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.     

Control of concanavalin A receptor mobility by cytoplasmic actin in human tumour cells.

Tissue culture monolayers of seven human intracranial tumours comprising 2 astrocytomas, 3 meningiomas, 1 secondary squamous cell carcinoma and 1 secondary adenocarcinoma were examined by a double immunofluorescent staining technique to demonstrate Concanavalin A (Con A) surface receptors and cytoplasmic actin in the same cell. Tumour cells, treated with fluoresceinisothiocyanate-labelled Con A (FITC-Con A) showed staining in cell margins or in a random distribution over the cell surface. Incubating the cells with FITC-Con A at 37 degrees for increasing periods of time resulted first in staining of clusters and later of perinuclear globules. Cells, pretreated with 4% paraformaldehyde at 4 degrees for 10 min or with cytochalasin B at 37 degrees for 30 min showed staining restricted to cell margins. In the cytochalasin B-treated cells, the peripheral staining was in the form of coarse clusters. Double fluorochrome studies showed that the anti-actin antibody (AAA) staining occurred in sites closely related to those stained by FITC-Con A both in untreated as well as in cytochalasin B-treated cells. The findings suggest that Con A receptors, as an example of a stable cell membrane determinant in human tumour cells, are associated with actin and that their mobility on the cell surface is dependent on an intact cytoplasmic actin system.     

Mobility of epidermal growth factor surface receptors and modulation by cytoplasmic actin.

Epidermal growth factor (EGF) receptors were demonstrated in cultured bovine odontogenic epithelial and ectomesenchymal cells and in rat embryonic and foetal lung fibroblasts by immunofluorescent reactivity with EGF and anti-EGF traced with a fluorescein-isothiocyanate-labelled goat anti-rabbit globulin. Mobility of EGF receptors, either alone or cross linked by anti-EGF, was manifest as sequential changes in staining patterns progressing from a random pattern to clusters, supranuclear caps and large perinuclear globules. Double fluorochrome studies showed that supranuclear caps of EGF receptors occurred in sites closely related to those occupied by cytoplasmic actin; the latter was demonstrated by anti-actin antibody traced with a rhodamine-labelled goat anti-human globulin. Prior treatment of cells with 2 x 10-5 M cytochalasin B for 10-120 min promoted capping of EGF receptors, while its presence throughout the staining procedure inhibited capping. The dual opposing effects of cytochalasin B on capping suggest that actin may have roles in the opposing functions of EGF receptor anchorage and mobility.     

Nerve fibers in culture and their interactions with non-neural cells visualized by immunofluorescence

Cultures of embryonic mouse spinal cord explants, alone or in combination with rat myotubes, were stained by indirect immunofluorescence using antibodies against three structural proteins to: (a) reveal the distribution of these proteins among different cell types, and (b) test the usefulness of antibody staining to reveal the gross morphology of the neurite network in complex cultures. Affinity column purified antibodies were used against chicken gizzard actin, porcine brain tubulin, and skeletal muscle alpha-actinin. Neurites were stained intensely by anti-actin as was the stress fiber pattern of underlying fibroblasts. With anti-tubulin, the staining of neurites was an order of magnitude more intense than the staining of the microtubule pattern of background fibroblasts. Neurite cell bodies and astrocyte-like glia cells were stained with anti-tubulin and their nuclei remained unstained. Anti-tubulin could thus be used to trace even the finest extensions of nerve processes in spinal cord and spinal cord-muscle cultures. Furthermore, it could be combined with the histochemical reaction for acetylcholinesterase (AChE, EC 3.1.1.7) to demonstrate AChE-positive neurons and specialized nerve-muscle contact sites. The staining of neural elements with anti-alpha-actinin was generally much weaker than with anti-actin and anti-tubulin. Neurites were stained only moderately in comparison to myotube Z lines in the same culture. However, a distinct staining of the periphery of dorsal root ganglion cells was observed. Thus, a protein immunologically related to muscle alpha-actinin is present in the nervous system. In myotubes, Z lines were stained intensely with anti-alpha-actinin while I bands were only faintly stained with anti-actin. In isolated myofibrils, both structures were stained intensely with the same antibody preparations.     

