Evidence for the participation of actin microfilaments and bristle coats in the internalization of gap junction membrane

Thin sections of rabbit granulosa, human SW-13 adrenal cortical adenocarcinoma, and mouse B-16 melanoma cells revealed an apparent single-layered basket of 4- to 7-nm filaments surrounding cytoplasmic gap junction vesicles. This interpretation was based upon apparent longitudinal, cross, and en face sections of structures surrounding the vesicle profiles in tissue treated with tannic acid-glutaraldehyde. In granulosa cells incubated with the S-1 fragment of heavy meromyosin, arrowhead-decorated filaments were observed at the periphery of the gap junction vesicles, suggesting that these filaments contained actin. In addition, we found that small gap junctional blebs and vesicles at the cell surface were coated with short electron-dense bristles similar in appearance to the cloathrin-containing coat of coated vesicles of nonjunctional membrane. The role of these and other cytoskeletal elements in the possible endocytosis of gap junction membrane is discussed.     

Fine structure of the nephridial muscle layer cells of Phascolosoma granulatum (Sipuncula)

The nephridial muscle layer of Phascolosoma granulatum consists of a network of longitudinal and circular cells separated by connective tissue matrix. The muscle fibers are densely packed with thick and thin myofilaments, among which are scattered cytoplasmic dense bodies. The nucleus and noncontractile cytoplasmic organelles occupy a lateral projection from the contractile portion of the fiber. Cytoplasmic dense bodies are the result of a clustering of an indeterminate number of the thin actin filaments that fill the cytoplasm between thick filaments. Attached to the cytoplasmic face of the cell membrane are membrane-associated electron-dense plaques. These sites are linked to the contractile myofilaments by narrow filamentous bridges. Extracellular narrow filaments extend from these plaques to collagen fibers of the connective tissue matrix. Differences in length of the dense plaques may be related to differences in thick myofilament diameter in three types of muscle fiber, types A, B and C, statistically distinguished by mean fiber size differences. The plaques may serve as connecting links for the transmission of tension from contractile units to the connective tissue of the muscle layer. © 1993 Wiley-Liss, Inc.     

The visualization of actin filament polarity in thin sections. Evidence for the uniform polarity of membrane-associated filaments

We have developed an improved method for visualizing actin filament polarity in thin sections. Myosin subfragment-1 (S-1)-decorated actin filaments display a dramatically enhanced arrowhead configuration when fixed in a medium which contains 0.2 % tannic acid. With the exception of brush borders from intestinal epithelial cells, the arrowhead periodicity of decorated filaments in a variety of nonmuscle cells is similar to that in isolated myofibrils. The periodicity of decorated filaments in brush borders is significantly smaller. Actin filaments which attach to membranes display a clear, uniform polarity, with the S-1 arrowheads pointing away from the plasma membrane, while those which comprise the stress fibers of myoblasts and CHO cells have antiparallel polarities. These observations are consistent with a sliding filament mechanism of cell motility.     

Electron microscopic localization of cytoplasmic myosin with ferritin- labeled antibodies

We localized myosin in vertebrate nonmuscle cells by electron microscopy using purified antibodies coupled with ferritin. Native and formaldehyde-fixed filaments of purified platelet myosin filaments each consisting of approximately 30 myosin molecules bound an equivalent number of ferritin-antimyosin conjugates. In preparations of crude platelet actomyosin, the ferritin-antimyosin bound exclusively to similar short, 10-15 nm wide filaments. In both cases, binding of the ferritin-antimyosin to the myosin filaments was blocked by preincubation with unlabeled antimyosin. With indirect fluorescent antibody staining at the light microscope level, we found that the ferritin-antimyosin and unlabeled antimyosin stained HeLa cells identically, with the antibodies concentrated in 0.5-microns spots along stress fibers. By electron microscopy, we found that the concentration of ferritin-antimyosin in the dense regions of stress fibers was five to six times that in the intervening less dense regions, 20 times that in the cytoplasmic matrix, and 100 times that in the nucleus. These concentration differences may account for the light microscope antibody staining pattern of spread interphase cells. Some, but certainly not all, of the ferritin-antimyosin was associated with 10-15-nm filaments. In mouse intestinal epithelial cells, ferritin- antimyosin was located almost exclusively in the terminal web. In isolated brush borders exposed to 5 mM MgCl2, ferritin-antimyosin was also concentrated in the terminal web associated with 10-15-nm filaments.     

