- and vimentin-deficient mice, we have obtained direct evidence that synemin is associated with muscle intermediate filaments in vivo. The organization of the synemin fibril is disrupted in skeletal and cardiac muscle when desmin is absent and in smooth muscle when vimentin is absent. The fact that the three synemin isoforms differ in the sequences of their tail domains as well as in their developmental patterns suggests that they fulfill different functions.

Occurrence of echinocytosis in circulating RBC of black bullhead, Ictalurus melas (Rafinesque), following exposure to an anionic detergent at sublethal concentrations

The shape of the erythrocytes can be altered by a great variety of chemical agents, such as many detergents due to their amphiphilic nature. The present study examines the effect of an anionic detergent on the shape of mature, circulating catfish red blood cells. Experimental exposure to sodium dodecyl benzene sulphonate dissolved in the water of aquaria at two sublethal concentrations (1.5 and 3 ppm), for a maximum of 15 days, induced morphological changes of normal erythrocyte shape to echinocytic form. These changes were evaluated at 5, 10 and 15 days after the start of treatment, using scanning electron microscopy. The crenated erythrocytes from animals exposed to detergent appeared either with border irregularities or undulations, without distinct spicules, or with numerous short spikes. Statistical analysis, applied to the data obtained from counting altered cells in the various experimental groups, showed no significant difference between the 1.5 ppm-treated animals at the three times and the controls, whereas a significant difference was observed between 3 ppm-treated animals compared to the controls, showing significance of action of the higher dose employed at the three times. These data suggest latent erythrocyte damage. The results are discussed in the light of the extensive bibliography concerning evaginating amphiphilic compounds and the mechanisms involved in echinocyte formation, taking into account the marked differences existing between the nucleated red blood cells of fish and those biconcave, unnucleated of mammals.

Human synemin gene generates splice variants encoding two distinct intermediate filament proteins

Intermediate filament (IF) proteins are constituents of the cytoskeleton, conferring resistance to mechanical stress, and are encoded by a dispersed multigene family. In man we have identified two isoforms (180 and 150 kDa) of the IF protein synemin. Synemin alpha and beta have a very short N-terminal domain of 10 amino acids and a long C-terminal domain consisting of 1243 amino acids for the alpha isoform and 931 amino acids for the beta isoform. An intronic sequence of the synemin beta isoform is used as a coding sequence for synemin alpha. Both mRNA isoforms (6.5 and 7.5 kb) result from alternative splicing of the same gene, which has been assigned to human chromosome 15q26.3. Analyses by Northern and Western blot revealed that isoform beta is the predominant isoform in striated muscles, whereas both isoforms (alpha and beta) are present in almost equal quantities in smooth muscles. Co-transfection and immunolabeling experiments indicate that both synemin isoforms are incorporated with desmin to form heteropolymeric IFs. Furthermore synemin and desmin are found aggregated together in certain pathological situations.

Elliptical versus circular erythrocyte marginal bands: isolation, shape conversion, and mechanical properties

Differentiation of nucleated erythrocytes involves transformation from spheroids to flattened discoids to mature flattened ellipsoids. The marginal band (MB) of microtubules is required for this process and continues to play a role in maintaining mature ellipsoidal cell shape. One hypothesis for MB function is that cell ellipticity is generated and maintained by asymmetric application of force across a flexible, circular MB frame by the membrane skeleton or other transverse elements. This is based on an earlier finding that isolated erythrocyte MBs are much more circular than MBs in situ. However, our present studies of salamander erythrocyte MBs isolated by a detergent-based method challenge this hypothesis. Most of these isolated MBs are initially elliptical, even though they lack transverse material (= E-MBs). They can be stabilized in that form for long periods and can be converted experimentally into the circular form (= C-MBs) by extended incubation in isolation medium or by treatment with elastase or subtilisin. We have tested an alternative hypothesis for generation and maintenance of ellipsoidal MBs, one based on intrinsic differential bending resistance and supported by construction of models. Using laser microsurgical transection to compare mechanical responses of isolated E-MBs and C-MBs, we have found their behavior to be quite different. Whereas C-MBs linearize, most E-MBs do not, instead retaining considerable curvature. These results are incompatible with the differential bending resistance hypothesis, which predicts both C-MB and E-MB linearization. However, they are consistent with a third model, in which material bound to the MB stabilizes it in the mature ellipsoidal form, and indicate that the mechanism for maintenance of MB ellipticity differs from that involved in its generation.

