Novel actin cytoskeleton: actin tubules

In spores of Dictyostelium discoideum three actin filaments are bundled to form a novel tubular structure and the tubules are then organized into rods. These tubular structures we will term actin tubules. Actin tubules are reconstructed from the supernatant of spore homogenates, while the usual actin filaments were bundled after incubation of supernatants from growing cells. Alpha-actinin, ABP-120 and EF-1alpha are not essential for rod formation. Cofilin is a component of the cytoplasmic rods but few cofilin molecules are included in the nuclear rods. The viability of spores lacking actin rods is very low, and the spore shape is round instead of capsular. The rods can be fragmented by pressure, indicating that the rods may be effective in absorbing physical pressure. The complex organization of actin filaments, actin tubules and rods may be required for spores to achieve complete dormancy and maintain viability.     

S-Adenosyl-L-homocysteine hydrolase is sequestered into actin rods in Dictyostelium discoideum spores.

Here we show evidence that S-adenosyl-L-homocysteine hydrolase (SAHH) is linked to the actin cytoskeleton. Actin rods formed in Dictyostelium discoideum spores during the final stage of development are structurally composed of novel bundles of actin filaments. SAHH only accumulates with actin at this stage of development in the life cycle of D. discoideum. Recently SAHH is believed to be a target for antiviral chemotherapy and the suppression of T cells. Our finding may contribute to designing novel antiviral and immunosuppressive drugs.     

Stress fibers in situ in proximal tubules of the rat kidney

Actin bundles in proximal tubules of the rat kidney were examined by immunofluorescence and confocal laser microscopy with special reference to their three-dimensional distribution and identification as stress fibers. Renal tubular segments were prepared from the fresh renal cortex by simple homogenization and centrifugation, and fixed in formaldehyde for staining with fluorescent dye-labeled phalloidin. Segments of the proximal tubules could be identified easily on the bases of their diameter, the height of epithelial cells and prominent brush borders. Confocal laser microscopy clearly demonstrated the overall distribution of actin bundles in the whole-mount proximal tubular segments. Actin bundles in the basal cytoplasm of epithelial cells were observed to run parallel to each other and at a right angle to the tubular axis. In the stereo views reconstructed from serial optical sections, the basal actin bundles appeared as straight rods with both ends tapered. They varied in length and width and extended rather short distances of not more than 10 microns. Often, two or more actin bundles were longitudinally aligned in tandem. Some bundles showed irregular bandings along their length. Each bundle was composed of tightly packed actin filaments which could be decorated with heavy meromyosin subfragment-1 to display a bi-directional arrangement within the bundle. Immunostaining of cryostat sections showed that actin bundles contained myosin and vinculin. Enzymatically isolated proximal tubules contracted upon addition of Mg-ATP. These observations collectively suggest that the actin bundles at the base of renal proximal tubule epithelial cells can be listed among the examples of stress fibers in situ.     

Actin-dependent cell elongation in teleost retinal rods: requirement for actin filament assembly

Teleost retinal rods elongate when exposed to light. Elongation is mediated by a narrow necklike region called the myoid. In the cichlid Sarotherodon mossambicus, the rod inner segment (composed of the myoid with adjacent ellipsoid) increases in length from 12 micrometers in the dark to 41 micrometers in the light. Long light-adapted myoids contain longitudinally oriented microtubules and bundles of parallel 60-A filaments that we have identified as actin by their ability to bind myosin subfragment 1. In short dark-adapted myoids, only microtubules are recognizable. Colchicine experiments reveal that light-induced rod elongation can occur in the absence of myoid microtubules. Intraocular injections of colchicine at concentrations that disrupt virtually all rod myoid microtubules do not block rod elongation. However, rod elongation is blocked by intraocular injections of cytochalasin B or cytochalasin D. The hierarchy of effectiveness of these drugs is consistent with their effectiveness in inhibiting actin assembly and in disrupting other actin-dependent motile processes. On the basis of ultrastructural observations and the results of these inhibitor studies, we propose that the forces responsible for rod elongation are dependent not on microtubules but on actin filament assembly.     