Immunocytochemical studies of quaking mice support a role for the myelin-associated glycoprotein in forming and maintaining the periaxonal space and periaxonal cytoplasmic collar of myelinating Schwann cells

The myelin-associated glycoprotein (MAG) is an integral membrane glycoprotein that is located in the periaxonal membrane of myelin-forming Schwann cells. On the basis of this localization, it has been hypothesized that MAG plays a structural role in (a) forming and maintaining contact between myelinating Schwann cells and the axon (the 12-14-nm periaxonal space) and (b) maintaining the Schwann cell periaxonal cytoplasmic collar of myelinated fibers. To test this hypothesis, we have determined the immunocytochemical localization of MAG in the L4 ventral roots from 11-mo-old quaking mice. These roots display various stages in the association of remyelinating Schwann cells with axons, and abnormalities including loss of the Schwann cell periaxonal cytoplasmic collar and dilation of the periaxonal space of myelinated fibers. Therefore, this mutant provides distinct opportunities to observe the relationships between MAG and (a) the formation of the periaxonal space during remyelination and (b) the maintenance of the periaxonal space and Schwann cell periaxonal cytoplasmic collar in myelinated fibers. During association of remyelinating Schwann cells and axons, MAG was detected in Schwann cell adaxonal membranes that apposed the axolemma by 12-14 nm. Schwann cell plasma membranes separated from the axolemma by distances greater than 12-14 nm did not react with MAG antiserum. MAG was present in adaxonal Schwann cell membranes that apposed the axolemma by 12-14 nm but only partially surrounded the axon and, therefore, may be actively involved in the ensheathment of axons by remyelinating Schwann cells. To test the dual role of MAG in maintaining the periaxonal space and Schwann cell periaxonal cytoplasmic collar of myelinated fibers, we determined the immunocytochemical localization of MAG in myelinated quaking fibers that displayed pathological alterations of these structures. Where Schwann cell periaxonal membranes were not stained by MAG antiserum, the cytoplasmic side of the periaxonal membrane was "fused" with the cytoplasmic side of the inner compact myelin lamella and formed a major dense line. This loss of MAG and the Schwann cell periaxonal cytoplasmic collar usually resulted in enlargement of the 12-14-nm periaxonal space and ruffling of the apposing axolemma. In myelinated fibers, there was a strict correlation between the presence of MAG in the Schwann cell periaxonal membrane and (a) maintenance of the 12-14-nm periaxonal space, and (b) presence of the Schwann cell periaxonal cytoplasmic collar.(ABSTRACT TRUNCATED AT 400 WORDS)     

Lumenal plasma membrane of the urinary bladder. II. Isolation and structure of membrane components

A technique has been devised for isolation of lumenal plasma membranes from transitional epithelial cells lining the urinary bladder in rabbits and for subsequent separation of particle-bearing plaque regions from particle-free areas of the membranes. The success of the procedures employed and their effects on the isolates were assessed by electron microscopy of conventional plastic sections, negatively stained preparations, and freeze-etch replicas. When bladders are distended with a solution of 0.01 M thioglycolic acid, which reduces sulfhydryl bridges, cytoplasmic filaments are disrupted, and large segments of the lumenal membranes rupture and float free into the lumen. A centrifugation procedure was developed for isolating a fraction enriched with the large fragments. A comparison of membranes isolated in the presence of thioglycolate with those isolated from epithelial cells homogenized in sucrose medium indicates that thioglycolate has little effect on their fine structure except for the removal of filaments which are normally associated with their cytoplasmic surface. The curved plaques of hexagonally arrayed particles and the particle-free interplaque regions, both characteristic of membranes before exposure to thioglycolate, are well preserved. Subsequent treatment of thioglycolate-isolated lumenal membranes with 1% sodium desoxycholate (DOC) severs many of the interplaque regions, releasing individual plaques in which the particles are more clearly visible than before exposure to desoxycholate. Presumably, DOC acts by disrupting the hydrophobic bonds within the membrane; therefore, this type of cohesive force probably is a major factor maintaining the structural integrity of interplaque regions. This conclusion is consistent with the observation that interplaque regions undergo freeze-cleaving like simple bilayers with a plane of hydrophobic bonding.     

