Rod-like elements from actin-containing microfilament bundles observed in cultured cells after treatment with cytochalasin A (CA)

Cofilin aggregation blocks intracellular trafficking and induces synaptic loss in hippocampal neurons

Cofilin is an actin-binding protein and a major actin depolymerization factor in the central nervous system (CNS). Cofilin-actin aggregates are associated with neurodegenerative disorders, but how cofilin-actin aggregation induces pathological effects in the CNS remains unclear. Here, we demonstrated that cofilin rods disrupted dendritic microtubule integrity in rat hippocampal cultures. Long term time-lapse imaging revealed that cofilin rods block intracellular trafficking of both mitochondria and early endosomes. Importantly, cofilin rod formation induced a significant loss of SV2 and PSD-95 puncta as well as dendritic spines. Cofilin rods also impaired local glutamate receptor responses. We discovered an inverse relationship between the number of synaptic events and the accumulation of cofilin rods in dendrites. We also detected cofilin rods in aging rat brains in vivo. These results suggest that cofilin aggregation may contribute to neurodegeneration and brain aging by blocking intracellular trafficking and inducing synaptic loss.

Cofilin expression induces cofilin-actin rod formation and disrupts synaptic structure and function in Aplysia synapses

Cofilin-actin rods are inclusion-like structures that are induced by certain chemical or physical stresses in cultured cells, and the rods formed in neurons are thought to be associated with neurodegeneration. Here, we cloned an Aplysia cofilin homolog and overexpressed it in cultured neurons. Overexpressed cofilin formed rod-like structures that included actin. The overall neuronal morphology was unaffected by cofilin overexpression; however, a decrease in number of synaptic varicosities was observed. Consistent with this structural change by cofilin overexpression, the synaptic strength was reduced, and furthermore, the long-term facilitation elicited by repeated pulses of 5-hydroxytryptamine was impaired in sensory-to-motor synapses. However, cofilin overexpression did not induce programmed cell death. These findings suggest that the formation of cofilin-actin rod-like structures can lead to neurodegeneration, and this might be a mechanism of rundown of neuronal and synaptic function without cell death in neurodegenerative diseases.

Restoration of movement and apical growth in the angiosperm pollen tube following cytochalasin-induced paralysis

Cytochalasin D (CD) at 5 pg ml-1arrested growth and vectorial movement in pollen tubes ofNarcissus pseudonarcissusandEndymion nonscriptusand caused the mainly longitudinally oriented actin fibrils in the vegetative cells to coalesce and form massive, more randomly oriented, cables. As extension growth was arrested, the tubes formed apical bulbs and abnormal wall thickenings. During recovery from a 10 min treatment period inE. nonscriptus, an essentially normal fibril system was reconstituted by partial dissociation of the thick cables formed during the exposure to CD. As this progressed movement was restored in the vegetative cells. Some 80 % of the blocked tubes initiated new growing points, either by producing randomly oriented swellings in sites where the wall was thinner, or by erosion and penetration of thicker zones. Contrary to expectation, the sites of the prospective growing points were not indicated in advance by any special disposition of the actin cytoskeleton. With the transition to cylindrical growth in the secondary tubes the standard stratification of the tube wall reappeared, with outer pectocellulosic and inner callosic layers. Normal movement pathways were established concomitantly, together with the apical zonation of organelles and other cytoplasmic inclusions characteristic of the extending tube. CD-treatment brought about rapid contraction of the vegetative nuclei with the loss of the elastic extensions of the nuclear envelopes. The extended form was resumed as the actin cytoskeleton was restored during recovery, and vegetative nuclei and generative cells moved into the secondary tubes where they continued to track the apex as in the normal tube.

Quantitative assessment of melanoma single-cell motility in vitro

Cell motility is a crucial property of tumor cells during invasion and metastasis. In this study we developed a computer assisted system to measure translocation and stationary motility of single cells and used this procedure to evaluate the influence of cytochalasin A (CA) on single-cell motility parameters of K1735-M2 mouse melanoma cells. The cells were seeded at low density into a microincubator. Time lapse microcinematography was performed every 20 seconds from a high power field to assess stationary motility and every 10 minutes with a screening objective to measure translocation. 1 muMol CA was added to the medium 48 hours before measurement. Calculation of stationary motility was performed by subtraction of subsequent images and the resulting image difference was used for quantitative evaluation. Three different measuring windows were drawn to discriminate between membrane ruffling, intracellular organelle transport and overall stationary motility. For each cell we measured change of density (CD), area of change (AC), perimeter of area of change (PC), area of ruffling (AR), number of ruffling sites (NR), change of intracellular organelles (CIO) and number of changing intracellular organelles (NIO). In order to quantify translocation, the center of gravity of each cell was assessed subsequently and the velocity was calculated by connecting the centers of gravity. CA-treated cells showed a significantly lower stationary motility and membrane ruffling compared to the untreated cells (U-test: p < = 0.01), but there was not significant difference concerning the intracellular organelle transport.(ABSTRACT TRUNCATED AT 250 WORDS)

