Identification of a short sequence essential for actin binding by Dictyostelium ABP-120

Tryptic digestion of ABP-120, an actin cross-linking protein from Dictyostelium discoideum, generates a ladder of peptides differing in molecular mass by 13,000 daltons, indicating a structural repeat within the molecule. A number of peptides bind actin with the smallest having a molecular mass of 17,000 daltons (T17). Our sedimentation assays also show that a peptide of 14,000 daltons does not bind actin. Using the full-length cDNA sequence (Noegel, A., Rapp, S., Lottspeich, F., Schleicher, M., and Stewart, M. (1989) J. Cell Biol. 109, 607-618) and protein sequencing techniques, we have determined that T17 begins at residue 89 while T14 begins at residue 116. Therefore we have localized 27 amino acids which are essential for actin binding activity. This region is at the end of the molecule, distal from the repetitive beta-sheet region predicted from the cDNA sequence, and displays high sequence identity with regions in the N termini of ABP/filamin, dystrophin, beta-spectrin, and alpha-actinin.     

Genetic deletion of ABP-120 alters the three-dimensional organization of actin filaments in Dictyostelium pseudopods

This study extends the observations on the defects in pseudopod formation of ABP-120+ and ABP-120- cells by a detailed morphological and biochemical analysis of the actin based cytoskeleton. Both ABP-120+ and ABP-120- cells polymerize the same amount of F-actin in response to stimulation with cAMP. However, unlike ABP-120+ cells, ABP-120- cells do not incorporate actin into the Triton X-100-insoluble cytoskeleton at 30-50 s, the time when ABP-120 is incorporated into the cytoskeleton and when pseudopods are extended after cAMP stimulation in wild-type cells. By confocal and electron microscopy, pseudopods extended by ABP- 120- cells are not as large or thick as those produced by ABP-120+ cells and in the electron microscope, an altered filament network is found in pseudopods of ABP-120- cells when compared to pseudopods of ABP-120+ cells. The actin filaments found in areas of pseudopods in ABP- 120+ cells either before or after stimulation were long, straight, and arranged into space filling orthogonal networks. Protrusions of ABP-120- cells are less three-dimensional, denser, and filled with multiple foci of aggregated filaments consistent with collapse of the filament network due to the absence of ABP-120-mediated cross-linking activity. The different organization of actin filaments may account for the diminished size of protrusions observed in living and fixed ABP-120- cells compared to ABP-120+ cells and is consistent with the role of ABP- 120 in regulating pseudopod extension through its cross-linking of actin filaments.     

Re-expression of ABP-120 rescues cytoskeletal, motility, and phagocytosis defects of ABP-120- Dictyostelium mutants.

The actin binding protein ABP-120 has been proposed to cross-link actin filaments in nascent pseudopods, in a step required for normal pseudopod extension in motile Dictyostelium amoebae. To test this hypothesis, cell lines that lack ABP-120 were created independently either by chemical mutagenesis or homologous recombination. Different phenotypes were reported in these two studies. The chemical mutant shows only a subtle defect in actin cross-linking, while the homologous recombinant mutants show profound defects in actin cross-linking, cytoskeletal structure, pseudopod number and size, cell motility and chemotaxis and, as shown here, phagocytosis. To resolve the controversy as to what the ABP-120- phenotype is, ABP-120 was re-expressed in an ABP-120- cell line created by homologous recombination. Two independently "rescued" cell lines that express wild-type levels of ABP-120 were analyzed. In both rescued cell lines, actin incorporation into the cytoskeleton, pseudopod formation, cell morphology, instantaneous velocity, phagocytosis, and chemotaxis were restored to wild-type levels. There is no alteration in the expression levels of several related actin binding proteins in either the original ABP-120- cell line or in the rescued cell lines, leading to the conclusion that neither the aberrant phenotype observed in ABP-120- cells nor the normal phenotype reasserted in rescued cells can be attributed to alterations in the levels of other abundant and related actin binding proteins. Re-expression of ABP-120 in ABP-120- cells reestablishes normal structural and behavioral parameters, demonstrating that the severity and properties of the structural and behavioral defects of ABP-120- cell lines produced by homologous recombination are the direct result of the absence of ABP-120.     

