Organization of actin, myosin, and intermediate filaments in the brush border of intestinal epithelial cells

Terminal webs prepared from mouse intestinal epithelial cells were examined by the quick-freeze, deep-etch, and rotary-replication method. The microvilli of these cells contain actin filaments that extend into the terminal web in compact bundles. Within the terminal web these bundles remain compact; few filaments are separated from the bundles and fewer still bend towards the lateral margins of the cell. Decoration with subfragment 1 (S1) of myosin confirmed that relatively few actin filaments travel horizontally in the web. Instead, between actin bundles there are complicated networks of the fibrils. Here we present two lines of evidence which suggest that myosin is one of the major cross-linkers in the terminal web. First, when brush borders are exposed to 1 mM ATP in 0.3 M KCl, they lose their normal ability to bind antimyosin antibodies as judged by immunofluorescence, and they lose the thin fibrils normally found in deep-etch replicas. Correspondingly, myosin is released into the supernatant as judged by SDS gel electrophoresis. Second, electron microscope immunocytochemistry with antimyosin antibodies followed by ferritin- conjugated second antibodies leads to ferritin deposition mainly on the fibrils at the basal part of rootlets. Deep-etching also reveals that the actin filament bundles are connected to intermediate filaments by another population of cross-linkers that are not extracted by ATP in 0.3 M KCl. From these results we conclude that myosin in the intestinal cell may not only be involved in a short range sliding-filament type of motility, but may also play a purely structural role as a long range cross-linker between microvillar rootlets.     

Distribution of actin and the actin-associated proteins myosin, tropomyosin, alpha-actinin, vinculin, and villin in rat and bovine exocrine glands

Actin, myosin, and the actin-associated proteins tropomyosin, alpha-actinin, vinculin, and villin were localized in acinar cells of rat and bovine pancreas, parotid, and prostate glands by means of immunofluorescent staining of both frozen tissue sections and semithin sections of quick-frozen, freeze-dried, and plastic-embedded tissues. Antibodies to actin, myosin, tropomyosin, alpha-actinin, and villin reacted strongly with a narrow cytoplasmic band extending beneath the luminal border of acinar cells. The presence of villin, which has so far been demonstrated only in intestinal and kidney brush border, was further confirmed by antibody staining of blotted electrophoresis gels of whole acinar cell extracts. Fluorescently labelled phalloidin, which reacts specifically with F-actin, gave similar staining, within the cell apex to that obtained with antibodies to actin, myosin, tropomyosin, alpha-actinin, and villin. In contrast, immunostaining with antibodies to vinculin was restricted to the area of the junctional complex. Ultrastructurally, the apical immunoreactive band corresponded to a dense web composed of interwoven microfilaments, which could be decorated with heavy meromyosin. Outside this apical terminal web, antibodies to myosin and tropomyosin gave only a weak immunostaining (confined to the lateral cell borders) whereas antibodies to actin and alpha-actinin led to a rather strong bead-like staining along the lateral and basal cell membrane most probably marking microfilament-associated desmosomes. Anti-villin immunofluorescence was confined to the apical terminal web. It is suggested that the apical terminal web is important for the control of transport and access of secretory granules to the luminal plasma membrane and that villin, which is known to bundle or sever actin filaments in a Ca(++)-dependent manner, might participate in the regulation of actin polymerization within this strategically located network of contractile proteins.     

Isolation of microvillar microfilaments and associated transmembrane complex from ascites tumor cell microvilli

The association of microvillar microfilaments with the microvillar membrane actin-containing transmembrane complex of MAT-C1 13762 ascites tumor cell microvilli has been investigated by differential centrifugation, gel electrophoresis and electron microscopy of detergent extracts of the isolated microvilli. Several methods have been used to reduce breakdown and solubilization of the microfilament core actin during the detergent extractions for preparation of microvillar core microfilaments. Gel electrophoresis of differential centrifugation fractions demonstrated that over 70% of the total microvillus actin could be pelleted with microfilament cores at 10 000 g under extraction conditions which reduce filament breakdown. Transmission electron microscopy (TEM) of all of the core preparations showed arrays of microfilaments and small microfilament bundles. The major protein components of the microfilament cores, observed by sodium dodecyl sulfate (SDS) electrophoresis, were actin and alpha-actinin. Among the less prominent polypeptide components was a 58 000 Dalton polypeptide (58 K), previously identified as a member of the MAT-Cl transmembrane complex. This three-component complex contains, in addition to 58 K, actin associated directly and stably with a cell surface glycoprotein (Carraway, CAC, Jung, G & Carraway, K L, Proc. natl acad. sci. US 80 (1983) 430). Evidence that the apparent association of complex with the microfilament core was not due simply to co-sedimentation was provided by myosin affinity precipitation. These results provide further evidence that the transmembrane complex is a site for the interaction of microfilaments with the microvillar plasma membrane.     