Intranuclear actin bundles induced by dimethyl sulfoxide in interphase nucleus of Dictyostelium

Electron microscopic evidence demonstrated that dimethyl sulfoxide (DMSO) induces formation of giant intranuclear microfilament bundles in the interphase nucleus of a cellular slime mold, Dictyostelium. These giant bundles are approximately giant bundles are approximately 3 micrometer long, 0.85 micrometer wide, and composed of microfilaments 6 nm in diameter. Studies in which glycerinated cells were used showed that these microfilaments bind rabbit skeletal muscle heavy meromyosin, forming typical decorated "arrowhead" structures, and that this binding can be reverted by Mg-adenosine triphosphate. These data verify that the intranuclear microfilaments are the contractile protein actin, and that DMSO affects intranuclear actin, inducing the formation of such giant bundles. The intranuclear actin bundles appear at any developmental stage in two different species of cellular slime molds after treatment with DMSO. The native form of the intranuclear actin molecules and their possible functions are discussed, and it is proposed that the contractile protein has essential functions in the cell nucleus.     

Formation of filopodia in coelomocytes: localization of fascin, a 58,000 dalton actin cross-linking protein.

Echinoderm coelomocytes or phagocytes purified in the petaloid stage will attach to a glass substrate and form large circumferential lamellIpodia. Hypotonic shock will induce quantitative transformation to a filopodial form. Differentiation of the peripheral cytoplasm begins at the cell edge, when phase dense rods composed of actin filaments start to form. These structures, which eventually form the cores of filopodia, continue to grow, lengthen and extend deeper into the cytoplasm. In the final stage, the plasma membrane retracts down around a core to form a filopodium. Antibody against a 58,000 dalton protein isolated from sea urchin egg actin gels has been used to study a rather striking redistribution of this protein in the peripheral cytoplasm of the coelomocyte during the transformation sequence. This protein is known to organize actin filaments in vitro into linear paracrystalline arrays with a distinct 11 nm banding pattern by forming cross-links between adjacent actin filaments. In the early stage of the transformation, indirect immunofluorescence indicates a random distribution of this protein in the circumferential lamellipodia. Organization is first seen at the cell edge, where fluorescent rods coincident with the phase-dense structures start to form. These rods lengthen, extend deeper into the cytoplasm and become more intensely fluorescent. After membrane retraction, cells with individual, intensely stained filopodia are visible. The known chemistry of the actin cross-linking protein (M_r = 58,000) and its redistribution during the transformation sequence are consistent with the idea that this protein functions to organize F actin into filopodial cores by cross-linking adjacent actin filaments. We have named this protein “fascin,” because it organizes actin filaments, both in vivo and in vitro, into linear arrays or fascicles. Antibody staining shows a second population of these actin cross-linking molecules localized in the perinuclear cytoplasm. In this region, fascin appears to function to maintain a stable circumnuclear cage structure which is part of the coelomocyte cytoskeleton.     

Rearrangements of actin cytoskeleton during infection with Escherichia coli O157 in macrophages

The lamina propria of the large intestine is rich in macrophages, and they might be one of the first lines of the host defense in enterohemorrhagic Escherichia coli (EHEC) O157:H7 infection. Although macrophages were infected with them, they can survive the EHEC O157 infection. We examined the structural rearrangements of the actin cytoskeleton during the microbial infection process. Macrophage actin filaments were rearranged in the following sequence; 1) disappearance of the actin filament bundles in the cytoplasm, 2) accumulation of actin filaments under the cell surface, and 3) construction of actin networks underlying the endosome membrane. Before infection, actin filaments were distributed under the cell surface and in bundles located in the macrophage cytoplasm. Within 2 min, infection caused a rapid and marked loss of the actin filament bundles that had run parallel to the long axis of the cell. Concomitant with the loss, actin filaments became more markedly distributed under the cell surface. In the formation of the endosome, new networks of actin filaments were constructed below the phagosome membrane. The networks contained a large amount of actin as well as a fodrin-like immunoreactivity. The thickness of the networks reached about 400 nm under the phagosome membrane. The actin networks disappeared again after the bacterial digestion. The results of this study showed that actin filaments undergo three major rearrangements of the actin filaments during the infection in macrophages, and suggested that the third rearrangement is mediated by actin-binding proteins, such as a fodrin-like molecules. These morphological changes in macrophages were not clear after infection with other strains of Escherichia coli.     