Banding and polarity of actin filaments in interphase and cleaving cells

Heavy meromyosin (HMM) decoration of actin filaments was used to detect the polarity of microfilaments in interphase and cleaving rat kangaroo (PtK2) cells. Ethanol at -20 degrees C was used to make the cells permeable to HMM followed by tannic acid-glutaraldehyde fixation for electron microscopy. Uniform polarity of actin filaments was observed at cell junctions and central attachment plaques with the HMM arrowheads always pointing away from the junction or plaque. Stress fibers were banded in appearance with their component microfilaments exhibiting both parallel and antiparallel orientation with respect to one another. Identical banding of microfilament bundles was also seen in cleavage furrows with the same variation in filament polarity as found in stress fibers. Similarly banded fibers were not seen outside the cleavage furrow in mitotic cells. By the time that a mid-body was present, the actin filaments in the cleavage furrow were no longer in banded fibers. The alternating dark and light bands of both the stress fibers and cleavage furrow fibers are approximately equal in length, each measuring approximately 0.16 micrometer. Actin filaments were present in both bands, and individual decorated filaments could sometimes be traced through four band lengths. Undecorated filaments, 10 nm in diameter, could often be seen within the light bands. A model is proposed to explain the arrangement of filaments in stress fibers and cleavage furrows based on the striations observed with tannic acid and the polarity of the actin filaments.     

Tannic acid effect on membrane of cell surface origin in guinea pig megakaryocytes and platelets.

Plasma membranes in isolated guinea pig megakaryocytes and washed platelets are poorly stained with the usual methods used to outline cell membranes. The addition of tannic acid and calcium to the initial fixative is useful to enhance electron density of all surface-derived membrane systems in these cells. The method described here shows that the increased electron denisty of membrane after fixation in the presence of tannic acid occurs both at the cell surface and along the invaginated membrane systems.     

Acetylcholine receptor clusters of rat myotubes have at least three domains with distinctive cytoskeletal and membranous components

Cultured rat myotubes develop high concentrations of acetylcholine receptors (AChR) in specialized areas of attachment to their substrate. We examined the ultrastructure of identified AChR clusters by quick-freeze, deep-etch, rotary replication or by thin sectioning of whole myotubes fixed in the presence of saponin and tannic acid to preserve the cytoskeleton. Our findings show that AChR clusters are composed of at least three distinct domains, differing in their cytoskeletal, intramembrane, and external components. At contact domains, the myotube's ventral membrane lacked AChR and lay within 10-15 nm of the substrate; electron-dense strands connected the two. The overlying cytoplasm contained bundles of parallel microfilaments passing above and through an irregular network of globular material, resembling the relationship of microfilament bundles to focal contacts already described in fibroblasts. Coated-membrane domains lay between the microfilament bundles and were overlain by cytoplasmic plaques of a regular network of polygons having associated coated pits. These plaques closely resembled the network of polymerized clathrin described in fibroblasts and macrophages. Coated membrane also lacked AChR and adhered to the substrate by electron-dense strands, but did not anchor microfilament bundles. The cytoplasm overlying AChR domains contained a complex network composed of at least two layers. The layer closest to the membrane consisted of protrusions from the cytoplasmic surface, some connected by fine filaments less than 5 nm in diameter. An overlying layer contained larger diameter filaments, some forming an anastomotic network reminiscent of the cortical cytoskeleton of erythrocytes. Longer filaments inserting into this network appeared identical to members of nearby microfilament bundles. The morphology of AChR domains supports the idea that AChR are immobilized by a network containing actin and spectrin.     