The lamprey (Lampetra fluviatilis) erythrocyte; morphology, ultrastructure, major plasma membrane proteins and phospholipids, and cytoskeletal organization

The aim of this study was to characterize the erythrocyte of the lamprey (Lampetra fluviatilis), a primitive vertebrate. The lamprey erythrocyte predominantly has a non-axisymmetric stomatocytelike shape. It has a nucleus and a haemoglobin-filled cytosol with a few organelles and vesicular structures. Surprisingly, there is no marginal band of microtubules. Sodium dodecylsulphate polyacrylamide gel electrophoresis followed by Coomassie blue staining of isolated plasma membranes revealed a single band at the level of the human spectrin doublet. Major bands also occurred at approximately 175 kDa and comigrating with human erythrocyte actin (approximately 45 kDa). The presence of spectrin, actin and vimentin was shown by immunoblotting. Band 3 protein, the anion exchanger in higher vertebrates, seemed to be highly deficient or lacking, as was also the case with ankyrin. Confocal laser scanning microscopy combined with immunocytochemical methods showed spectrin, actin and vimentin mainly to be localized around the nucleus, from where actin- and vimentin-strands extended out into the cytoplasm. Actin also seemed to be present at the plasma membrane. Phospholipid analyses of plasma membrane preparations showed the presence of the same four major phospholipid groups as in the human erythrocyte, although with higher and lower amounts of phosphatidylcholine and sphingomyelin, respectively. The low fluorescein isothiocyanate conjugated annexin V binding, as monitored by flow cytometry, indicated that phosphatidylserine is mainly confined to the inner membrane leaflet in the lamprey erythrocyte plasma membrane.

Vertical Pt-C replication for TEM, a revolution in imaging non-periodic macromolecules, biological gels and low-density polymer networks

Vertical replication for TEM is ideal for studying non-periodic specimens from 0.7 to 3 nm, a resolution mid-range difficult to attain by any other technique. This paper discusses the importance of vertical replication, its methods and hardware for high-resolution TEM. Evidence from diverse published research will demonstrate vertical replication's versatility in imaging the molecular level normally unattainable in freeze-dried polymers, polyethylene tribological wear on surfaces, low-density polymer networks or biological gels. Vertical platinum-carbon (Pt-C) replication minimizes the horizontal movement of Pt-C on a surface. Surface objects are symmetrically enlarged by a vertically deposited Pt-C film. To estimate real size in replicas, 16-25 particles or filaments need to be measured in calibrated transmission electron microscopy (TEM) images and reduced by a value less than the Pt-C film thickness measured with a quartz monitor. Continuous, vertically deposited Pt-C films are formed on mica at a deposition thickness of around 1.0 nm and on silver at a thickness of 0.4-0.5 nm. The distance between helical turns in poly(1-tetradecene sulfone) of 0.7 nm is the highest resolution achieved with vertical replication. Two polysulfones freeze-dried and vertically replicated on mica contained structures are predicted by indirect physical chemical methods to be present in solution. Polymer chains are fully Pt-C coated, with no uncoated gaps along chains. Some side-chains on the extended non-helical poly(1-tetradecene sulfone) are also detected. To estimate the real chain width, polymer chains measured in images are reduced by the Pt-C film thickness minus 0.5 nm. The polymer chain widths estimated from molecular models are in the same range of widths as those measured using the image size correction method. Also, it is possible to distinguish random coil proteins (chain width of around 0.5 nm) from an alpha-helix (chain diameter of about 1 nm) in vertically replicated samples on silver substrates. In the future, subnanometer resolutions below 0.7 nm should be possible. The resolution of vertical replication depends on the thickness of a continuous, amorphous Pt-C film. That thin, continuous 0.4-0.5 nm Pt-C films on silver substrates can be made suggests that a point-to-point resolution limit of around 0.28 nm in TEM may ultimately be approachable with replication.