Cytoimmunofluorescent localization of severin in Dictyostelium amoebae

Severin is a 40-kDa Ca2+-activated protein from Dictyostelium that rapidly fragments and disassembles actin filaments in vitro (S.S. Brown, K. Yamamoto, and J.A. Spudich, J. Cell Biol. 93, 205-210, 1982; and K. Yamamoto, J.D. Pardee, J. Reidler, L. Stryer, and J.A. Spudich. J. Cell Biol. 95, 711-719, 1982). To determine if severin is colocalized with actin filaments in vivo, we have used the agar-overlay technique of S. Yumura, H. Mori, and Y. Fukui (J. Cell Biol. 99, 894-899, 1984) to examine the intracellular locations of severin and F-actin in vegetative Dictyostelium amoebae. In rounded cells taken from suspension culture severin colocalized with F-actin at cortical edges while maintaining an endoplasmic presence. Both severin and F-actin were present throughout nascent pseudopods of motile cells, while severin appeared concentrated at the leading edge of fully developed pseudopods. Amoebae feeding on a bacterial lawn formed large phagocytic vesicles that were surrounded by an extensive cell cortex rich in severin. Streaming cells entering aggregates during the Dictyostelium developmental cycle showed severin staining throughout the cytoplasm with F-actin at the cortex. The preferential localization of severin in cytoplasmic regions of vegetative cells undergoing extensive actin cytoskeletal rearrangement prompts consideration of a role for severin-mediated disruption of actin filament networks during pseudopod extension and phagocytosis.     

Electron microscopic mapping of monoclonal antibodies on the tail region of Dictyostelium myosin

The binding sites of five monoclonal antibodies against myosin of Dictyostelium discoideum have been mapped. These antibodies bind to the tail region of the myosin molecule. By rotary shadowing, images of myosin-antibody complexes were obtained in which the mean distance of the midpoint of an antibody molecule from the myosin heads was localized with a precision better than 2 nm (90% confidence limit). Other quantitative data extracted from electron micrographs provided information on the stoichiometry of antibody-myosin interaction. Certain antibodies interacted with myosin molecules only at a ratio of 1:1. Other antibodies formed complexes of two molecules bound to homologous sites on a double-stranded myosin tail. Affinities were estimated and the abilities of different antibodies to cross-connect two myosin molecules were evaluated.     

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.     

Release of myosin II from the membrane-cytoskeleton of Dictyostelium discoideum mediated by heavy-chain phosphorylation at the foci within the cortical actin network

Membrane-cytoskeletons were prepared from Dictyostelium amebas, and networks of actin and myosin II filaments were visualized on the exposed cytoplasmic surfaces of the cell membranes by fluorescence staining (Yumura, S., and T. Kitanishi-Yumura. 1990. Cell Struct. Funct. 15:355-364). Addition of ATP caused contraction of the cytoskeleton with aggregation of part of actin into several foci within the network, but most of myosin II was released via the foci. However, in the presence of 10 mM MgCl2, which stabilized myosin II filaments, myosin II remained at the foci. Ultrastructural examination revealed that, after contraction, only traces of monomeric myosin II remained at the foci. By contrast, myosin II filaments remained in the foci in the presence of 10 mM MgCl2. These observations suggest that myosin II was released not in a filamentous form but in a monomeric form. Using [gamma 32P]ATP, we found that the heavy chains of myosin II released from membrane-cytoskeletons were phosphorylated, and this phosphorylation resulted in disassembly of myosin filaments. Using ITP (a substrate for myosin II ATPase) and/or ATP gamma S (a substrate for myosin II heavy-chain kinase [MHCK]), we demonstrated that phosphorylation of myosin heavy chains occurred at the foci within the actin network, a result that suggests that MHCK was localized at the foci. These results together indicate that, during contraction, the heavy chains of myosin II that have moved toward the foci within the actin network are phosphorylated by a specific MHCK, with the resultant disassembly of filaments which are finally released from membrane-cytoskeletons. This series of reactions could represent the mechanism for the relocation of myosin II from the cortical region to the endoplasm.     