Distribution of actin and tubulin in cells and in glycerinated cell models after treatment with cytochalasin B (CB)

The organization of microfilaments and microtubules in cultured cells before and after the addition of cytochalasin B (CB) was studied both by electron microscopy and immunofluorescence microscopy using antibodies specific for actin, tubulin and tropomyosin. CB induces a rapid disorganization of normal microfilament bundles. Star-like patches of actin and tropomyosin are visualized in immunofluorescence microscopy and dense aggregates of condensed microfilaments are seen in electron microscopy. The integrity of the microtubules is not changed by CB treatment. Addition of CB to glycerinated cells, in contrast to normal cells, does not result in the disorganization of microfilament bundles. CB-treated glycerinated models can still contract upon addition of ATP. Thus the CB-induced rearrangement of microfilament bundles occurs only in vivo and not in glycerinated cell contractility models.     

Formation of the tooth enamel rod pattern and the cytoskeletal organization in secretory ameloblasts of the rat incisor

The localization of actin, myosin, tropomyosin, alpha-actinin, vinculin, and desmoplakin I/II was visualized by immunofluorescence microscopy. Antibodies against myosin, tropomyosin, and alpha-actinin and rhodamine-phalloidin labeled strongly the proximal and distal terminal webs which ultrastructurally consist of dense microfilament bundles. In the distal terminal web, the staining by these reagents occurred mostly perpendicular to the long axis of the incisor. Antivinculin stained the general area where the distal terminal web is located in the ameloblast. Anti-desmoplakin I/II labeled the junctional area associated with the proximal and distal terminal webs. The anti-desmoplakin staining was stronger along the cell border perpendicular to the long axis of the incisor. Comparison of the rhodamine-phalloidin staining pattern of the distal terminal web and the enamel secretion pattern by ameloblasts revealed that a change in the distal terminal web staining pattern preceded a change in the secretion pattern. These observations suggest that the cytoskeletal organization in the ameloblast is involved in the formation of the enamel matrix pattern in the rat incisor.     

Immunofluorescent localization of myosin, alpha-actinin and tropomyosin in odontoblast microfilament bundles of the rat incisor

The localization of alpha-actinin, tropomyosin, myosin and actin in odontoblasts was examined by fluorescence microscopy using well characterized antibodies and rhodamine-phalloidin. All the reagents labeled the distal end of the cell body in the form of an oval ring with a preferential axis along the tooth axis. This ring was often interrupted. In conventional electron microscopy, microfilament bundles with periodical dense spots were running along the tooth axis at the level of the distal end of the cell body. The periodicity was about 0.6-1.0 microns. It may be possible that this dynamic structure functions to keep odontoblasts in a layer by contracting in an isometric form.     

Brush border motility. Microvillar contraction in triton-treated brush borders isolated from intestinal epithelium

The brush border of intestinal epithelial cells consists of an array of tightly packed microvilli. Within each microvillus is a bundle of 20-30 actin filaments. The basal ends of the filament bundles are embedded in and interconected by a filamentous meshwork, the terminal web, which lies directly beneath the microvilli. When calcium and ATP are added to isolated brush borders that have been treated with the detergent, Triton X-100, the microvillar filament bundles rapidly retract into and through the terminal web region. Biochemical studies of brush border contractile proteins suggest that the observed microvillar contraction is actomyosin mediated. We have shown previously that the major protein of the brush border's actin (Tilney, L. G., and M. S. Mooseker. 1971. Proc. Natl. Acad. Sci. U. S. A. 68:2611-2615). The brush border also contains a protein with the same molecular weight as the heavy chain subunit of myosin (200, 000 daltons). In addition, preparations of demembranated brush borders exhibit potassium-EDTA ATPase activity of 0.02 mumol phosphate/mg-min (22 degrees C); this assay is diagnostic for myosin-like ATPase isolated from vertebrate sources. Other proteins of the brush border include a 30,000 dalton protein with properties similar to those of tropomyosin, and a protein with the same molecular weight as the Z band protein, alpha-actinin (95,000 daltons). How these observations bear on the basis for microvillar movements in vivo is discussed within the framework of our recent model for the organization of actin and myosin in the brush border (Mooseker, M. S., and L. G. Tilney. 1975. J. Cell Biol. 67:725-743).     

