Tracking down the different forms of nuclear actin

Actin is a rather uncommitted protein with a high degree of structural plasticity: it can adopt a variety of structural states, depending on the specific ionic conditions or the interaction with ligand proteins. These interactions lock actin into a distinct conformation, which specifies the oligomeric or polymeric form it can assume. The interplay between monomeric, oligomeric and polymeric forms is used by the cell to execute an enormous variety of motility processes, such as lamellipodium formation during locomotion or intracellular transport of vesicles. In these cytoplasmic events, monomeric G-actin and filamentous F-actin are the prevalent forms. However, there might be other structural states of actin in cells that have so far not received the attention they deserve. Here, we propose that specific, "unconventional" actin conformations might contribute especially to the multitude of functions executed by actin in the nucleus. We present evidence for the existence of different forms of nuclear actin, taken from studies with selected antibodies.     

Influence of botulinum C2 toxin on F-actin and N-formyl peptide receptor dynamics in human neutrophils

Stimulation of human neutrophils with the chemotactic N-formyl peptide causes production of oxygen radicals and conversion of monomeric actin (G-actin) to polymeric actin (F-actin). The effects of the binary botulinum C2 toxin on the amount of F-actin and on neutrophil cell responses were studied. Two different methods for analyzing the actin response were used in formyl peptide-stimulated cells: staining of F-actin with rhodamine-phalloidin and a transient right angle light scatter. Preincubation of neutrophils with 400 ng/ml component I and 1,600 ng/ml component II of botulinum C2 toxin for 30 min almost completely inhibited the formyl peptide-stimulated polymerization of G-actin and at the same time decreased the amount of F-actin in unstimulated neutrophils by an average of approximately 30%. Botulinum C2 toxin preincubation for 60 min destroyed approximately 75% of the F-actin in unstimulated neutrophils. Right angle light scatter analysis showed that control neutrophils exhibited the transient response characteristic of actin polymerization; however, after botulinum C2 toxin treatment, degranulation was detected. Single components of the binary botulinum C2 toxin were without effect on the actin polymerization response. Fluorescence flow cytometry and fluorospectrometric binding studies showed little alteration in N-formyl peptide binding or dissociation dynamics in the toxin-treated cells. However, endocytosis of the fluorescent N-formyl peptide ligand-receptor complex was slower but still possible in degranulating neutrophils treated with botulinum C2 toxin for 60 min. The half-time of endocytosis, estimated from initial rates, was 4 and 8 min in control and botulinum C2 toxin-treated neutrophils, respectively.     

The interaction between actin and FA fragment of diphtheria toxin

Actin protein has many other cellular functions such as movement, chemotaxis, secretion and cytodiaresis. Besides, it have structural function. Actin is a motor protein that it has an important role in the movement process of toxin in the cell. It is known that F-actin gives carriage support during the endosomal process. Actin is found in globular (G) and filamentous (F) structure in the cell. The helix of actin occurs as a result of polymerisation of monomeric G-actin molecules through sequential rowing, is called F-actin (FA). Actin interacts with a great number of cellular proteins along with cell skeleton and plasma membrane. It is also known that some bacterial toxins have ADP-ribosylation affect on actin. Diphteria toxin is the part which has the FA enzymatic activity corresponding the N-terminal section of the toxin, which inhibits the protein synthesis by ADP-ribosylating the elongation factor 2 in the presence of NAD. FA, taken into the cell by endocytosis inhibits protein synthesis by ADP-ribosyltransferase activity and breaks the cytoskeleton. In the studies both in vitro and in vivo, actin with interaction FA of diphteria toxin has been yet to be fully elucidated. The aim of this study was to determine the three dimensional structures of actin with interaction FA of diphteria toxin by the amprical methods and in paralel with the computing technology, theoretical methods have gained significant importance. In our study, actin with interaction FA of diphteria toxin has been determined as the most possible interaction area with the theoretical method; analogy modelling. This area has been closed in the presence of polypeptides and FA-actin interactions have been tested with the gel filtration chromatography techniques. As a result of the findings, we found that 15 amino acid artificial peptides (DAMYETMAQACAGNR) corresponding to 201–215 amino acid residues of FA interacts with G-actin and closes this area. Secondly, in the model formed with the analogy modelling, it appears that the most possible interaction area is between FA (tyr204) and G-actin (gly48). Results obtained from both theoretical and experimental data support the idea that the interaction occurs in this area.     