Identification and cellular localization of the actin-binding protein ABP-120 from Entamoeba histolytica

Several actin-binding proteins participate in the morphological changes that occur during amoeboid movement. The gene encoding one of these proteins, the gelation factor ABP-120, was identified and characterized from trophozoites of Entamoeba histolytica . The sequence contains 2574 nucleotides, with an open reading frame of 858 amino acids, giving a protein of 93 kDa belonging to the spectrin family. The N-terminal domain of ABP-120 from E. histolytica revealed a consensus site for actin binding homologous to the actin-binding sites of ABP-120 of Dictyostelium discoideum , α-actinin and spectrin. Analysis of the central domain revealed the presence of four repeats of a 73-amino-acid motif constituting 31% of the protein. In addition, a stretch of 105 amino acids was highly divergent when compared with the C-terminal domain of D. discoideum ABP-120. This sequence showed short motifs that are homologous to microtubule-binding domains. We found that ABP-120 from E. histolytica binds to F-actin. In addition, upon motility of the parasite, this protein localized in the pseudopod and the uroid region, implying a role for ABP-120 in movement and capping of surface receptors in E. histolytica .     

Localization of actin and myosin for the study of ameboid movement in Dictyostelium using improved immunofluorescence

The distribution of actin and myosin in Dictyostelium amebae at different developmental stages was studied by improved immunofluorescence ("agar-overlay" technique). Both were localized at the cortical region of amebae in all early developmental stages. In amebae with polarized morphology, bright fluorescence with antiactin was seen in the anterior pseudopode. The cortex in the posterior end was also stained with antiactin. On the other hand, very specific crescent-shaped staining with antimyosin was seen at the posterior cortex. In cells in contact with each other, actin was concentrated at the contact region, whereas myosin was localized specifically in the cortex on the other side of the contact region. At the aggregation stage, when monopodial amebae migrate forming streams, actin staining was seen all around the cell periphery, with intense fluorescence in the anterior pseudopode. On the other hand, specific staining of myosin was seen only at the posterior cortex. The cleavage furrow of cells performing cytokinesis displayed distinct myosin staining, and this staining represented the filamentous structure aligned in parallel to the axis of constriction. These findings indicate that myosin staining reflects the portion of the cell cortex where contraction occurs and the motive force of ameboid movement is generated at the posterior cortex of a migrating cell.     

Functional characterization of vertebrate nonmuscle myosin IIB isoforms using Dictyostelium chimeric myosin II

The alternatively spliced isoform of nonmuscle myosin II heavy chain B (MHC-IIB) with an insert of 21 amino acids in the actin-binding surface loop (loop 2), MHC-IIB(B2), is expressed specifically in the central nervous system of vertebrates. To examine the role of the B2 insert in the motor activity of the myosin II molecule, we expressed chimeric myosin heavy chain molecules using the Dictyostelium myosin II heavy chain as the backbone. We replaced the Dictyostelium native loop 2 with either the noninserted form of loop 2 from human MHC-IIB or the B2-inserted form of loop 2 from human MHC-IIB(B2). The transformant Dictyostelium cells expressing only the B2-inserted chimeric myosin formed unusual fruiting bodies. We then assessed the function of chimeric proteins, using an in vitro motility assay and by measuring ATPase activities and binding to F-actin. We demonstrate that the insertion of the B2 sequence reduces the motor activity of Dictyostelium myosin II, with reduction of the maximal actin-activated ATPase activity and a decrease in the affinity for actin. In addition, we demonstrate that the native loop 2 sequence of Dictyostelium myosin II is required for the regulation of the actin-activated ATPase activity by phosphorylation of the regulatory light chain.     

Immunochemical analysis of the supramolecular structure of myosin in contractile cytoskeletons of Dictyostelium amoebae

A collection of monoclonal antibodies against Dictyostelium myosin was screened to identify an antibody that could distinguish monomeric from polymeric myosin. An antibody was found that reacted only with monomeric myosin, provided that the antigen-antibody reaction was carried out in solution. This antibody was used in competition radioimmunoassays to probe the supramolecular structure of myosin in Triton-extracted cell models, or cytoskeletons, of Dictyostelium amoebae. The competition assay showed that, as isolated, cytoskeletal myosin was entirely filamentous, but could be converted to monomeric form by increasing the ionic strength of the surrounding buffer. As monomer, it remained associated with the cytoskeleton and could be cycled back to filament form by a second change of buffer. The ability of cytoskeletons to carry out ATP-dependent contraction was examined as a function of the assembly state of myosin. The results suggested that filamentous myosin is responsible for contraction of the cortical filament matrix.     