Immunocytochemical localization of myosin in the brush border region of the intestinal epithelium

Summary Myosin was localized in rat intestinal epithelium by means of indirect immunofluorescence and immunoelectron microscopy (unlabeled antibody peroxidase method), using a specific antibody to myosin from chicken gizzard. Immunoreactivity was localized in the apical cytoplasm, where it was concentrated along the rootlets of the microvillar filament bundles and in the terminal web. A model of microvillar contraction is proposed.     

Cytoskeletal organization in locomoting cells of the V2 rabbit carcinoma

The relationship between the organization of cytoskeletal elements and locomotory activity was studied in single cells of the V2 rabbit carcinoma. Like migratory fibroblasts, and unlike colony-forming epithelial cells, these cells show a pronounced horizontal polarization, and develop a large lamella at their leading front. With affinity-purified antibodies and a combination of light and electron microscopic techniques, actin and alpha-actinin (but not myosin and tropomyosin) were found highly concentrated within the marginal region of the leading lamella, both in ruffles and in the underlying zone of contacts with the substratum. Close contacts prevailed in the locomotory cells and small focal contacts developed only in cells detaching from others. Focal contacts always contained small microfilament bundles. Reorganization of actin filaments is suggested as the fundamental event for the dynamic contact formation of the leading lamella. Large microfilament bundles (stress fibers) were absent in all stages of locomotion.Since locomotory behavior and shape changes of V2 cells are the same on glass as on the surface of a natural membrane, the rabbit mesentery, organization and distribution of contractile elements of cultured V2 cells probably reflect the in vivo situation.     

Identification of the cytoskeletal proteins in lens-forming cells, a special epithelioid cell type

Proteins of contractile and cytoskeletal elements have been studied in bovine lens-forming cells growing in culture as well as in bovine and murine lenses grown in situ by immunofluorescence microscopy using antibodies to the following proteins: actin, myosin, tropomyosin, α-actinin, tubulin, prekeratin, vimentin, and desmin. Lens-forming cells contain actin, myosin, tropomyosin, and α-actinin which in cells grown in culture are enriched in typical cable-like structures, i.e. microfilament bundles. Antibodies to tubulin stain normal, predominantly radial arrays of microtubules. In the epithelioid lens-forming cells of both monolayer cultures grown in vitro and lens tissue grown in situ intermediate-sized filaments of the vimentin type are abundant, whereas filaments containing prekeratin-like proteins (‘cytokeratins’) and desmin filaments have not been found. The absence of cytokeratin proteins observed by immunological methods is supported by gel electrophoretic analyses of cytoskeletal proteins, which show the prominence of vimentin and the absence of detectable amounts of cytokeratins and desmin. This also correlates with electron microscopic observations that typical desmosomes and tonofilament bundles are absent in lens-forming cells, as opposed to a high density of vimentin filaments. Our observations show that the epithelioid lens-forming cells have normal arrays of (i) microfilament bundles containing proteins of contractile structures; (ii) microtubules; and (iii) vimentin filaments, but differ from most true epithelial cells by the absence of cytokeratins, tonofilaments and typical desmosomes. The question of their relationship to other epithelial tissues is discussed in relation to lens differentiation during embryogenesis. We conclude that the lens-forming cells either represent an example of cell differentiation of non-epithelial cells to epithelioid morphology, or represent a special pathway of epithelial differentiation characterized by the absence of cytokeratin filaments and desmosomes. Thus two classes of tissue with epithelia-like morphology can be distinguished: those epithelia which contain desmosomes and cytokeratin filaments and those epithelioid tissues which do not contain these structures but are rich in vimentin filaments (lens cells, germ epithelium of testis, endothelium).     

