Form and distribution of actin and myosin in non-muscle cells: a study using cultured chick embryo fibroblasts

How actin crosslinking and bundling proteins cooperate to generate an enhanced cell mechanical response

Actin-crosslinking proteins organize actin filaments into dynamic and complex subcellular scaffolds that orchestrate important mechanical functions, including cell motility and adhesion. Recent mutation studies have shown that individual crosslinking proteins often play seemingly non-essential roles, leading to the hypothesis that they have considerable redundancy in function. We report live-cell, in vitro, and theoretical studies testing the mechanical role of the two ubiquitous actin-crosslinking proteins, alpha-actinin and fascin, which co-localize to stress fibers and the basis of filopodia. Using live-cell particle tracking microrheology, we show that the addition of alpha-actinin and fascin elicits a cell mechanical response that is significantly greater than that originated by alpha-actinin or fascin alone. These live-cell measurements are supported by quantitative rheological measurements with reconstituted actin filament networks containing pure proteins that show that alpha-actinin and fascin can work in concert to generate enhanced cell stiffness. Computational simulations using finite element modeling qualitatively reproduce and explain the functional synergy of alpha-actinin and fascin. These findings highlight the cooperative activity of fascin and alpha-actinin and provide a strong rationale that an evolutionary advantage might be conferred by the cooperative action of multiple actin-crosslinking proteins with overlapping but non-identical biochemical properties. Thus the combination of structural proteins with similar function can provide the cell with unique properties that are required for biologically optimal responses.

Imaging subcellular structures of rat mammary carcinoma cells by scanning force microscopy

Scanning force microscopy (SFM) was used for imaging subcellular structures of cultured rat mammary carcinoma cells dried in air. Identification of cellular substructures was achieved by immunofluorescence and specific fluorescence probes. Cells grown attached to a glass support exhibited submicrometer thickness in the dried state. Inside the nuclear domain the nucleoli appeared as prominent conical protrusions. Membrane extensions, microspikes and microvilli were well preserved at the cell periphery after fixation in glutaraldehyde vapor and air-drying and were distinguishable either as isolated elements or intercellular communications. The plasma membrane and soluble proteins were selectively removed with nonionic detergent in a buffer system. The mitochondria were concentrated primarily in the perinuclear space and exhibited a well defined filamentous shape. Their identity was confirmed by specific fluorescence staining with rhodamine 123. In the membrane-free system achieved by dry-cleaving of the sample surface, the cytoskeletal network was resolved as a complex mesh of actin-containing fiber bundles interwoven with a filigree arrangement of thinner filaments. The smallest fibrous substructures revealed by SFM with the scanning tips used to date were approximately 8 to 10 nm in height and 80 nm in width.

Virological applications of the grid-cell-culture technique

Whole mounts of intact virus-infected cells have been used for several decades to examine virus-cell relationships and virus structure. The general concept of studying virus structure in association with the host cell has recently been expanded to reveal interactions between viruses and the cytoskeleton. The procedure permits utilization of immuno-gold protocols using both the transmission and scanning electron microscopes. The grid-cell-culture technique is reviewed to explain how it can be exploited to provide valuable information about virus structure and replication in both diagnostic and research laboratories. The use of the technique at the research level is discussed using bluetongue virus as a model. The procedure can provide basic structural information about intact virions and additional data on the intracellular location of viruses and virus-specific structures and about the mode of virus release from infected cells. Application of immunoelectron microscopy reveals information on the protein composition of not only released virus particles but also cell surface and cytoskeletal-associated viruses and virus-specific structures. Collectively, this simple and physically gentle technique has provided information which would otherwise be difficult to obtain.

Fine (2-5-nm) filaments: new types of cytoskeletal structures

Over the past 30 years filaments 2-5 nm in diameter have been found in a number of different types of eukaryotic cells. As a group, these fine filaments lack the similarity of composition and function that characterize the three major classes of cytoskeletal elements--microfilaments, microtubules, and intermediate filaments. Six different proteins that form fine filaments have been identified; proposed functions for these fibers range from cell motility to cytoarchitecture. Recent studies, however, have revealed filaments with similar compositions and/or functions in otherwise different cells, suggesting that the fine filaments may eventually fit into a limited number of subgroups.