The regulation of myosin II in Dictyostelium

Dictyostelium conventional myosin (myosin II) is an abundant protein that plays a role in various cellular processes such as cytokinesis, cell protrusion and development. This review will focus on the signal transduction pathways that regulate myosin II during cell movement. Myosin II appears to have two modes of action in Dictyostelium: local stabilization of the cytoskeleton by myosin filament association to the actin meshwork (structural mode) and force generation by contraction of actin filaments (motor mode). Some processes, such as cell movement under restrictive environment, require only the structural mode of myosin. However, cytokinesis in suspension and uropod retraction depend on motor activity as well. Myosin II can self-assemble into bipolar filaments. The formation of these filaments is negatively regulated by heavy chain phosphorylation through the action of a set of novel alpha kinases and is relatively well understood. However, only recently it has become clear that the formation of bipolar filaments and their translocation to the cortex are separate events. Translocation depends on filamentous actin, and is regulated by a cGMP pathway and possibly also by the cAMP phosphodiesterase RegA and the p21-activated kinase PAKa. Myosin motor activity is regulated by phosphorylation of the regulatory light chain through myosin light chain kinase A. Unlike conventional light chain kinases, this enzyme is not regulated by calcium but is activated by cGMP-induced phosphorylation via an upstream kinase and subsequent autophosphorylation.     

Compartmentalization and actin binding properties of ABP-50: the elongation factor-1 alpha of Dictyostelium.

ABP-50 is the elongation factor-1 alpha (EF-1 alpha) of Dictyostelium discoideum (Yang et al.: Nature 347:494-496, 1990). ABP-50 is also an actin filament binding and bundling protein (Demma et al.: J. Biol. Chem. 265:2286-2291, 1990). In the present study we have investigated the compartmentalization of ABP-50 in both resting and stimulated cells. Immunofluorescence microscopy shows that in addition to being colocalized with F-actin in surface extensions in unstimulated cells, ABP-50 exhibits a diffuse distribution throughout the cytosol. Upon addition of cAMP, a chemoattractant, ABP-50 becomes localized in the filopodia that are extended as a response to stimulation. Quantification of ABP-50 in Triton-insoluble and -soluble fractions of resting cells indicates that 10% of the total ABP-50 is recovered in the Triton cytoskeleton, while the remainder is in the soluble cytosolic fraction. Stimulation with cAMP increases the incorporation of ABP-50 into the Triton cytoskeleton. The peak of incorporation of ABP-50 at 90 sec is concomitant with filopod extension. Immunoprecipitation of the cytosolic ABP-50 from unstimulated cells using affinity-purified polyclonal anti ABP-50 results in the coprecipitation of non-filamentous actin with ABP-50. Purified ABP-50 binds to G-actin with a Kd of approximately 0.09 microM. The interaction between ABP-50 and G-actin is inhibited by GTP but not by GDP, while the bundling of F-actin by ABP-50 is unaffected by guanine nucleotides. We conclude that a significant amount of ABP-50 is bound to either G- or F-actin in vivo and that the interaction between ABP-50 and F-actin in the cytoskeleton is regulated by chemotactic stimulation.     