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.

Cofilin is a component of intranuclear and cytoplasmic actin rods induced in cultured cells

Incubation of cultured cells under specific conditions induces a dramatic change in the actin organization: induction of intranuclear and/or cytoplasmic actin rods (actin paracrystal-like intracellular structures). We have found that cofilin, a 21-kDa actin-binding protein, is a component of these rods. Antibodies directed against cofilin labeled intranuclear actin rods induced in cells treated with dimethyl sulfoxide or exposed to heat shock and also labeled cytoplasmic actin rods induced in cells incubated in specific salt buffers. Moreover, we found that these actin rods are not stained with fluorescent phalloidin derivatives at all and appear to be right-handed helices, different from straight bundles of F-actin such as stress fibers. In vitro experiments revealed that cofilin and phalloidin compete with each other for binding to F-actin. Since cofilin and phalloidin have the ability to stoichiometrically bind actin molecule in the filament in vitro, the above results seem to suggest that cofilin directly binds to actin molecule in nearly an equimolar ratio in these rods. We call these rods "actin/cofilin rods."

Cytoplasmic intermediate filament proteins and the nuclear lamins A, B and C share the IFA epitope

The murine monoclonal antibody IFA isolated by Pruss et al. (Cell 27 (1981) 419) reacts with all major proteins of the cytoplasmic intermediate filament family (IF) albeit with different affinities but leaves the nucleus undecorated in standard immunofluorescence microscopy. Here we show that IFA reacts with all three nuclear lamins from rat and man in immunoblotting. This is most easily demonstrated in a cell line in which most cells lack cytoplasmic IFs. Thus the rather minor but ubiquitous 66 kD polypeptides identified by Pruss et al. as IF-associated proteins reflect the lamin triplet. While surprising at first, these results are in agreement with the approximate location of the IFA epitope on IF molecules and the recently discovered sequence homology along the rod domain between lamins A and C and IF proteins. Our results extend this relation to lamin B in spite of its unique behaviour during mitosis.

Reversible induction of actin rods in mouse C3H-2K cells by incubation in salt buffers and by treatment with non-ionic detergents

Incubating conditions which induced actin paracrystal-like intracellular structures (actin rods) were investigated by using several cell lines. We have found that an incubation of cells of a mouse fibroblastic cell line, C3H-2K, in an isotonic solution of NaCl containing 1 mM MgCl2, 1 mM CaCl2 and 10 mM MES, pH 6.5, induced disintegration of stress fibers and formation of actin rods in the cytoplasm. Actin rods were induced also by incubating in salt buffers in which Na+ of the above solution was substituted by most cations except K+ or Rb+. When the actin rod-forming cells were transferred back to DMEM containing 10% FBS, actin rods disappeared and stress fibers subsequently re-formed within 1 h at 37 degrees C. Although the induction was observed in NaCl buffer at a wide range of pH values (5.5-10), the optimal pH was 6.5. Formation of actin rods is dependent upon cellular metabolism, as it was inhibited at 4 degrees C, or by metabolic inhibitors. Incubation in NaCl buffer induced actin rods in HeLa, L, NRK, BALB/c 3T3 and Swiss 3T3 cells, but not in CEF or MEF cells. A decrease in cell volume was observed parallel with the induction of actin rods, except for CEF and MEF cells. Alterations in intracellular concentrations of Na, K or Ca were not correlated with the induction, however. Actin rods were also induced in C3H-2K cells by a brief treatment with non-ionic detergents. Tween 80 at concentrations as low as 0.003% was effective for the induction, but did not increase the passive membrane transport of p-nitrophenylphosphate. In contrast to the induction by NaCl buffer, treatment with Tween 80 induced numerous tiny actin rods at 4 degrees C, which became larger when further incubated at 37 degrees C. Double immunofluorescence staining with anti-actin antibody and anti-vinculin antibody showed that vinculin plaques remained at least in an early stage of the actin rod formation. We discuss the mechanism for the induction of actin rods based upon the present findings.