Microinjected anti-actin antibodies decrease gap junctional intercellular commmunication in cultured astrocytes

The purpose of the present study was to investigate the influence of the actin cytoskeleton on gap junctional intercellular communication (GJIC) in cultured astrocytes. This report describes an decrease of GJIC following microinjection of anti-actin antibodies or cytochalasin D treatment. Dye transfer of microinjected neurobiotin was used to assay gap junctional permeability in cultured astrocytes. Besides this translocation of connexins to the plasma membrane we investigated subsequent anti-actin antibody injection. While control cultures exhibited intensive dye spreading of microinjected neurobiotin, GJIC was impaired by microinjection of anti-actin antibodies. Additionally, impaired GJIC was observed after cytochalasin D treatment for 15 min. After the drug had been washed out, a recovery of GJIC was achieved. Cultured astrocytes exhibited a prominent actin cytoskeleton, with strong staining of actin filaments at the plasma membrane. Confocal laser scanning microscopy revealed an impaired translocation of Cx 43 from the Golgi apparatus to the cell membrane of cell processes following anti-actin antibody injection. These results suggest that the morphological integrity of microfilaments seems to be fundamental for GJIC, probably by means of associations among actin filaments, actin binding proteins, and Cx 43 at the plasma membrane or indirectly through the transport of connexins from the cytoplasm to the cell membrane.     

Structural proteins in the growth cone of cultured spinal cord neurons

The distribution of several structural proteins in the extending neurites and growth cones of cultured embryonic mouse spinal cord neurons was studied by indirect immunofluorescence, using affinity chromatography-purified antibodies. Fibroblastic cells in the same cultures served as internal standards for the evaluation of staining intensities. Anti-tubulin, anti-actin, and anti-clathrin stained neurons and their processes intensely, while staining with anti-α-actinin was only moderate compared with fibroblasts. Microtubules were resolved by anti-tubulin in the ‘palm’ of the growth cone but not in the neurite. Anti-actin stained even the finest lamellae and filopodia of the growth cone, and the neurite. Anti-α-actinin revealed an irregularly speckled pattern of cross-reactive material in the neurite and in the palm of the growth cone and was absent from the filopodia. Anti-clathrin stained the neurite intensely and homogeneously, and to a lesser extent the palm of the growth cone. The staining with antibodies against tubulin and clathrin differed grossly between neurons and fibroblastic cells. Within the neuron there were only gradual differences in staining intensities. The growth cone was not qualitatively different from the rest of the neurite, except for the filopodia which lacked tubulin and α-actinin, similar to the microvilli of epithelial cells.     

Trypanosoma cruzi: distribution of fluorescently labeled tubulin and actin in epimastigotes

Cytoskeletal components were visualized in epimastigote forms of Trypanosoma cruzi by double immunofluorescence microscopy using monospecific antibodies against tubulin and against actin. Intense staining of the flagellum and the edges of the cell body was observed when the cells were stained with anti-tubulin, reflecting the presence of the basal bodies, the flagellar axoneme and the subpellicular microtubules. A less intense staining was seen in the cell body of epimastigotes stained with anti-actin. However, an intense staining was observed with this antibody in the flagellum, in a pattern similar to that observed with anti-tubulin. It is suggested that the paraxial structure, which is formed by a complex array of 6-nm-thick microfilaments is composed, at least in part, of actin.     

Anti-actin antibodies generated against profilin:actin distinguish between non-filamentous and filamentous actin, and label cultured cells in a dotted pattern

Actin polymerization is a prominent feature of migrating cells, where it powers the protrusion of the leading edge. Many studies have characterized the well-ordered and dynamic arrangement of filamentous actin in this submembraneous space. However, less is known about the organization of unpolymerized actin. Previously, we reported on the use of covalently coupled profilin:actin to study actin dynamics and presented evidence that profilin-bound actin is a major source of actin for filament growth. To locate profilin:actin in the cell we have now used this non-dissociable complex for antibody generation, and obtained monospecific anti-actin and anti-profilin antibodies from two separate immunizations. Fluorescence microscopy revealed drastic differences in the staining pattern generated by the anti-actin antibody preparations. With one, distinct puncta appeared at the actin-rich leading edge and sometimes aligned with microtubules in the interior of the lamella, while the other displayed typical actin filament staining. Labelling experiments in vitro demonstrated failure of the first antibody to recognize filamentous actin and none of the two bound microtubules. The two anti-profilin antibodies purified in parallel generated a punctated pattern similar to that seen with the first anti-actin antibody. All antibody preparations labelled the nuclei.     

Cellular distribution of p68, a new calcium-binding protein from lymphocytes.