Regulation of Dictyostelium myosin I and II

Dictyostelium expresses 12 different myosins, including seven single-headed myosins I and one conventional two-headed myosin II. In this review we focus on the signaling pathways that regulate Dictyostelium myosin I and myosin II. Activation of myosin I is catalyzed by a Cdc42/Rac-stimulated myosin I heavy chain kinase that is a member of the p21-activated kinase (PAK) family. Evidence that myosin I is linked to the Arp2/3 complex suggests that pathways that regulate myosin I may also influence actin filament assembly. Myosin II activity is stimulated by a cGMP-activated myosin light chain kinase and inhibited by myosin heavy chain kinases (MHCKs) that block bipolar filament assembly. Known MHCKs include MHCK A and MHCK B, which have a novel type of kinase catalytic domain joined to a WD repeat domain, and MHC-protein kinase C (PKC), which contains both diacylglycerol kinase and PKC-related protein kinase catalytic domains. A Dictyostelium PAK (PAKa) acts indirectly to promote myosin II filament formation, suggesting that the MHCKs may be indirectly regulated by Rac GTPases.     

Colocalization of F-actin and 34-kilodalton actin bundling protein in Dictyostelium amoebae and cultured fibroblasts

The Ca2+-sensitive actin-binding protein isolated from Dictyostelium discoideum, 30,000-D protein (Fechheimer and Taylor: J. Biol. Chem. 259:4514-4520, 1984;) has recently been localized in filipodia of substrate-adhered amoebae (Fechheimer: J. Cell Biol. 104:1539-1551, 1987). We have determined that this protein has a Mr of 34,000 daltons and is strictly colocalized with actin filaments in both substrate-attached Dictyostelium amoebae and cultured fibroblasts. 3T3 fibroblasts, as well as normal and virally transformed rat kidney fibroblasts (NRK) contain a 34-kilodalton (kD) protein that cross-reacts specifically with antibody to the Dictyostelium bundling protein. Mammalian 34-kD protein is colocalized with F-actin in stress fibers and the cortical cytoskeleton in substrate-adhered fibroblasts. In substrate-adhered vegetative Dictyostelium, F-actin and 34-kD protein are concentrated in regions of the cell cortex exhibiting filipodia and membrane ridges. Multiple filipodia formed after exposure to the chemoattractant folic acid stain intensely for 34-kD protein, implying participation in the assembly of actin bundles during filipod formation. The cortex of pseudopodia also contained high concentrations of bundling protein, but pseudopod interiors did not. In contrast to vegetative Dictyostelium, F-actin and 34-kD protein were not colocalized in cells that had progressed through the developmental cycle. In fruiting bodies, 34-kD protein was detected by immunofluorescence microscopy only in prespore cells, while F-actin appeared in stalk cells and spores.     

The mechanism of the reverse recovery step, phosphate release, and actin activation of Dictyostelium myosin II

The rate-limiting step of the myosin basal ATPase (i.e. in absence of actin) is assumed to be a post-hydrolysis swinging of the lever arm (reverse recovery step), that limits the subsequent rapid product release steps. However, direct experimental evidence for this assignment is lacking. To investigate the binding and the release of ADP and phosphate independently from the lever arm motion, two single tryptophan-containing motor domains of Dictyostelium myosin II were used. The single tryptophans of the W129+ and W501+ constructs are located at the entrance of the nucleotide binding pocket and near the lever arm, respectively. Kinetic experiments show that the rate-limiting step in the basal ATPase cycle is indeed the reverse recovery step, which is a slow equilibrium step (k(forward) = 0.05 s(-1), k(reverse) = 0.15 s(-1)) that precedes the phosphate release step. Actin directly activates the reverse recovery step, which becomes practically irreversible in the actin-bound form, triggering the power stroke. Even at low actin concentrations the power stroke occurs in the actin-attached states despite the low actin affinity of myosin in the pre-power stroke conformation.     

Immunoelectron microscopic studies of the ultrastructure of myosin filaments in Dictyostelium discoideum