Cytoskeletal organization affects cellular responses to cytochalasins: comparison of a normal line and its transformant

The relationships between cytoskeletal network organization and cellular response to cytochalasin D (CD) in a normal rat fibroblast cell line (Hmf-n) and its spontaneous transformant (tHmf-e), with markedly different cytoskeletal phenotypes, were compared (using immunofluorescence, electron microscopy, and DNAse I assay for actin content). Hmf-n have prominent, polar stress fiber (SF) arrays terminating in vinculin adhesion plaques whereas tHmf-e, which are apolar, epithelioid cells with dense plasma membrane-associated actin networks, lack SF and adhesion plaques. Hmf-n exposed to CD become markedly retracted and dendritic, SF-derived actin aggregates form large endoplasmic masses, and discrete tabular aggregates at the distal ends of retraction processes. Prolonged exposure leads to recession of process, cellular rounding, and development of large cystic vacuoles. tHmf-e cells exposed to similar doses of CD display a diagnostically different response; retraction is less drastic, cells retain broad processes containing scattered actin aggregates in discrete foci often associated with plasma membrane, large tabular aggregates are never found and processes persist throughout long exposure, vacuolation is uncommon. The CD-induced microfilamentous aggregates in Hmf-n are composed of short, kinky filament fragments forming a felt-like skein, often aggregates contain a more ordered array of roughly parallel fragments, while those of tHmf-e are very short, kinky, randomly orientated filaments imparting a distinctly granular nature to the mass. Total actin content and the amount of actin associated with detergent-resistant cytoskeletons increase following CD exposure in both cell types. Throughout exposure to CD, the actin-associated contractile proteins tropomyosin, myosin, and alpha-actinin co-localize within the actin aggregates in both cell types. Fodrin, the protein linking cortical actin to membrane, co-localizes with actin aggregates in tHmf-e cells and most, but not all, such aggregates in Hmf-n cells, consistent with their stress fiber derivation. Vinculin is lost from the tabular aggregates at the distal ends of retraction processes in Hmf-n cells concomitant with the fragmentation and contraction of SF. The aborized processes in both cells types contain strikingly similar axial cores of bundled vimentin filaments associated with passively compressed microtubules. The characteristic CD-induced distribution of actin filament aggregates and redistribution of vimentin in these cell types also occur when cells are allowed to respread from the rounded state in the presence of CD.

Effects of bunaftine on morphology, microfilament integrity, and mitotic activity in cultured human fibroblasts and HeLa cells

Human fibroblasts and HeLa cells were treated with bunaftine (N-butyl-N-/2-(diethylamino)ethyl/-1-naphthalenecarboxamide ) in vitro. At concentrations of 0.5-2.0 mM, the drug caused contraction and rounding of the cells with loss of microvilli-like processes. Aggregates of dense, partly granular, partly fibrillar material formed in the cytoplasm and the rough endoplasmic reticulum became vesiculated. Immunofluorescence microscopy with DNase I and anti-DNase I demonstrated that bundles of actin filaments were disrupted, forming rings, coils, and granules. Filaments stained with antibodies to vimentin (fibroblasts) and prekeratin (HeLa cells) showed less characteristic rearrangements, probably related to the rounding up of the cells. 0.4 mM bunaftine increased and 0.8-1.0 mM markedly decreased the percentage of mitotic cells, without accumulation of cells in any particular stage of mitosis. The drug may arrest the cell cycle at some point before mitosis; it may have a critical concentration above which the arrest becomes permanent. These results suggest that bunaftine interferes with the integrity of microfilament bundles in a different manner from that of cytochalasins. It does not cause any depletion of cellular ATP, indicating that its effect is not a result of inhibition of cell metabolism. It is proposed that bunaftine may be used a complement to cytochalasins in studies of the microfilament system of the cell. The possible binding of bunaftine to actin or myosin and further details of its mechanism of action remain to be elucidated.