Roles of actin networks in peristaltic squeezing of sperm bundles in Bombyx mori

Two types of sperm are produced in the silkworm, Bombyx mori. Nucleate eupyrene sperm is an ordinary sperm that contributes to fertilization, while anucleate apyrene sperm is considered to play important roles in assisting eupyrene sperm. At the very late stage of spermatogenesis, a phenomenon called "peristaltic squeezing" occurs in both types of sperm, whereby cytoplasm of the eupyrene and nuclei of the apyrene sperm are discarded from the posterior end, forming matured sperm. In this study, rhodamine-phalloidin staining for actin was applied to sperm bundles. Before the start of peristaltic squeezing, actin filament networks are spread on the cyst cells and constrictions by the networks appear in several places of the bundles. Actin particles, which are later recognized as circlets, are localized within the bundles. Squeezing action by the networks occurs from the anterior region and transfers toward the posterior, eliminating cytoplasm together with circlets from the posterior end. It seems that actin filaments contribute to the peristaltic squeezing of the sperm bundles in Bombyx mori.     

Anisotropic nucleation growth of actin bundle: a model for determining the well-defined thickness of bundles

Biopolymers such as DNA, F-actins, and microtubules, which are highly charged, rodlike polyelectrolytes, are assembled into architectures with defined morphology and size by electrostatic interaction with multivalent cations (or polycations) in vivo and in vitro. The physical origin to determine their morphology and size is not clearly understood yet. Our results show that the actin bundle formation consists of two stages: the thickness of actin bundles is determined nearly at the initial stage, while the length of actin bundles is determined later on. It is also found that the thickness of actin bundles decreases with the increase of polycation-mediated attraction between F-actins. From these results, we propose the anisotropic nucleation-growth mechanism, in which the thickness of actin bundles is determined by critical nucleus size, whereas the length of actin bundles is determined by the concentration of free actins relative to nucleus concentration. Observing that polycations are concentrated in some sites of actin bundles, which are thought to be nucleation sites to initiate the formation of actin bundles, supports this model. This anisotropic nucleation-growth mechanism of actin bundles can be broadly applied to the self-assembly of rodlike polyelectrolytes.     

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.     

The maize actin-depolymerizing factor, ZmADF3, redistributes to the growing tip of elongating root hairs and can be induced to translocate into the nucleus with actin

The maize actin depolymerizing factor, ZmADF3, binds G-and F-actin, and increases in vitro actin dynamics. Polyclonal antibodies have been raised against ZmADF3 and these detect a single band of approximately 17 kDa in all maize tissues examined, with the exception of pollen. In the development of root hairs, the distribution of ZmADF3 is related to actin reorganization. In the early stages of hair development, ZmADF3 is distributed throughout the cytoplasm. As the hair emerges and the microfilament bundles redirect to the outgrowth there is a simultaneous redistribution of ZmADF3 which now concentrates at the tip of the emerging hair and remains in this position as elongation proceeds. These observations show that ZmADF3 localizes to a region where actin is being remodelled during tip growth. After cytochalasin D treatment which disrupts actin filaments, short rods of ZmADF3 and actin appear in the nucleus suggesting that ZmADF3 may function by guiding actin to sites of actin polymerization.     

Growth conditions control the size and order of actin bundles in vitro.

The bonding rules for actin filament bundles do not lead to a particular packing symmetry, but allow for either regular or disordered filament packing. Indeed, both hexagonal and disordered types of packing are observed in vivo. To investigate factors which control bundle order, as well as size, we examined the effect of protein concentration on the growth of actin-fascin bundles in vitro. We found that bundles require 4-8 d to achieve both maximum size and order. The largest and best ordered bundles were grown at low fascin and high actin concentrations (an initial fascin/actin ratio of 1:200). In contrast, a much larger number of poorly ordered bundles were formed at ratios of 1:25 and 1:50, and most surprisingly, no bundles were formed at 1:300 or 1:400. Based on these observations we propose a two-stage mechanism for bundle growth. The first stage is dominated by nucleation, which requires relatively high concentrations of fascin and which is therefore accompanied by rapid growth. Below some concentration threshold, nucleation ceases and bundles enter the second stage of slow growth, which continues until the supply of fascin is exhausted. By analogy with crystallization, we hypothesize that slower growth produces better order. We are able to use this mechanism to explain our observations as well as previous observations of bundle growth both in vitro and in vivo.     