Association of glycoconjugates with the cytoskeletal framework

The association of glycoconjugates with the cytoskeletal framework was examined in detergent-extracted cells. Sparse cultures of fibroblasts that assemble only minimal amounts of extracellular matrix were extracted under mild conditions with Triton X-100 which remove most of the lipids and soluble cellular proteins. The detergent-resistant framework retains lectin binding sites in the nucleus, in the perinuclear area occupied by the rough endoplasmic reticulum-Golgi system of the intact cell, and in a network throughout the cytoskeletal framework. Fluorescent-antibody staining with antibody against collagen type I and fibronectin reveals extensive perinuclear staining of the remnant rough endoplasmic reticulum-Golgi system. In contrast, only sporadic staining of the pericellular area is obtained with these antibodies, in sparse cultures of whole cells. Lectin binding sites were detected in the nucleus and are attributed to chromatin-associated glycoconjugates. They can be removed by DNase under conditions that preserve the cytoplasmic lectin binding sites and the nuclear matrix. The results suggest a high degree of integration of the membrane residues of the cytoplasmic elements and the nuclear matrix with the skeletal framework and indicate a possible role for the glycoconjugates in this structural integration.

Association of glycoconjugates with the cytoskeletal framework

The association of glycoconjugates with the cytoskeletal framework was examined in detergent-extracted cells. Sparse cultures of fibroblasts that assemble only minimal amounts of extracellular matrix were extracted under mild conditions with Triton X-100 which remove most of the lipids and soluble cellular proteins. The detergent-resistant framework retains lectin binding sites in the nucleus, in the perinuclear area occupied by the rough endoplasmic reticulum-Golgi system of the intact cell, and in a network throughout the cytoskeletal framework. Fluorescent-antibody staining with antibody against collagen type I and fibronectin reveals extensive perinuclear staining of the remnant rough endoplasmic reticulum-Golgi system. In contrast, only sporadic staining of the pericellular area is obtained with these antibodies, in sparse cultures of whole cells. Lectin binding sites were detected in the nucleus and are attributed to chromatin-associated glycoconjugates. They can be removed by DNase under conditions that preserve the cytoplasmic lectin binding sites and the nuclear matrix. The results suggest a high degree of integration of the membrane residues of the cytoplasmic elements and the nuclear matrix with the skeletal framework and indicate a possible role for the glycoconjugates in this structural integration.

A yellow crescent cytoskeletal domain in ascidian eggs and its role in early development

In this investigation, Triton X-100 extraction was utilized to examine the cytoskeleton of ascidian eggs and embryos. The cytoskeleton contained little carbohydrate or lipid and only about 20-25% of the total cellular protein and RNA. It was enriched in polypeptides of molecular weight (Mr)54, 48, and 43 x 10(3) Mr polypeptide was identified as actin based on its Mr, isoelectric point, and affinity for DNase I. Electron microscopy of the detergent-extracted eggs showed that they contained cytoskeletal domains corresponding to colored cytoplasmic regions of specific morphogenetic fate in the living egg. A yellow crescent cytoskeletal domain in the myoplasm was examined and shown to consist of a plasma membrane lamina (PML) and a deeper lattice of filaments which appeared to connect the yellow crescent pigment granules to the PML. The PML probably consists of integral membrane proteins stabilized by an underlying network of actin filaments since NBD-phallacidin stained this area of the egg cortex and the PML was extracted from the cytoskeleton by DNase I treatment. The yellow crescent cytoskeletal domain was found throughout the cortex of the unfertilized egg. During ooplasmic segregation it progressively receded into the vegetal hemisphere and was subsequently partitioned to the presumptive muscle and mesenchyme cells of the 32-cell embryo. It is suggested that contraction of the actin network in the yellow crescent cytoskeletal domain is the motive force for ooplasmic segregation. This structure may also serve as a framework for the positioning of morphogenetic determinants involved in muscle cell development.

Many cytoskeletal proteins associate with the hela cytoskeleton during translation in vitro

Observations that cytoskeletal proteins assemble in vivo close to the time and site of synthesis have been confirmed and extended by an in vitro translation system. HeLa cytoskeletons prepared with Triton in a translation-extraction buffer without reticulocyte or wheat germ lysate efficiently incorporate 35S-methionine into polypeptides, and are stable during this translation. Cytoskeletal proteins translated in this way associate with the HeLa cytoskeleton independent of the concentration of soluble proteins. These associations are puromycin-resistant before the proteins are complete; the protein associations made in vitro show only minor differences from those made in vivo. The protein associations are not simply a consequence of protein solubility in the buffers used, as the associations require initiation in vivo. These results indicate that many cytoskeletal proteins associate with the cytoskeleton during translation.

Developmental reorganization of the skeletal framework and its surface lamina in fusing muscle cells

The skeletal framework of cells, composed of internal structural fibers, microtrabeculae, and the surface lamina, is revealed with great clarity after extraction with detergent. When muscle cells fuse to form a multinucleated myotube, their skeletal framework reorganizes extensively. When myoblasts prepare to fuse, the previously continuous surface lamina develops numerous lacunae unique to this stage. The retention of iodinated surface proteins suggests that the lacunae are not formed by the extraction of lamina proteins. The lacunae appear to correspond to extensive patches that do not bind concanavalin A and are probably regions of lipid bilayer devoid of glycoproteins. The lacunae appear to be related to fusion and disappear rapidly after the multinucleated myotube is formed. When muscle cells fuse, their internal structural networks must interconnect to form the framework of the myotube. Transmission electron microscopy of skeletal framework whole mounts shows that proliferating myoblasts have well developed and highly interconnected internal networks. Immediately before fusion, these networks are extensively reorganized and destabilized. After fusion, a stable, extensively cross-linked internal structure is reformed, but with a morphology characteristic of the myotube. Muscle cells therefore undergo extensive reorganization both on the surface and internally at the time of fusion.