Vinblastine-induced autophagocytosis: the effect of disorganization of microfilaments by cytochalasin B

The effects of disorganization of cellular microfilaments by cytochalasin B on vinblastine-induced autophagocytosis was studied in Ehrlich ascites tumor cells in vitro. Incubation with vinblastine induced a formation of autophagic vacuoles in the cytoplasm. The disorganization of microfilaments by cytochalasin B failed to inhibit vinblastine-induced autophagocytosis. Incubation with cytochalasin B alone induced a rapid formation of blebs on the cell surface. These contained cytoplasmic organelles and were connected by a narrow shaft to the main part of the cell. Thin subcortical microfilaments seen in the control cell cytoplasm were apparently relocated after cytochalasin B treatment and formed amorphous masses deeper in the cytoplasm. Vinblastine did not affect the formation of blebs after cytochalasin B treatment.

Actin paracrystal induction by forskolin and by db-cAMP in CHO cells

Forskolin, a hypotensive diterpine, is assumed to be a potent activator of adenylate cyclase leading to increased levels of cAMP. When this drug is used at 10(-5) M on CHO-C14 cells in culture, it induces within 15 min actin paracrystals in all cells. At this time the paracrystals are mostly situated close to the cell periphery. Electron microscopy (EM) shows structures typical of actin paracrystals. Scanning electron microscopy (SEM) reveals a reduction in surface microvilli and blebs. Identical results can be obtained by adding 1 mM db-cAMP to the culture medium directly. The paracrystals are observed within 15 min and thus represent one of the earliest ultrastructural changes so far described for reverse transformation of CHO cells by db-cAMP. The microtubular and vimentin profiles appear unchanged by forskolin treatment of CHO-K1 cells. Out of currently unknown reasons forskolin does not induce the actin transformation in several other commonly used cell lines.

Ultrastructural effects of Clostridium difficile toxin B on smooth muscle cells and fibroblasts

The mechanism by which Clostridium difficile toxin B causes cells in culture to round was investigated. Cultured human lung fibroblasts and rabbit aortic smooth muscle cells were treated with partially purified or purified toxin B and monitored by light and transmission electron microscopy (TEM). Both preparations caused progressive cell rounding which correlated with disorganization of actin-containing myofilament bundles. Thin myofilaments became fragmented and finally disappeared (after 24 h) and dense bodies became more prominent, while all other organelles appeared unaffected.

Altered cell spreading in cytochalasin B: a possible role for intermediate filaments

Trypsinized chicken embryo dermal fibroblasts plated in the presence of cytochalasin B (CB) quickly attached to the substrate and within 24 h obtained an arborized morphology. This morphology is the result of the pushing out of pseudopodial processes along the substrate from the round central cell body. There were no microfilament bundles in the processes of these cells plated in the presence of CB; however, the processes were packed with highly oriented, parallel-aligned intermediate filaments. Only a few scattered microtubules were seen in these processes. These results demonstrated that in CB, cells are capable of a form of movement, i.e., the extension of pseudopodial processes, without the presence of the microfilament structures usually associated with extensions of the cytoplasm and pseudopodial movements. We also found that arborization did not depend on fibronectin since cells plated in CB did not have fibronectin fibers associated with the processes. Chicken fibroblasts transformed with tsLA24A, a Rous sarcoma virus which is temperature sensitive for pp60src, formed arborized cells with properties similar to those of uninfected fibroblasts when plated in the presence of CB at the nonpermissive temperature (41 degrees C). At the permissive temperature for transformation (36 degrees C), the cells attached to the substrate but remained round. These round cells were not only deficient in microfilament bundles but also lacked the highly organized intermediate filaments found in the processes of the arborized cells at 41 degrees C. Although both microfilament bundles and the fibronectin matrix were decreased after transformation with Rous sarcoma virus, neither was involved in the formation of processes in normal cells plated in CB. Therefore, the inability of the transformed cells to form or maintain processes in CB must be the result of another structural alteration in the transformed cells, such as that of the intermediate filaments.