A Ca2+-binding protein of mol. wt. 68 000 ( p68 ) is a major component of a Nonidet P-40 insoluble fraction of human and pig lymphocyte plasma membrane. An affinity-purified rabbit antibody has been produced against p68 and used to study its cellular distribution. The antibody stained fixed and permeabilised human B lymphoblastoid cells, peripheral blood lymphocytes and sections of human tonsil. Whole cells, however, were not stained, indicating that the protein was not represented at the cell surface. This assignment was consistent with the detection of p68 in immunoprecipitates from biosynthetically- but not surface-labelled cells. It is concluded that p68 is located on the cytoplasmic face of the plasma membrane. Subcellular fractionation experiments confirmed that p68 was largely membrane-bound in lymphocytes, although a small soluble fraction (approximately 10% of the total) was detected. Sub-fractionation of lymphocyte membranes revealed that p68 was associated not only with the plasma membrane but also with other endomembrane systems. As judged by immunoprecipitation, p68 was present in a variety of cultured cell lines of both lymphoid and non-lymphoid origin. p68 demonstrated a diffuse distribution in fixed and permeabilised fibroblasts which did not correspond to the distribution of either microfilaments or intermediate filaments. However, in detergent-extracted cells the protein was localised in a lamina-like network. A similar immunofluorescent staining pattern has recently been observed for spectrin-related proteins in the detergent-resistant cytoskeleton of fibroblasts. It is suggested that p68 is part of a sub-membranous cytoskeletal complex not only in lymphocytes but also in other cell types.     

Immunofluorescence demonstration of tubulin and actin in estrogen-induced rat prolactinoma cells in vitro : Alteration of their distribution after bromocriptine, colchicine and cytochalasin B treatments

Cultured cells in vitro from estrogen-induced rat prolactin-secreting adenomas (prolactinomas) were examined by indirect immunofluorescence microscopy for the distribution of cytoskeletal proteins and alterations of cytoskeleton after treatment with bromocriptine, colchicine and cytochalasin B (CB). After 8 days in culture, prolactinoma cells were well expanded and developed cytoplasmic processes were seen. The cytoplasmic microtubules were observed as fine reticular networks radiating from perinuclear portions toward the cell periphery when decorated with an antibody against tubulin. On the other hand, the actin filaments showed diffuse and spotty distribution when detected with an anti-actin antibody. Contaminated fibroblasts showed a reticular distribution of microtubules and a parallel array of actin cables which corresponds to "stress fibers" throughout the cytoplasm. After treatment with bromocriptine, the reticular distribution of microtubules in prolactinoma cells changed into a coarse and sparse pattern, which was identical with the changes in the distribution of tubulin after treatment with colchicine. On the other hand, distribution of actin was not affected by bromocriptine. Bromocriptine treatment did not alter the distribution of microtubules and actin filaments in fibroblasts, whereas colchicine changed the distribution of microtubules in both prolactinoma cells and fibroblasts. CB treatment changed the localization of actin filaments in both kinds of cells. These in vitro studies indicated bromocriptine would selectively affect the cytoplasmic microtubular system of prolactinoma cells.     

Distribution of actin, myosin, actin-binding protein and gelsolin in cultured lymphoid cells

Myosin, actin-binding protein (ABP) and gelsolin are proteins interacting with actin in vitro and may control the movement of amoeboid cells. The distribution of these proteins was examined by indirect immunofluorescence (IFL) of smeared, acetone-fixed lymphoid cells. Actin, ABP and gelsolin were found in filopodia and in the cytoplasm, whereas myosin was mainly in the cortical cytoplasm. In the presence of Ca²⁺ the staining of the filopodia by anti-actin, anti-ABP and anti-gelsolin antibodies were abolished. A 91 000 daltons (D) polypeptide reacting with anti-gelsolin antibodies and a 43 000 D polypeptide reacting with anti-actin antibodies were eluted from acetone-treated cells in presence of Ca²⁺. This effect of Ca²⁺ on the staining could be due to the action of gelsolin, which severs actin filaments. The shortened filaments would then elute from the cells during the staining procedures.     

Mitogen-like monoclonal anti-actin antibodies

Monoclonal antibodies (IgM kappa) have been produced to actin isolated electrophoretically from L cell extracts. These monoclonal anti-actin antibodies bind to intact L cells and modulate DNA synthesis and cell proliferation, much like affinity-purified polyclonal rabbit antibody to the same Mr 42,000 actin. In addition, monoclonal antibodies specific for actin from Entamoeba histolytica also bound to and modulated the growth of L cells. A monoclonal antibody directed against a neuroblastoma surface antigen did not produce stimulation of L cells, and the binding activity of anti-actin monoclonal antibody to L cells was removed by absorption with actin covalently coupled to Sepharose. These observations demonstrate the specificity of interaction between the anti-actin monoclonal antibodies and the surface of intact L cells. We conclude that a surface actin-like molecule on the L cell, when bound by specific monoclonal antibody, initiates a stimulatory signal which results in enhanced cellular metabolism.     