Stress fiber dynamics as probed by antibodies against myosin

The dynamics of microfilament bundles (stress fibers) in tissue culture cells were studied by microinjecting an affinity-purified polyclonal antibody against chicken gizzard myosin. This antibody cross-reacted exclusively with the light chains of nonmuscle myosin and should therefore bind to the head portion of myosin molecules. When injected in high concentrations (13-26 mg/ml), it disrupted stress fibers in a high proportion (60-80%) of rat and chicken embryo fibroblasts, as well as in PtK2 cells. Myosin was found collected in large aggregates probably comprising protein: antibody precipitates, while actin and alpha-actinin were not localized in any defined structures in stress fiber depleted cells. Fibroblasts rounded up, probably because of lack of tension-generating microfilament bundles. After several hours, stress fibers were seen to regrow again in the afflicted cells, even when myosin precipitates and excess antibody were still present. The extent of stress fiber disruption and the time point of their reappearance were dependent on the concentration of the injected antibody.     

Visualization of the same PtK2 cytoskeletons by both immunofluorescence and low power electron microscopy.

A procedure is described which allows the examination of the cytoskeleton of a single PtK2 cell first by immunofluorescence and then by electron microscopy after staining with uranyl acetate. The immunofluorescent patterns of these detergent resistant cytoskeletons elicited with various monospecific antibodies closely resemble the patterns found in whole cells. Comparison of the immunofluorescence and electron micrographs directly supports the previous assignments of actin, myosin, filamin, α-actinin and tropomyosin as proteins associated with microfilament bundles in non-muscle cells. Actin is also found associated with a fine lattice-like structure present both in the ruffles and lying above the microfilament bundles in the cell body. The tonofilament bundles present in PtK2 cytoskeletons are not decorated by antibodies directed against the proteins associated with microfilament bundles. Antibodies directed against tonofilaments decorate specifically this system and not the microfilament bundles.     

Quick-freeze, deep-etch visualization of the cytoskeleton beneath surface differentiations of intestinal epithelial cells

The cytoskeleton that supports microvilli in intestinal epithelial cells was visualized by the quick-freeze, deep-etch, rotary-replication technique (Heuser and Salpeter. 1979. J. Cell Biol. 82: 150). Before quick freezing, cells were exposed to detergents or broken open physically to clear away the granular material in their cytoplasm that would otherwise obscure the view. After such extraction, cells still displayed a characteristic organization of cytoskeletal filaments in their interiors. Platinum replicas of these cytoskeletons had sufficient resolution to allow us to identify the filament types present, and to determine their characteristic patterns of interaction. The most important new finding was that the apical "terminal web" in these cells, which supports the microvilli via their core bundles of actin filaments, does not itself contain very much actin but instead is comprised largely of narrow strands that interconnect adjacent actin bundles with one another and with the underlying base of intermediate filaments. These strands are slightly thinner than actin, do not display actin's 53A periodicity, and do not decorate with myosin subfragment S1. On the contrary, two lines of evidence suggested that these strands, could include myosin molecules. First, other investigators have shown that myosin is present in the terminal web (Mooseker et al. 1978. J. Cell Biol. 79: 444-453), yet we could find no thick filaments in this area. Second, we found that the strands were removed completely in the process of decorating the core filament bundles with the myosin subfragment S1, suggesting that they had been competitively displaced by exogenous myosin. We conclude that myosin may play a structural role in these cells, via its cross-linking distribution, in addition to whatever role it plays in microvillar motility.     

Analysis of actin and microfilament-associated proteins in the mitotic spindle and cleavage furrow of PtK2 cells by immunofluorescence microscopy: A critical note

The distribution of actin and the microfilament-associated proteins myosin and tropomyosin was studied in mitotic PtK2 cells. Using fluorescent heavy meromyosin and two different antibodies against actin we have found no evidence for increased accumulations of actin in the mitotic spindle but have found increased levels of actin in the cleavage furrow and the contractile ring. Short, thin microfilament pieces remain detectable in the cytoplasm throughout mitosis. Purified antibodies against myosin and tropomyosin also revealed no increased levels of these proteins in the spindle region, although both proteins were found in the contractile ring and areas of the cytoplasm close to the intercellular bridge. These data are in agreement with functional and ultrastructural studies involving a role for actin and microfilament-related proteins in cytokinesis. They do not support models in which microfilament-related proteins are assumed to be a major constituent of the mitotic spindle.     