Altered cell spreading in cytochalasin B: a possible role for intermediate filaments

Trypsinized chicken embryo dermal fibroblasts plated in the presence of cytochalasin B (CB) quickly attached to the substrate and within 24 h obtained an arborized morphology. This morphology is the result of the pushing out of pseudopodial processes along the substrate from the round central cell body. There were no microfilament bundles in the processes of these cells plated in the presence of CB; however, the processes were packed with highly oriented, parallel-aligned intermediate filaments. Only a few scattered microtubules were seen in these processes. These results demonstrated that in CB, cells are capable of a form of movement, i.e., the extension of pseudopodial processes, without the presence of the microfilament structures usually associated with extensions of the cytoplasm and pseudopodial movements. We also found that arborization did not depend on fibronectin since cells plated in CB did not have fibronectin fibers associated with the processes. Chicken fibroblasts transformed with tsLA24A, a Rous sarcoma virus which is temperature sensitive for pp60src, formed arborized cells with properties similar to those of uninfected fibroblasts when plated in the presence of CB at the nonpermissive temperature (41 degrees C). At the permissive temperature for transformation (36 degrees C), the cells attached to the substrate but remained round. These round cells were not only deficient in microfilament bundles but also lacked the highly organized intermediate filaments found in the processes of the arborized cells at 41 degrees C. Although both microfilament bundles and the fibronectin matrix were decreased after transformation with Rous sarcoma virus, neither was involved in the formation of processes in normal cells plated in CB. Therefore, the inability of the transformed cells to form or maintain processes in CB must be the result of another structural alteration in the transformed cells, such as that of the intermediate filaments.

The response of chicken embryo dermal fibroblasts to cytochalasin B is altered by Rous sarcoma virus-induced cell transformation

The drug cytochalasin B (CB), which disrupts the cellular microfilament network, allows the identification of as yet unclassified structural differences between normal and Rous sarcoma virus-transformed chicken embryo fibroblasts. When exposed to CB, normal chick fibroblasts attain an arborized or dendritic morphology. This results as the cytoplasm collapses upon the remaining structural and adhesive components of the cell. Rous sarcoma virus-transformed cells did not form or maintain these dendritic-like processes in the presence of CB and, as a result, rounded up but still remained attached to the substrate. With a temperature-sensitive mutant of Rous sarcoma virus, LA24A, it was possible to show that these effects are completely reversible and dependent on the expression of pp60src. The cytoskeleton in these CB-treated cells was examined by both immunofluorescence and electron microscopy. After exposure to CB, the microfilaments were found to be disrupted similarly throughout both the transformed and the nontransformed cells. In the nontransformed cells arborized by exposure to CB, the extended processes were found to contain intermediate filaments in an unusually high concentration and degree of organization. The distribution of these filaments in the central body of the arborized cells was random. This lower concentration and random distribution was similar to that seen throughout the transformed cells rounded up by exposure to CB. The failure of these transformed cells to arborize in CB indicates that the structural component(s) which is necessary for the formation or maintenance or both of the arborized state is altered by the expression of pp60src.

The response of chicken embryo dermal fibroblasts to cytochalasin B is altered by Rous sarcoma virus-induced cell transformation

The drug cytochalasin B (CB), which disrupts the cellular microfilament network, allows the identification of as yet unclassified structural differences between normal and Rous sarcoma virus-transformed chicken embryo fibroblasts. When exposed to CB, normal chick fibroblasts attain an arborized or dendritic morphology. This results as the cytoplasm collapses upon the remaining structural and adhesive components of the cell. Rous sarcoma virus-transformed cells did not form or maintain these dendritic-like processes in the presence of CB and, as a result, rounded up but still remained attached to the substrate. With a temperature-sensitive mutant of Rous sarcoma virus, LA24A, it was possible to show that these effects are completely reversible and dependent on the expression of pp60src. The cytoskeleton in these CB-treated cells was examined by both immunofluorescence and electron microscopy. After exposure to CB, the microfilaments were found to be disrupted similarly throughout both the transformed and the nontransformed cells. In the nontransformed cells arborized by exposure to CB, the extended processes were found to contain intermediate filaments in an unusually high concentration and degree of organization. The distribution of these filaments in the central body of the arborized cells was random. This lower concentration and random distribution was similar to that seen throughout the transformed cells rounded up by exposure to CB. The failure of these transformed cells to arborize in CB indicates that the structural component(s) which is necessary for the formation or maintenance or both of the arborized state is altered by the expression of pp60src.