Integration of intermediate filaments into cellular organelles

The intermediate filaments represent core components of the cytoskeleton and are known to interact with several membranous organelles. Classic examples of this are the attachment of keratin filaments to the desmosomes and the association of the lamin filament meshwork with the inner nuclear membrane. At this point, the molecular mechanisms by which the filaments link to membranes are not clearly understood. However, since a substantial body of information has been amassed, the time is now ripe for comparing notes and formulating working hypotheses. With this objective in mind, we review here pioneering studies on this subject, together with work that has appeared more recently in the literature.

Microtubule-associated protein 2 and the organization of cellular microtubules

Microtubule-associated proteins (MAPs) are prominent components of the neuronal cytoskeleton that can promote microtubule formation and whose expression is under strong developmental regulation. They are thought to be involved in organizing the structure of microtubule fascicles in axons and dendrites, although whether they form active cross-links between microtubules or serve as strut-like spacer elements has yet to be resolved. In the experiments reported here we explored their influence on microtubules by expressing them in non-neuronal cells using DNA transfection techniques. We confirm earlier reports that microtubule-associated proteins of the MAP2/tau class can induce bundling of microtubules. In addition we find that MAP2 causes the rearrangement of microtubules in the cytoplasm in a manner that is dependent on the length of the microtubule bundles. Short bundles are straight and run across the cytoplasm whereas long bundles form a marginal band-like array at the periphery. We suggest that the latter arrangement is produced when microtubule bundles that are too long to fit inside the diameter of the cell bend under the restraining influence of the cortical cytoskeleton. In confirmation of this, we show that when the cortical actin network is depolymerized by cytochalasin B the MAP2-containing microtubule bundles push out cylindrical extensions from the cell surface. These results suggest that the induction of stiff microtubules bundles by MAP2, coupled with a breach in the cortical actin network, can confer two of the properties characteristic of neuronal processes; their cylindrical form and the presence of fasciculated microtubules.

Ultrathin (1 nm) vertically shadowed platinum-carbon replicas for imaging individual molecules in freeze-etched biological DNA and material science metal and plastic specimens

Single molecule resolution in beam-sensitive, uncoated, noncrystalline materials has heretofore not been possible except in thin (less than or equal to 150 A) platinum-carbon (Pt-C) replicas, which are resistant to electron beam destruction. Previously, the granularity of metal film replicas limited their resolution to greater than or equal to 20 A. This paper demonstrates that Pt-C film granularity and resolution are a function of the method of replication and other controllable factors. Low-angle 20 degrees rotary, 45 degrees unidirectional, and vertical 9.7 +/- 1 A Pt-C films deposited on mica under the same conditions were compared. Vertical replication had a 5 A granularity, the highest resolution, and evenly coated the whole surface. A 45 degrees replication had a 9.5 A granularity, a slightly poorer resolution, and a discontinuous surface coating. The use of 20 degrees rotary replication proved to be unsuitable for high-resolution imaging, with 20-25 A granularity and resolution two to three times poorer. Vertical and 45 degrees Pt-C replicas can visualize the deep-etched DNA helix and the 13.3 A 3(2) helix of pectin in a gel. The DNA double helix, the complex structures of sol-gel glasses, Immobilon filters (polyvinylidene fluoride), a polymethacrylate plastic, the metal oxide surfaces of 440c stainless steel, and aluminum are illustrated. This high-resolution vertical Pt-C replica technique can image in the context of solutions, gels, or solids, single molecular chains 3-7 A wide, their associations, and their conformation. Included in the present article are first time descriptions for removing replicas from metals and plastics and for making high-magnification photographic prints of normal contrast using a reversal rephotographic process.