Disorganization of actin bundles of ectoplasmic specialization

The degradation of ectoplasmic specialization consisting of bundles of actin sandwiched between the plasma membrane and endoplasmic reticulum of the Sertoli cell, occurs just before spermiation. For elucidation of the processes involved in this degradation, changes in fibrous actin of the rat testis were analyzed using BODIPY-phalloidin by fluorescence and electron microscopy.
Before step 17, the fluorescence of BODIPY-phalloidin was evenly distributed around the spermatid head. When the spermatids became positioned at the luminal surface, the fluorescence had condensed on the concave side of the spermatid head. At step 19, lines of fluorescence distributed at regular intervals projected at right angles from the head. Ultrastructural observation showed that the tubulobulbar complex was formed at step 19 and electron-dense material accumulated around thin tubules of the tubulobulbar complex. Immunohistochemical examination of BODIPY-phalloidin showed that the electron dense materials around the thin tubules of the tubulobulbar complex had the capacity to bind to phallotoxin. Therefore the pattern of fluorescence in the spermatid at step 19 corresponds to that of the tubulobulbar complex.
Actin bundles of the ectoplasmic specialization would thus appear to de-polymerize into actin monomers via electron dense materials around the thin tubules of the tubulobulbar complex. The tubulobulbar complex may contribute to the disorganization of actin bundles.     

Nucleus-associated actin in Amoeba proteus

The presence, spatial distribution and forms of intranuclear and nucleus-associated cytoplasmic actin were studied in Amoeba proteus with immunocytochemical approaches. Labeling with different anti-actin antibodies and staining with TRITC-phalloidin and fluorescent deoxyribonuclease I were used. We showed that actin is abundant within the nucleus as well as in the cytoplasm of A. proteus cells. According to DNase I experiments, the predominant form of intranuclear actin is G-actin which is associated with chromatin strands. Besides, unpolymerized actin was shown to participate in organization of a prominent actin layer adjacent to the outer surface of nuclear envelope. No significant amount of F-actin was found in the nucleus. At the same time, the amoeba nucleus is enclosed in a basket-like structure formed by circumnuclear actin filaments and bundles connected with global cytoplasmic actin cytoskeleton. A supposed architectural function of actin filaments was studied by treatment with actin-depolymerizing agent latrunculin A. It disassembled the circumnuclear actin system, but did not affect the intranuclear chromatin structure. The results obtained for amoeba cells support the modern concept that actin is involved in fundamental nuclear processes that have evolved in the cells of multicellular organisms.     

Changes in cytoskeletal actin patterns in the Malpighian tubules of the fleshfly,Sarcophaga bullata (Parker) (Diptera : Calliphoridae), during metamorphosis

Using the rhodamine-labelled phalloidin staining method in combination with detergent extraction, metamorphic changes in actin filament patterns were investigated in the Malpighian tubules of the fleshfly, Sarcophaga bullata (Parker) (Diptera : Calliphoridae). Metamorphosis in this organ implies a process of dedifferentiation, followed by a process of redifferentiation. During dedifferentiation, the large basal actin bundles of the primary cells disappear and the microvillar membrane surface of these cells decreases. Concomitantly, several vesicles are pinched off from infoldings of the brush border. In older pupae, the Malpighian tubules redifferentiate to give rise to adult tubules with actin patterns similar to those of larvae. During redifferentiation of the tubules, the secondary cells display a marked increase in the number of actin filaments in their protrusions. The primary cells in the distal part of the anterior Malpighian tubules of late pupae display a well-developed basal pattern of thick parallel actin bundles. In most cases, major changes in actin filament patterns are found simultaneously with major changes in cell shape, indicating a close relationship between these actin filaments and the process of cellular remodelling.     