Immunofluorescent staining of keratin fibers in cultured cells.

Antibody prepared against a group of keratins purified from human stratum corneum was used to identify cells containing keratins by immunofluorescence. In sectioned tissue and in culture, keratinocytes of skin and other stratified squamous epithelia-whether human, rabbit of mouse-stained strongly, indicating homologous amino acid sequences in the keratins of these species. In all cases, the antibody revealed a dense cytoplasmic network of discrete fibers probably consisting of aggregated (tono-) filaments. The pattern of staining was not affected by cytochalasin B or colcemid. No keratins were detected in cultured cells of mesenchymal origin (3T3, NIL, BHK, human diploid fibroblasts) or in connective tissues, indicating that the 100 A filaments of fibroblasts are not related to the keratins. Keratinocytes at all stages of differentiation, including basal cells, stained brightly and therefore contained abundant keratins.     

Actin in the acrosome of the spermatozoa of the crab,Cancer pagurus L. (decapoda,crustacea)

The cytoskeletal protein actin was identified in the mature spermatozoon of the European edible crab, Cancer pagurus Linnaeus, by indirect immunofluoresce with monoclonal and polyclonal anti-actin antibodies, fluorescent phalloidin, and DNAase I. The actin was localized in two distinct concentric rings within the acrosome vesicle of the spermatozoon and appeared to correlate with the internal zonation of the vehicle. Modifications of the fluorescent pattern for actin were observed in sperm cells which were undergoing changes associated with the acrosome reaction. In these cases, fluorescent staining was observed in the nucleocytoplasm immediately subjacent to the perforatorial column and sometimes in the perforatorial column within the acrosome vesicle. Equally intense fluorescence was observed in an apical perforatorial projection. SDS-PAGE of C. pagurus sperm confirmed the presence of actin in the cells. A single band of actin (approximately 43 kDa) comigrated with rabbit muscle actin when immunoblotted onto nitrocellulose with mouse monoclonal anti-actin. The actin-associated cytoskeletal proteins α-actinin, tropomyosin, and spectrin were also identified within the spermatozoon of C. pagurus using specific polyclonal antibodies, but their presence was not confirmed by SDS-PAGE and immunoblotting. © 1994 Wiley-Liss, Inc.     

An antiactin antibody that distinguishes between cytoplasmic and skeletal muscle actins

We elicited antibodies in rabbits to actin purified from body wall muscle of the marine mollusc, Aplysia californica. We found that this antiactin has an unusual specificity: in addition to reacting with the immunogen, it recognizes cytoplasmic vertebrate actins but not myofibrillar actin. Radioimmunoassay showed little or no cross-reaction with actin purified from either chicken gizzard or rabbit skeletal muscle. Immunocytochemical studies with human fibroblasts and L6 myoblasts revealed intense staining of typical cytoplasmic cables. Myofibrils were not stained after treatment of human and frog skeletal muscle with the antibody, although the distribution of immunofluorescence suggested that cytoplasmic actin is associated with membrane systems in the muscle fiber. The antibody may therefore be especially suited for studying the localization of cytoplasmic actin in skeletal muscle cells even in the presence of a great excess of the myofibrillar form.     

Actin in mating structures of Chlamydomonas eugametos gametes

The presence of actin in Chlamydomonas eugametos mating structures was studied using monoclonal anti-actin antibodies. Immunofluorescent labelling of mating gametes clearly stained their mating structures and this was confirmed at the electron microscope level by immunogold labelling of sections. Anti-actin labelling also strongly stained the flagella at the flagellar collar regions and weakly stained the rest of the flagella. Treatment of gametes with 6–8% ethanol induced mating structures which protruded as large 'balloons'. Balloons stained brilliantly with anti-actin antibodies and weakly with FITC-phalloidin, a fluorescent reagent that stains F-actin. Isolated mating structure balloons and flagella were analyzed using western blotting. A prominent 43 kDa band, co-migrating with actin in erythrocyte ghosts, reacted with anti-actin antibodies. The results indicate that actin is present in mating structures and flagella of both mating types of C, eugametos .     