Fine structure of the cell envelope layers of Flexibacter polymorphus.

Electron microscopy of the filamentous gliding marine bacterium Flexibacter polymorphus demonstrated that the cell envelope consists of an electron-dense intermediate layer located between two unit-type membranes: an outer membrane, presumably of lipopolysaccharide, and an inner cytoplasmic membrane. Separation of living filaments into single cells by lysozyme suggests that a peptidoglycan moiety, possibly corresponding to the intermediate layer, might be situated between the two membranes. Cell division proceeds by invagination of the cytoplasmic membrane and intermediate layer forming a transverse septum. Cells generally fail to separate after the division process, so that a common outer membrane encloses all of the cells in a single filament. There is a continuous layer of macromolecular cup-shaped elements ('goblets') attached to the outermost surface of the lipopolysaccharide membrane. Tangential thin sections, as well as negatively stained preparations of envelope fragments (produced by sonication of autolyzed cells), showed that the goblets are arranged in a close-packed hexagonal array. The presence of electron-dense structures located between the outer and inner membranes, and exhibiting the same periodicity as the goblets, suggests that some part of the goblets penetrates the outer membrane and extends across the periplasmic space to the dense intermediate layer or cytoplasmic membrane. Spontaneous autolysis in aging cultures is accompanied by the formation and release into the culture medium of large numbers of outer membrane vesicles coated with globlets. A tentative reconstruction of the envelope of F. polymorphus, based on the fine-structural data, is presented.     

Ultrastructural demonstration of exocytosis in intact and saponin-permeabilized cultured bovine chromaffin cells

Exocytosis is the release of intracellular vesicular contents directly to the cell exterior after fusion of the vesicular and plasma membranes. It is generally accepted as the process by which transmitters and hormones are released from neurons and neurosecretory cells. There is overwhelming biochemical evidence that exocytosis is the mechanism by which catecholamines are released from adrenal chromaffin cells. With the exception of the hamster, however, there is little ultrastructural evidence to support such a mechanism. We have used a modified in vitro tannic-acid method to visualize exocytosis by transmission electron microscopy in intact and saponin-permeabilized bovine chromaffin cells. When cells are exposed to tannic-acid-containing medium, the content of vesicles involved in exocytosis is coagulated in situ as the vesicle opens to the exterior. Numerous exocytotic profiles were observed. The exposed vesicle contents appeared more granular than those of vesicles in the cell interior. Tannic acid also made the plasma membrane more distinct. Small holes were apparent in the plasma membrane of saponin-treated cells, with little disruption of underlying cytoplasmic structure. Furthermore, when these cells were stimulated with calcium, exocytosis was evident only at regions of intact plasma membrane, not at the holes. Parallel measurements of secretion showed no secretion in the presence of tannic acid. Pretreatment with tannic acid prevented subsequent secretion by intact cells and markedly reduced that of permeabilized cells, indicating a probable change in the nature of the plasma membrane.(ABSTRACT TRUNCATED AT 250 WORDS)     

Human epithelial cell intermediate filaments: isolation, purification, and characterization