We have examined the characteristics of myosin in situ in Dictyostelium amoebae. By an improved immunofluorescence method, we previously found rod-like structures that contain myosin, which we call "myosin rods", in amoebae (Yumura. S., and Fukui, Y. (1985) Nature, 314: 194-196). Although we prepared samples for electron microscopy using conventional chemical fixation to clarify the ultrastructure of the myosin rods, we could not find any filamentous structures similar to myosin thick filaments. Therefore, we examined the effects of chemical fixatives on the myosin rods in situ by immunofluorescence staining. When cells were fixed in more than 0.05% glutaraldehyde or more than 1% osmium tetroxide at 4 degrees C, the myosin rods disappeared. These effects did not result from loss of the antigenicity, because a monoclonal myosin-specific antibody was able to react with synthetic myosin filaments treated with 0.5% glutaraldehyde or 2% osmium tetroxide. Cells fixed by the procedure used for immunofluorescence staining were post-fixed with permissible concentrations of chemical fixatives and prepared for examination by transmission electron microscopy. We found discrete filaments of about 12 nm thickness between the microfilaments. These filaments were shown to contain myosin by immunoelectron microscopy with an immunogold probe. These filaments were thinner than synthetic myosin thick filaments formed in vitro in the presence of 10 mM MgCl2, but they were similar to those formed in the presence of 2 mM MgCl2, or under nearly physiological ionic conditions. The images after immunofluorescence and immunogold labeling both suggested that these 12-nm-thick filaments in Dictyostelium amoebae were myosin filaments in situ.     

Electron microscopic immunochemical localization of actin in fibroblasts in healing skin and palate wounds of beagle dog

Wound contraction in soft tissue has been attributed to the activity of contractile fibroblasts containing actin microfilaments. Immunochemical staining at the electron microscopic level was used to demonstrate the presence of such cells in healing wounds from skin and oral mucosa. Biopsies of granulation tissue from 10 and 16 day old excision wounds in beagle palate mucoperiosteum and skin were fixed and 10 micrometer sections were treated with antiactin serum, peroxidase-anti peroxidase (PAP) and then incubated to reveal the localization of actin. Controls were prepared using non-immune serum or preabsorbed immune serum. Thin sections examined with the electron microscope revealed the presence of PAP particles associated with microfilament bundles beneath the plasma membrane and in processes of fibroblasts. Reaction was also associated with micropinocytotic vesicles at the cell surface. More reactive cells were seen in 16 day than in 10 day old wounds and there were greater numbers of these cells in skin than in oral mucoperiosteum. The results indicate that actin containing cells with the ultrastructural characteristics of contractile fibroblasts (myofibroblasts) are present in the granulation tissue of healing skin and oral mucosal wounds. Such cells may be responsible for the wound contraction observed clinically in the healing palatal mucoperiosteum.     

Electron microscopic evidence for the myosin head lever arm mechanism in hydrated myosin filaments using the gas environmental chamber

Muscle contraction results from an attachment–detachment cycle between the myosin heads extending from myosin filaments and the sites on actin filaments. The myosin head first attaches to actin together with the products of ATP hydrolysis, performs a power stroke associated with release of hydrolysis products, and detaches from actin upon binding with new ATP. The detached myosin head then hydrolyses ATP, and performs a recovery stroke to restore its initial position. The strokes have been suggested to result from rotation of the lever arm domain around the converter domain, while the catalytic domain remains rigid. To ascertain the validity of the lever arm hypothesis in muscle, we recorded ATP-induced movement at different regions within individual myosin heads in hydrated myosin filaments, using the gas environmental chamber attached to the electron microscope. The myosin head were position-marked with gold particles using three different site-directed antibodies. The amplitude of ATP-induced movement at the actin binding site in the catalytic domain was similar to that at the boundary between the catalytic and converter domains, but was definitely larger than that at the regulatory light chain in the lever arm domain. These results are consistent with the myosin head lever arm mechanism in muscle contraction if some assumptions are made.     

Studies on the organization and localization of actin and myosin in neurons

The organization of actin in mouse neuroblastoma and chicken dorsal root ganglion (DRG) nerve cells was investigated by means of a variety of electron microscope techniques. Microspikes of neuroblastoma cells contained bundles of 7- to 8-nm actin filaments which originated in the interior of the neurite. In the presence of high concentrations of Mg++ ion, filaments in these bundles became highly ordered to form paracrystals. Actin filaments, but not bundles, were observed in growth cones of DRG cells. Actin was localized in the cell body, neurites, and microspikes of both DRG and neuroblastoma nerve cells by fluorescein-labeled S1. Myosin was localized primarily in the neurites of chick DRG nerve cells with fluorescein-labeled anti-brain myosin antibody. This antibody also stained stress fibers in fibroblasts and myoblasts but did not stain muscle myofibrils.