The molecular architecture of an insect midgut brush border cytoskeleton.

The cytoskeletal apparatus of the vertebrate intestinal brush border (BB) has served as a model system for the actin-based cytoskeleton of nonmuscle cells. In this study, we examine the structural organization and molecular architecture of the BB cytoskeleton expressed in the midgut of lepidopteran larvae, Manduca sexta. Electron microscopy of the midgut of the 5th instar larvae revealed enterocytes with an apical BB surface comparable to that in the vertebrate intestine, with both microvillar (MV) and terminal web (TW) domains, the latter defined by a zone of organelle exclusion directly beneath the MV. As reported previously for the larval dragon fly, the MV contain a bundle of actin filaments, as determined by staining with rhodamine phalloidin (Kukulies, J., et al., Protoplasma 121, 157-162 (1984)) and heavy meromyosin decoration (Komnick, H., J. Kukulies, Zoomorphology 107, 241-253 (1987)). Two-dimensional gel analysis revealed the presence of multiple isoelectric variants of actin with the major isoform corresponding to the non-muscle actin isoform II, expressed in Drosophila. Like the vertebrate BB, the Manduca BB can be isolated intact from enterocytes by mechanical shear. Immunochemical analysis of isolated BB fractions or whole homogenates of midgut revealed proteins of appropriate molecular weight immunoreactive with antibodies to the MV core proteins: BB myosin I, villin and fimbrin, and the TW components: spectrin, myosin II and tropomyosin. Immunocytochemical localization of a subset of these proteins at the light microscopic (spectrin) and electron microscopic (actin, villin, spectrin, myosin II, and tropomyosin) level reveals that the molecular architecture of the Manduca BB cytoskeleton is homologous to that found in vertebrates.     

Overexpression of human fibroblast caldesmon fragment containing actin- , Ca++/calmodulin-, and tropomyosin-binding domains stabilizes endogenous tropomyosin and microfilaments

Fibroblast caldesmon is a protein postulated to participate in the modulation of the actin cytoskeleton and the regulation of actin-based motility. The cDNAs encoding the NH2-terminal (aa.1-243, CaD40) and COOH-terminal (aa.244-538, CaD39) fragments of human caldesmon were subcloned into expression vectors and we previously reported that bacterially produced CaD39 protein retains its actin-binding properties as well as its ability to enhance low M(r) tropomyosin (TM) binding to actin and to inhibit TM-actin-activated HMM ATPase activity in vitro (Novy, R. E., J. R. Sellers, L.-F. Liu, and J. J.-C. Lin. 1993. Cell Motil. Cytoskeleton. 26:248-261). Bacterially produced CaD40 does not bind actin. To study the in vivo effects of CaD39 expression on the stability of actin filaments in CHO cells, we isolated and characterized stable CHO transfectants which express varying amounts of CaD39. We found that expression of CaD39 in CHO cells stabilized microfilament bundles as well as endogenous TM. CaD39-expressing clones displayed an increased resistance to cytochalasin B and Triton X-100 treatments and yielded increased amounts of TM-containing actin filaments in microfilament isolation procedures. In addition, analysis of these clones with immunoblotting and indirect immunofluorescence microscopy with anti-TM antibody revealed that stabilized endogenous TM and enhanced TM-containing microfilament bundles parallel increased amounts of CaD39 expression. The increased TM observed corresponded to a decrease in TM turnover rate and did not appear to be due to increased synthesis of endogenous TM. Additionally, the phenomenon of stabilized TM did not occur in stable CHO clones expressing CaD40. Therefore, it is likely that CaD39 can enhance TM's binding to F-actin in vivo, thus reducing TM's rate of turnover and stabilizing actin microfilament bundles.     