Intermediate filaments (IF) isolated from human epithelial cells (HeLa) can be disassembled in 8 M urea and reassembled in phosphate-buffered solutions containing greater than 0.1 mg/ml IF protein. Eight proteins were associated with HeLa IF after several disassembly-reassembly cycles as determined by sodium dodecyl sulfate gel electrophoresis (SDS PAGE). A rabbit antiserum directed against HeLa IF contained antibodies to most of these proteins. The immunofluorescence pattern that was seen in HeLa cells with this antiserum is complex. It consisted of a juxtanuclear accumulation of IF protein and a weblike array of cytoplasmic fibers extending to the cell border. Following preadsorption with individual HeLa IF proteins, the immunofluorescence pattern in HeLa cells was altered to suggest the presence of at least two distinct IF networks. The amino acid composition and alpha-helix content (approximately 38%) of HeLa IF proteins was similar to the values obtained for other IF proteins. One-dimensional peptide maps show extensive homology between the major HeLa IF protein of 55,000-mol- wt and a similar 55,000-mol-wt protein obtained from hamster fibroblasts (BHK-21). HeLa 55,000-mol-wt homopolymer IF assembled under conditions similar to those required for BHK-21 55,000-mol-wt homopolymers. Several other proteins present in HeLa IF preparations may be keratin-like structural proteins. The results obtained in these studies indicate that the major HeLa IF protein is the same major IF structural protein found in fibroblasts. Ultrastructural studies of HeLa cells revealed two distinct IF organizational stages including bundles and loose arrays. In addition, in vitro reconstituted HeLa IF also exhibited these two organizational states.     

The probable role of phosphatidyl cholines in the tannic acid enhancement of cytomembrane electron contrast

Unsaturated natural and synthetic phosphatidyl cholines (PCs), when treated with tannic acid and OsO4, demonstrated a substantial increase in contrast as compared to PC treated only with OsO4. This was not observed when phosphatidyl ethanolamine (PEA) was similarly exposed to tannic acid. The increased electron density observed in the lamellar organization of the PC phospholipids was limited to the hydrophilic layers corresponding to the polar regions of the phospholipid molecules. The repeating periods of lamellae were identical in PC, treated with both tannic acid and OsO4, and when treated only with OsO4. In each case, this approximated 45 A. The enhancement of membrane contrast by tannic acid in the presence of OsO4 is interpreted as being at least in part due to its multivalent capacity, binding to reactive sites on choline, as well as with OsO4.     

Specific attachment of desmin filaments to desmosomal plaques in cardiac myocytes

Intercellular junctions which are similar in ultrastructure and protein composition to typical desmosomes have so far only been found in epithelial cells and in heart tissue, specifically in the intercalated disks of cardiac myocytes and at cell boundaries between Purkinje fiber cells. In epithelial cells the cytoplasmic side of desmosomes, the 'desmosomal plaque', represents a specific attachment structure for the anchorage of intermediate filaments (IF) of the cytokeratin type. Cardiac myocytes do not contain cytokeratin filaments. In primary cultures of rat cardiac myocytes, we have examined by immunofluorescence and electron microscopy, using single and double label techniques, whether other types of IF are attached to the desmosomal plaques of the heart. Antibodies to desmoplakin, the major protein of the desmosomal plaque, have been used to label specifically the desmosomal plaques. It is shown that the desmoplakin-containing structures are often associated with IF stained by antibodies to desmin, i.e., the characteristic type of IF present in these cells. Like cytokeratin filaments in epithelial cells, desmin filaments attach laterally to the desmosomal plaque. They also remain attached to these plaques after endocytotic internalization of desmosomal domains by treatment of the cells with EGTA. These desmin filaments do not appear to attach to junctions of the fascia adherens type and to nexuses (gap junctions). These observations show that anchorage at desmosomal plaques is not restricted to IF of the cytokeratin type and that IF composed of either cytokeratin or desmin, specifically attach, in a lateral fashion, to desmoplakin-containing regions of the plasma membrane. We conclude that special domains exist in these two IF proteins that are involved in binding to the desmosomal plaque.     

Alzheimer's disease: coated vesicles, coated pits and the amyloid-related cell

The amyloid-related cell (ARC) of the neuritic plaques of Alzheimer's disease revealed numerous cytoplasmic projections surrounding extracellular amyloid material. It is proposed that ARC-coated vesicles fuse with the cell membrane, forming coated pits, which may empty their secretory material into the extracellular space where polymerization of amyloid filaments could occur.     