Observation of the three-dimensional structure of actin bundles formed with polycations

Three-dimensional structures of actin bundles formed with polycations were observed by using transmission electron microtomography and atomic force microscopy. We found, for the first time, that the cross-sectional morphology of actin bundles depends on the polycation species and ionic strength, while it is insensitive to the degree of polymerization and concentration of polycation. Actin bundles formed with poly-N-[3-(dimethylamino)propyl] acrylamide methyl chloride quaternary show a ribbon-like cross-sectional morphology in low salt concentrations that changes to cylindrical cross-sectional morphology with hexagonal packing of the actin filaments in high salt concentrations. Contrastingly, actin bundles formed with poly-L-lysine show triangular cross-sectional morphology with hexagonal packing of the actin filaments. These variations in cross-sectional morphology are discussed in terms of anisotropy in the electrostatic energy barrier.     

绿色荧光蛋白基因结合鼠Talin基因蛋白标记转基因水稻未成熟花粉的微丝骨架

利用绿色荧光蛋白基因结合鼠Talin基因表达技术及水稻转基因技术,在未成熟花粉发育期(即生殖细胞在形成后从靠壁部位移向中央部位的阶段)的水稻(Oryza sativa L.)内发现了一系列前人未曾报道过的微丝骨架的形成和多变过程.在这一发育阶段,未成熟花粉内的生殖细胞呈圆形,中央部位存有一个大液泡,大量微丝在细胞的中央胞质内形成.微丝首先在营养核的核膜表面形成两个集结中心,中心内的微丝呈短粗状.尔后,中心微丝不断延长,最终在细胞中央的胞质内形成一个非常复杂的类似多个纺锤体结合在一起的网络结构.这一网络的中间部位经常包围着营养核和生殖细胞,网络的部分微丝则与存在周缘细胞质(或称周质)的微丝网络形成连接,在连接点部位则形成一些由微丝环状组成的结构.未成熟花粉中央的微丝网络可能与营养核和生殖细胞在未成熟花粉内的运动有密切关系.     

Cytoskeletal arrays in the cells of soybean root nodules: The role of actin microfilaments in the organisation of symbiosomes

Summary Within the infected cells of root nodules there is evidence of stratification and organisation of symbiosomes and other organelles. This organisation is likely to be important for the efficient exchange of nutrients and metabolites during functioning of the nodules. Using immunocytochemical labelling and confocal microscopy we have determined the organisation of cytoskeletal elements, micro tubules and actin microfilaments in soybean nodule cells, with a view to assessing their possible role in organelle distribution. Most microtubule arrays occurred in the cell cortex where they formed disorganised arrays in both uninfected and infected cells from mature nodules. In infected cells from developing nodules, parallel arrays of microtubules, transverse to the long axis of the cell, were observed. In incipient nodules, before release of rhizobia into the plant cells, the cells also had an array of microtubules which radiated from the nucleus into the cytoplasm. Three actin arrays were identified in the infected cells of mature nodules: an aster-like array which emanated from the surface of the nucleus, a cortical array which had an arrangement similar to that of the cortical microtubules, and, throughout the cytoplasm, an array of fine filaments which had a honeycomb arrangement consistent with a distribution between adjacent symbiosomes. Uninfected cells from mature nodules had only a random cortical array of actin filaments. In incipient nodules, the density of actin microfilaments associated with the nucleus and radiating through the cytoplasm was much less than that seen in mature infected cells. The cortical array of actin also differed, being composed of swirling configurations of filaments. After invasion of nodule cells by the rhizobia, the number of actin filaments emanating from the nucleus increased markedly and formed a network through the cytoplasm. Conversely, the cytoplasmic array in uninfected cells of developing nodules was identical to that in the cells of incipient nodules. The cytoplasmic network in infected cells of developing nodules is likely to be the precursor of the honeycomb array seen in mature nodule cells. We propose that this actin array plays a role in the spatial organisation of symbiosomes and that the microtubules are involved in the localisation of mitochondria and plastids at the cell periphery in the infected cells of root nodules.