Regulation of actin microfilament integrity in living nonmuscle cells by the cAMP-dependent protein kinase and the myosin light chain kinase

Microinjection of the catalytic subunit of cAMP-dependent protein kinase (A-kinase) into living fibroblasts or the treatment of these cells with agents that elevate the intracellular cAMP level caused marked alterations in cell morphology including a rounded phenotype and a complete loss of actin microfilament bundles. These effects were transient and fully reversible. Two-dimensional gel electrophoresis was used to analyze the changes in phosphoproteins from cells injected with A-kinase. These experiments showed that accompanying the disassembly of actin microfilaments, phosphorylation of myosin light chain kinase (MLCK) increased and concomitantly, the phosphorylation of myosin P- light chain decreased. Moreover, inhibiting MLCK activity via microinjection of affinity-purified antibodies specific to native MLCK caused a complete loss of microfilament bundle integrity and a decrease in myosin P-light chain phosphorylation, similar to that seen after injection of A-kinase. These data support the idea that A-kinase may regulate microfilament integrity through the phosphorylation and inhibition of MLCK activity in nonmuscle cells.     

Localization of actin and microfilament-associated proteins in the microvilli and terminal web of the intestinal brush border by immunofluorescence microscopy.

Indirect immunofluorescence microscopy was used to localize microfilament-associated proteins in the brush border of mouse intestinal epithelial cells. As expected, antibodies to actin decorated the microfilaments of the microvilli, giving rise to a very intense fluorescence. By contrast, antibodies to myosin, tropomyosin, filamin, and alpha-actinin did not decorate the microvilli. All these antibodies, however, decorated the terminal web region of the brush border. Myosin, tropomyosin, and alpha-actinin, although present throughout the terminal web, were found to be preferentially located around the periphery of the organelle. Therefore, two classes of microfilamentous structures can be documented in the brush border. First, the highly ordered microfilaments which make up the cores of the microvilli apparently lack the associated proteins. Second, seemingly less-ordered microfilaments are found in the terminal web, in which region the myosin, tropomyosin, filamin and alpha-actinin are located.     

Some of eukaryotic elongation factor 2 is colocalized with actin microfilament bundles in mouse embryo fibroblasts

Indirect immunofluorescent microscopy was used to study the distribution of eukaryotic elongation factor 2 (EF-2) in cultured mouse embryo fibroblasts. The perinuclear area (endoplasm) of all the cells and many straight cables running along the whole cytoplasm were stained with monospecific goat or rabbit antibodies to rat liver EF-2. Double staining of the cells with antibodies to EF-2 and rhodaminyl-phalloidin (used for actin microfilament detection) showed that EF-2 containing cables coincided with bundles of actin microfilaments. Not all actin microfilament bundles contained EF-2: sometimes EF-2 was not observed in bundles running along the cell edges or in actin microfilament junctions. Triton X-100 extracted most of EF-2 from the cells and no actin microfilament bundles were stained with the EF-2 antibodies in the Triton-extracted cells. Thus, in mouse embryo fibroblasts EF-2 can be found along actin microfilament bundles, but it is unlikely to be their integral protein.     

Microfilaments and tropomyosin of cultured mammalian cells: isolation and characterization

Microfilaments were isolated from cultured mammalian cells, utilizing procedures similar to those for isolation of "native" thin filaments from muscle. Isolated microfilaments from rat embryo, baby hamster kidney (BHK- 21), and Swiss mouse 3T3 cells appeared structurally similar to muscle thin filaments, exhibiting long, 6 nm Diam profiles with a beaded, helical substructure. An arrowhead pattern was observed after reaction of isolated microfilaments with rabbit skeletal muscle myosin subfragment 1. Under appropriate conditions, isolated microfilaments will aggregate into a form that resembles microfilament bundles seen in situ cultured cells. Isolated microfilaments represent a complex of proteins including actin. Some of these components have been tentatively identified, based on coelectrophoresis with purified proteins, as myosin, tropomyosin, and a high molecular weight actin-binding protein. The tropomyosin components of isolated microfilaments were unexpected; polypeptides comigrated on SDS-polyacrylamide gels with both muscle and nonmuscle types of tropomyosin. In order to identify more specifically these subunits, we isolated and partially characterized tropomyosin from three cell types. BHK-21 cell tropomyosin was similar to other nonmuscle tropomyosins, as judged by several criteria. However, tropomyosin isolated from rate embryo and 3T3 cells contained subunits that comigrated with both skeletal muscle and nonmuscle types of myosin, whereas the BHK cell protein consistently contained a minor muscle-like subunit. The array of tropomyosin subunits present in a cell culture was reflected in the polypeptide chain pattern seen on SDS-polyacrylamide gels of microfilaments isolated from that culture. These studies provide a starting point for correlating changes in the ultrastructural organization of microfilaments with alterations in their protein composition.