A lymphocyte cell surface molecule that is antigenically related to actin

When viable murine lymphocytes are incubated sequentially with a saturating amount of affinity-purified, rabbit anti-actin and highly conjugated FITC-goat anti-rabbit Ig, about 52% of mesenteric lymph node (MLN) lymphocytes and 36% of thymocytes exhibit a faint, but sharply punctate surface fluorescence. Cell surface actin (CSA) can be distinguished from staining of cytoplasmic actin in permeable cells, which are identified by their uptake of ethidium bromide. Staining of actin in ethidium bromide-permeable cells is 10-fold more intense than staining of actin on ethidium bromide-impermeable cells and is seen as uniformly fluorescent rings or crescents at the periphery of the cell and as dimmer, diffuse fluorescence centrally. Binding of rabbit anti-actin and goat anti-rabbit Ig to the lymphocyte cell surface is not mediated by Fc receptors; F(ab')2 fragments of these antibodies detect the same number of positive cells as do the intact molecules, and affinity-purified anti-KLH does not bind significantly. The cell surface stain, measured by flow cytometry or fluorescence microscopy, can be absorbed by pretreatment of the anti-actin with immobilized actin but not with IgG-Sepharose. Double-label experiments show that about 70% of the non-B cells and 30% of the MLN B cells bear detectable CSA. Although we have not ascertained the origin of CSA, we find that the number and brightness of cells exhibiting CSA cannot be increased by preincubating the cells with exogenous native skeletal muscle actin or with supernatant from dissociated MLN, indicating that there are no free binding sites for exogenous actin. The findings imply that either there is a developmentally expressed binding site(s) for actin, or that at various stages of development lymphocytes express a protein antigenically related to actin on their surface.     

Immunological characterization of an anti-actin antibody specific for cytoplasmic actins and its use for the immunocytological localization of actin in Aplysia nervous tissue

Previous immunochemical and immunocytochemical studies have shown that an antibody to actin prepared from body wall muscle of the marine mollusc Aplysia californica is specific for vertebrate cytoplasmic actins. The ability of this anti-actin to distinguish between different forms of actin most likely reflects the recognition of amino acid sequences unique to cytoplasmic actins. We have confirmed the specificity of this antibody for cytoplasmic actins using nervous tissue as a source of cytoplasmic actin in further immunochemical studies. In addition to binding cytoplasmic actin in purified preparations, the antibody removed actin selectively from crude extracts of nervous tissue of some but not all of the species tested. Our results also suggest that tissue-specific differences in the distribution of cytoplasmic actins may exist. Immunofluorescence studies of Aplysia nervous tissue stained with anti-actin revealed that actin is present in the cell body and axonal processes of Aplysia neurons. Although the function of actin in nerve cells is not understood, the observed pattern of immunofluorescence staining is consistent with the idea that actin may be involved in movement within the axoplasm.     

Human plasma actin-depolymerizing factor. Purification, biological activity and localization in leukocytes and platelets

The plasma and serum of humans and various animal species exert an actin-depolymerizing activity. Human actin-depolymerizing factor (ADF) has been purified by ammonium sulfate fractionation, DEAE-cellulose and blue-Sepharose chromatography. It is a single polypeptide of approximately 90 kDa, with a pI between 6.0 and 6.5. ADF is heat and trypsin-sensitive, inactivated by EGTA, not stained by HIO4/Schiff on sodium dodecyl sulfate/polyacrylamide gel electrophoresis (SDS/PAGE), and not retained on a concanavalin-A-Sepharose column. Incubation of ethanol-fixed cultured cells or unfixed cryostat tissue sections with ADF abolishes immunofluorescent actin staining, by a mechanism which involves extraction of actin from the preparations. ADF promotes fragmentation and depolymerization of actin filaments as shown by electron microscopy, differential ultracentrifugation and DNAse I inhibition assay. This depolymerized actin retains its mobility on SDS/PAGE and is able to repolymerize in the presence of EGTA. Human white blood cells and platelets (but neither human fibroblasts nor white blood cells and platelets from pig, rat and rabbit) contain a 90-kDa protein reacting with an antibody raised in rabbit against human ADF as judged by immunofluorescence and immunoblotting techniques. Immunoblots of human granulocyte subcellular fractions suggest that the protein reacting with ADF antibody is present in the soluble cytoplasmic fraction. ADF may play a role in solubilization of plasma actin and in the intracellular organization of actin, and should be useful for the evaluation of the relative stability of cytoplasmic actin filaments in various physiological and pathological processes.