Microfilaments interacting with heavy meromyosin and deoxyribonuclease I in cells of the ovarian follicle of a lizard

Two types of filaments (microfilaments 4--6 nm in diameter, and intermediate filaments 7--10 nm in diameter) are common in the surface epithelial cells and theca fibroblasts of vitellogenic ovarian follicles of the lizard Anolis carolinensis. Heavy meromyosin (HMM), which forms complexes with actin filaments, interacts only with the microfilaments of theca fibroblasts. After myosin extraction of follicles no filaments disappeared, but when this treatment was followed by incubation with deoxyribonuclease I (DNA-ase I), which depolymerizes F-actin to G-actin, microfilaments disappeared from the theca fibroblasts. It is concluded that microfilaments in theca fibroblasts are actin-like and may contract to provide the mechanism of expulsion for the oocyte during ovulation. The intermediate filaments of the surface epithelial cells and theca fibroblasts may serve as a skeletal system for the large (up to 8 mm in diameter) vitellogenic follicle.

Mechanism of retraction of the trailing edge during fibroblast movement

Retraction of the taut, trailing portion of a moving chick heart fibroblast in vitro is an abrupt dynamic process. Upon retraction, the fibroblast tail always ruptures, leaving a small amount of itself attached to the substratum by focal contacts. Time-lapse cinemicrography shows that retraction produces a sudden, massive movement of both surface and cytoplasmic material toward a cluster of focal contacts near the main body of the cell. The appearance of folds on the upper cell surface at this time and the absence of endocytotic vesicles are consistent with this forward movement. Retraction of the trailing edge, either occurring naturally or produced artificially with a microneedle, consists of an initial fast component followed and overlapped by a slow component. Upon artificial detachment in the presence of iodoacetate, dinitrophenol, and sodium fluoride, and at 4 degrees C, the slow component is strongly inhibited and the fast one only slightly inhibited. Moreover of the bundles of microfilaments oriented parallel to the long axis of the tail seen in TEM. Most of the birefringence is lost during the fast phase and the rest during the slow phase of retraction. Concurrently, the bundles of microfilaments disappear during the fast phase of retraction and are replaced by a microfilament meshwork. All of these results are consistent with the hypothesis that the initial fast component of retraction is a passive elastic recoil, associated with the oriented bundles of microfilaments, and that the slow component of retraction is an active contraction, associated with a meshwork of microfilaments.

Messenger RNA is translated when associated with the cytoskeletal framework in normal and VSV-infected HeLa cells

When the cytoskeletal framework is prepared from suspension-grown HeLa by extraction with nonionic detergent, all the polyribosomes are associated with the framework while 80% of tRNA and the major portion of monoribosomes as well as 75% of the cell proteins are found in the soluble fraction. The mRNA of polyribosomes is bound to the cytoskeleton and these molecules remain attached even after polyribosomes are disassembled in vivo prior to extraction. Although all actively translating message molecules are attached to the framework, about one quarter of the poly(A)+ mRNA is free of the framework. The binding of message to the skeleton may be obligatory for translation. Upon infection with VSV, all the viral polyribosomes but not all the viral messages of the infected cell are associated with the cytoskeletal framework. Pulse-chase labeling shows that VSV messages initially associate with the framework and then later detach and cease translation. The mRNA for the viral glycoprotein (G), known to translate only on ribosomes bound to endoplasmic reticulum, is also retained by the detergent-extracted structure. It appears that the protein substructure of the endoplasmic reticulum which binds polyribosomes is a component of the cytoskeletal framework.

The spatial distribution of polyribosomes in 3T3 cells and the associated assembly of proteins into the skeletal framework

Acridine fluorescence reveals polyribosomes in fibroblasts and Triton-extracted skeletal frameworks; simultaneous phase-contrast images show cellular structure. Polyribosomes appear near nuclei of both intact fibroblasts and skeletal frameworks. Simultaneous autoradiography of cells so examined locates radioactive proteins. After synthesis, most proteins diffuse rapidly through the cytoplasm; intact cells autoradiographed afer a 35S pulse show grains throughout. In sharp contrast, extraction with Triton leaves only radioactive skeletal proteins, which, although released from ribosomes, are near polyribosomes after a pulse. After a chase, skeletal-associated radioactivity is found throughout the framework structure. However, skeletal proteins migrate only if protein synthesis continues. Emetine administered following a pulse block protein migration; skeletal framework radioactivity remains near polyribosomes. This also indicates limited exchange between skeletal framework and soluble cytoplasmic proteins. The fact that proteins insert themselves into the skeletal framework at or near their synthesis site, with limited subsequent exchange, appears to contradict current view of protein self-assembly.