Immunogold-labeled microtubule crossbridges in platinum-carbon replicas of the marginal band of erythrocyte cytoskeletons

Cytoskeletons of erythrocytes from the toad Bufo marinus are composed of a surface-associated cytoskeleton that encapsulates the annular bundle of microtubules known as the marginal band (MB) and the centrally located nucleus. As seen by phase-contrast microscopy, the microtubules (MTs) of the MB remain tightly bundled after cell lysis without the need for added stabilizing factors. The integrity of this structure suggested that in addition to MTs other components were present in the MB and were responsible for its stability. Thin (less than 18 nm) platinum-carbon (Pt-C) replicas of freeze-dried cytoskeletons prepared by using a modified Balzers 300 system provided a novel method of sample preparation for a high-resolution study of the ultrastructure of the MB. Electron micrographs of replicas revealed that, the MTs of the MB displayed numerous filamentous projections which, when viewed in stereo, appear as side-arm connections between adjacent MTs. Immunofluorescence data show that monospecific antibodies to tubulin and to MT-associated protein 2 (MAP2) from brain each detect cross-reactive material in the MB. The combination of immunogold cytochemistry with Pt-C replication provided the increased resolution required to identify the individual structures recognized by antibodies to tubulin and MAP2. As expected, antitubulin labeled the MTs of the MB. However, anti-MAP2 antibodies were localized specifically to the cross-bridging filaments between adjacent MTs. Thus, a MAP2-like protein was identified in situ as the crossbridging filament that bundles MTs to form a stable MB.

Structure of low density heparan sulfate proteoglycan isolated from a mouse tumor basement membrane

A large heparan sulfate proteoglycan of low buoyant density (p = 1.32 to 1.40 g/cm3 in 6 M-guanidine.HCl) was extracted from a tumor basement membrane with denaturing solvents and purified by chromatography and CsCl gradient centrifugation. Chemical, immunological, physical and electron microscopical analyses have demonstrated a high degree of purity and have allowed us to propose a structural model for this proteoglycan. It is composed of an 80 nm long protein core formed from a single polypeptide chain (Mr about 500,000) with intrachain disulfide bonds. This core is folded into a row of six globular domains of variable size as shown by electron microscopy after rotary shadowing and negative staining. A multidomain structure was confirmed by protease digestion experiments that allowed the isolation of a single heparan sulfate-containing peptide segment representing less than 5% of the total mass of the protein core. Electron microscopy has visualized generally three heparan sulfate chains in each molecule close to each other at one pole of the protein core. The molecular mass and length (100 to 170 nm) of the heparan sulfate chains were found to vary consistently between different preparations. The mass per length ratio (350 nm-1) indicated an extended conformation for the heparan sulfate side-chains. These structural features are distinctly different from those of the high density proteoglycan, suggesting that both forms of basement membrane heparan sulfate proteoglycan are genetically distinct and not derived from a common precursor.

A protein factor from Bufo marinus erythrocytes cross-bridges microtubules in vitro

A microtubule cross-bridging factor was isolated from erythrocytes of the toad, Bufo marinus. Erythrocytes were lysed and their cytoskeletons disassembled by sonication and high salt extraction. The solubilized proteins were recovered and fractionated using Sephadex G-200 column chromatography. The protein fractions from the column were analysed by SDS-PAGE and pooled into three groups: high molecular weight (HMW) proteins that eluted from the column in the void volume and had a protein composition that included HMW polypeptides; intermediate MW proteins that were shown by SDS-PAGE to contain polypeptides smaller than 120,000 D; and low MW (LMW) proteins that contained polypeptides smaller than 70,000 D. Each group was further fractionated by phosphocellulose (PC) chromatography. The flow-through was recovered, and bound proteins were then eluted by a step gradient of salt (0.2, 0.4, 0.6 and 0.8 M KCl). To assay for microtubule cross-bridging activity, column fractions were incubated with taxol-stabilized microtubules, formed from PC-purified brain tubulin (PC microtubules). Negatively stained samples were examined in the electron microscope for the reconstitution of microtubule bundles with interconnecting cross-bridges. The HMW protein fraction from the G-200 column contained the cross-bridging factor. When these proteins were further fractionated by PC chromatography only the fraction eluted by 0.2 M KCl induced the formation of microtubule bundles with cross-bridges. No other protein fraction isolated by the described method revealed cross-bridges between microtubules in vitro.