Correlation between effects of 24 different cytochalasins on cellular structures and cellular events and those on actin in vitro

To compare the effects of cytochalasins on the cellular level with those on the molecular level, 24 cytochalasins, 20 natural compounds and 4 derivatives, were used. The following effects were tested for each of 24 cytochalasins; (a) four high dose (2-20 muM) effects on the cellular level: rounding up of fibroblastic cells, contraction of actin cables, formation of hairy filaments containing actin, and inhibition of lymphocyte capping; (b) a low dose (0.2-2 muM) effect: inhibition of membrane ruffling; and (c) two in vitro effects: an inhibition of actin filament elongation (the high affinity effect [low dose effect] in vitro) and an effect on viscosity of actin filaments(the low affinity effect [high dose effect] in vitro). These results indicated that there are almost the same hierarchic orders of relative effectiveness of different cytochalasins between low and high dose effects and between cellular and molecular effects. From the data obtained with the 24 cytochalasins, we have calculated correlation coefficients of 0.87 and 0.79 between an effect in vivo, inhibition of capping, and an effect in vitro, inhibition of actin filament elongation, as well as between inhibition of capping and another effect in vitro, effect on viscosity of actin filaments, respectively. Furthermore, a correlation coefficient between the high affinity effect and the low affinity effect determined in vitro was calculated to be 0.90 from the data obtained in this study. The strong positive correlation among low and high dose effects in vivo and those in vitro suggests that most of the effects caused by a cytochalasin, irrespective of doses or affected phenomena, might be attributed to the interaction between the drug and the common target protein, actin. In the course of the immunofluorescence microscope study on cytochalasin-treated cells using actin antibody, we have found that aspochalasin D, a 10-isopropylcytochalasin, strongly induced the formation of rodlets containing actin in the cytoplasm of the treated fibroblasts. In contrast, the other cytochalasins, including cytochalasin B, cytochalasin C, cytochalasin D, and cytochalasin H, were found to induce the formation of nuclear rodlets. Both cytoplasmic and nuclear rodlets found in the cytochalasin-treated cells were similar in ultrastructures to those induced by 5 to 10 percent (vol/vol) dimethyl sulfoxide in the same type of cells.

Chemotactic factor receptor modulation and cytoskeletal structures

The microfilament-disrupting agents cytochalasins A, B, and D were shown to impair the binding of the chemotactic factors [3H]formylmethionylleucylphenylalanine and 125 I-labeled crystal-induced chemotactic factor to their neutrophil receptor. Scatchard plot analysis revealed a decrease of the available binding sites in the cytochalasin B-treated cells. Cytochalasin B showed the same inhibitory profile on intact cells and on a membrane-rich preparation, suggesting that the effect was not dependent on an intact microfilament apparatus. The microtubule modifiers colchicine and vinblastine had no effect on the binding of the chemotactic factor to its cell receptors

Stereo immunofluorescence microscopy: I. Three-dimensional arrangement of microfilaments, microtubules and tonofilaments

An easy manipulation of the commercial fluorescence microscope allows stereo pairs of pictures to be taken, which when examined with a stereo viewer, give a strong three-dimensional impression. The procedure is described in detail. Its use allows the documentation by immunofluorescence microscopy of the three-dimensional display and organization of microfilament bundles, microtubules and tonofilaments in some well characterized tissue culture cell lines.

Effects of microfilament-active drugs, phalloidin and the cytochalasins A and B, on exocytosis in mast cells evoked by 48/80 or A23187

Rat peritoneal mast cells were used as a model system to study the effect, on exocytosis, of three agents known to interact with microfilaments. Mast cell secretion was evaluated by fluorimetric assay of histamine and by ruthenium red staining, the latter method allowing a direct visualization and quantitation of exocytosis at the light microscopic level. Phalloidin, in concentrations up to 300 microgram/ml, was without effect on either spontaneous or 48/80-evoked secretion, even after cells were exposed to the drug for 28 h. The failure of even high doses of phalloidin to influence cellular morphology and exocytosis in the mast cell may reflect the absence of a specific membrane receptor. Cytochalasin B was likewise without effect on the response to 48/80 in normally respiring cells; but inhibited this response in the presence of Antimycin A. This inhibitory effect probably reflects the ability of cytochalasin B to block glucose transport. In normally respiring cells, neither phalloidin nor cytochalasin B affected the active expulsion of granules from exocytotic pits. Cytochalasin A, without concomitant treatment with Antimycin A, completely inhibited secretion in response to both 48/80 and A23187, and did so in low concentration. Whether this striking inhibitory effect results from an interaction with microfilaments is uncertain for the inhibition could be mimicked by nonpenetrating thiol-oxidizing agents and prevented by impermeant thiol-protecting agents suggesting that cytochalasin A may inhibit histamine release by thiol-oxidation at the cell surface. Possible surface sulfhydryls are important for membrane rearrangements accompanying exocytosis.