Electron microscopic visualization of the filamentous reticulum in whole cultured presumptive chick myoblasts

This present study describes an experimental approach whereby subcellular 3-dimensional filamentous structures present within whole cells can be examined, using a conventional transmission electron microscope. This procedure uses cells which have been cultured on carbon-coated titanium grids, and treated with Triton X-100 to extract the soluble cytoplasm. Subsequent fixation and critical-point drying allows filamentous proteins to be easily visualized, due to the increase in contrast produced by removal of the ground cytoplasm. The high resolution obtainable in these preparations permitted an initial classification and description of the filamentous reticulum within cultured presumptive myoblasts. This reticulum is a continuum of filaments and cables, all elements of which appear to be interconnected. These morphological findings were then correlated with the biochemical identification of detergent-insoluble proteins, of which only actin, myosin, and, perhaps, intermediate filament and LETS protein are the major elements.

Three-dimensional view of the chromatin in freeze-fractured chicken erythrocyte nuclei

The freeze-fracture thaw-fix (FfTF) technique described in earlier papers is applied in the present work to more detailed study of the chicken erythrocyte, by transmission replicas and high resolution scanning electron microscopy (3 nm scan beam size). The three-dimensional structure of the chromatin, and possibly the non-histone protein matrix, of fractured nuclei is to a large extent retained in this method of preparation and seen in stereomicrographs. In these micrographs the helical sub-structure of the 25 nm chromatin strands can be seen at about the same resolution as that of previously published micrographs in which extracted chromatin is viewed by negative contrast or after metal shadowing. The useful resolution of the secondary electron micrographs, for a suitably mounted specimen, is shown to be as good as that of transmission micrographs of platinum-carbon replicas of the same material.

The cytoskeletal framework and poliovirus metabolism

The cytoskeletal framework prepared by detergent lysis of suspension-grown HeLa cells is compared to the structure obtained from poliovirus-infected cells. This framework, which retains major features of cell morphology and carries the cellular polyribosomes as well as the major structural filaments, is profoundly reorganized following virus infection. This reorganization underlies, at least in part, the morphological changes termed the "cytoplasmic effect." These cytoskeletal changes appear related to the involvement of the framework with viral-specific metabolism. Extensive cytoskeleton alterations occur even when guanidine inhibits viral replication, and thus result from small amounts of early viral products. The normally spheroidal nucleus deforms, allowing a modified region of the cytoplasm to occupy a central position in the cell, and many membrane-enclosed vesicles peculiar to the infected cell are elaborated here. The skeleton preparation reveals that this region contains intermediate filaments arranged in a pattern unique to infected cells. Further changes occur when viral replication is permitted. The central region filaments become coated with darkly staining material which may be viral RNA. Numerous small particles appear on the filaments which resemble partially assembled virions. Mature virions, however, have no affinity for the cytoskeleton and appear to be free in the cytoplasm. Host cell messenger RNA, normally attached to the skeletal framework, is released in infected cells and is replaced by the viral-specific polyribosomes. The trabecular network which carries polyribosomes appears to be rearranged; the viral polyribosomes are located principally at the cell periphery and are excluded from the central region. The viral replication complex with its double-stranded RNA is also attached to the skeletal framework and may comprise the dark staining material coating the filaments of the central cell region.

Spreading of vascular endothelial cells in culture: spatial reorganization of cytoplasmic fibers and organelles

The three-dimensional organization and fine structure of cytoplasmic components within whole non-embedded bovine aortic endothelial cells were examined during their attachment and spreading in tissue culture. Cells were cultured directly on Formvar-coated gold grids, fixed in glutaraldehyde and osmium tetroxide, critical point dried and examined by transmission electron microscopy (TEM) using stereoscopic methods, and by scanning electron microscopy (SEM). Reorganization of cytoplasmic structures during cell spreading occurred in four sequential stages: (1) spreading of the plasma membrane and unstructured cytoplasmic matrix; (2) spreading of cytoplasmic fiber systems (microtubules, microfilament bundles and microtrabecular system); (3) alignment of microfilament bundles and formation of radial tracts of microtubules; and (4) centripetal movement of organelles along radial tracts. These stages observed by TEM correlated with progressive degrees of cell flattening as visualized by SEM. These studies demonstrate that a characteristic reorganization of intracellular fiber systems and organelles accompanies the spreading of endothelial cells in culture.