Urothelial plaque formation in post-Golgi compartments

Urothelial plaques are specialized membrane domains in urothelial superficial (umbrella) cells, composed of highly ordered uroplakin particles. We investigated membrane compartments involved in the formation of urothelial plaques in mouse umbrella cells. The Golgi apparatus did not contain uroplakins organized into plaques. In the post-Golgi region, three distinct membrane compartments containing uroplakins were characterized: i) Small rounded vesicles, located close to the Golgi apparatus, were labelled weakly with anti-uroplakin antibodies and they possessed no plaques; we termed them "uroplakin-positive transporting vesicles" (UPTVs). ii) Spherical-to-flattened vesicles, termed "immature fusiform vesicles" (iFVs), were uroplakin-positive in their central regions and contained small urothelial plaques. iii) Flattened "mature fusiform vesicles" (mFVs) contained large plaques, which were densely labelled with anti-uroplakin antibodies. Endoytotic marker horseradish peroxidase was not found in these post-Golgi compartments. We propose a detailed model of de novo urothelial plaque formation in post-Golgi compartments: UPTVs carrying individual 16-nm particles detach from the Golgi apparatus and subsequently fuse into iFV. Concentration of 16-nm particles into plaques and removal of uroplakin-negative membranes takes place in iFVs. With additional fusions and buddings, iFVs mature into mFVs, each carrying two urothelial plaques toward the apical surface of the umbrella cell.     

Comparison of purified anti-actin and fluorescent-heavy meromyosin staining patterns in dividing cells

We purified actin antibodies by affinity chromatography from the serum of rabbits immunized with glutaraldehyde-fixed chicken gizzard actin filaments and used this anti-actin to localize actin in myofibrils and fixed cultured cells at each stage of the cell cycle. By double immunodiffusion the anti-actin reacted with both smooth and skeletal muscle actin. Several blocking and absorption experiments demonstrated that the antibodies also bound specifically to actin in nonmuscle cells. The same structures stained using either the direct or the indirect fluorescent antibody technique; and, while the indirect method was more sensitive, the direct method was superior because there was no detectable nonspecific staining. As expected, anti-actin stained the I-band of myofibrils. It also stained stress fibers and membrane ruffles in HeLa cells. Some PtK-2 cells have straight stress fibers which stained with anti-actin, but in confluent cultures all PtK-2 cells have, instead, sinuous phase-dense fibers which stained with antibody. At prophase the whole cytoplasm stained uniformly with anti-actin. During metaphase and anaphase, anti-actin staining was concentrated diffusely in the mitotic spindle. In contrast, fluorescent heavy meromyosin stained discrete fine spindle fibers in these fixed cells. During cytokinesis, anti-actin stained the whole cytoplasm uniformly and was not concentrated in the cleavage furrow.     

What moves chromosomes, microtubules or microfilaments?

An investigation of the spindle apparatus of crane-fly (Nephrotoma suturalis) spermatocytes has been undertaken using methods that permit combined light and electron microscopy of selected cells. At the ultrastructural level, spindles contain microtubules in a granular matrix. Microtubules have been classified as kinetochore microtubules (which connect to kinetochores of chromosomes) and non-kinetochore microtubules (not attached to kinetochores). Kinetochore microtubules are distributed in densely packed bundles, which are the birefringent chromosomal fibers seen in living cells. Actin filaments were not observed in spindles of unglycerinated cells or in cells fixed in glutaraldehyde containing tannic acid, which negatively stains F-actin in situ and thus can be used to aid the localization of actin filaments in non-muscle cells. The absence of actin filaments in the spindle coupled with their presence in the "contractile ring" of spermatocytes fixed during cytokinesis is evidence against the hypothesis that chromosome movements are microfilament-based. The results are compatible with the hypothesis that microtubules are involved in the mechanism of chromosome transport. The details of that mechanism remain to be clarified.