Linked regulation of motility and integrin function in activated migrating neutrophils revealed by interference in remodelling of the cytoskeleton

Neutrophils migrate rapidly by co-ordinating regulation of their beta2-integrin adhesion with turnover of filamentous F-actin. The seven-protein Arp2/3 complex regulates actin polymerisation upon activation by proteins of the WASP-family. To investigate links between actin polymerisation, adhesion, and migration, we used a novel osmotic-shock method to load neutrophils with peptides: (1). WASP-WA and Scar-WA (which incorporate the actin- and Arp2/3-binding regions of WASP and Scar1), to compete with endogenous WASP-family members; (2). proline rich motifs (PRM) from the ActA protein of L. monocytogenes or from vinculin, which bind vasodilator-stimulated phosphoprotein (VASP), a regulator of cytoskeleton assembly. In a flow system, rolling-adherent neutrophils were stimulated with formyl tri-peptide. This caused rapid immobilisation, followed by migration with increasing velocity, supported by activated beta2-integrin CD11b/CD18. Loading ActA PRM (but not vinculin PRM) caused concentration-dependent reduction in migration velocity. At the highest concentration, unstimulated neutrophils had elevated F-actin and were rigid, but could not change their F-actin content or shape upon stimulation. Scar-WA also caused marked reduction in migration rate, but WASP-WA had a lesser effect. Scar-WA did not modify activation-dependent formation of F-actin or change in shape. However, a reduction in rate of downregulation of integrin adhesion appeared to contribute to impaired migration. These studies show that interference in cytoskeletal reorganisation that follows activation in neutrophils, can impair regulation of integrin function as well as motility. They also suggest a role of the Arp2/3 complex and WASP-family in co-ordinating actin polymerisation and integrin function in migrating neutrophils.     

Computational prediction of actin–actin interaction

Actin is one of the most abundant proteins in eukaryotic cells, where it plays key roles in cell shape, motility, and regulation. Actin is found in globular (G) and filamentous (F) structure in the cell. The helix of actin occurs as a result of polymerization of monomeric G-actin molecules through sequential rowing, is called F-actin. Recently, the crystal structure of an actin dimer has been reported, which details molecular interface in F-actin. In this study, the computational prediction model of actin and actin complex has been constructed base on the atomic model structure of G-actin. To this end, a docking simulation was carried out using predictive docking tools to obtain modeled structures of the actin–actin complex. Following molecular dynamics refinement, hot spots interactions at the protein interface were identified, that were predicted to contribute substantially to the free energy of binding. These provided a detailed prediction of key amino acid interactions at the protein–protein interface. The obtained model can be used for future experimental and computational studies to draw biological and functional conclusions. Also, the identified interactions will be used for designing next studies to understand the occurrence of F-actin structure.     

The effects of sulfhydryl inhibitors and cytochalasin on the cytoplasmic and cytoskeletal actin of human neutrophils

To better understand the changes that occur in cytoplasmic actin during cell movement, we studied the effect of inhibitors of cell movement on the molecular conformation of actin and its incorporation into the Triton-insoluble cytoskeleton of human neutrophils. The sulfhydryl reactive compound N-ethylmaleimide caused an increase in cellular F-actin as measured by uptake of the F-actin specific fluorescent probe 7-nitrobenz-2-oxadiazole-phallacidin. However, N-ethylmaleimide reduced the amount of actin associated with the Triton-insoluble cytoskeleton. Dithiobisnitrobenzoic acid, a sulfhydryl reagent that does not cross cell membranes efficiently, did not alter the F-actin content of neutrophils. The effect of N-ethylmaleimide was blocked by the presence of dithiothreitol, a donor of sulfhydryl groups. N-ethylmaleimide did not affect the polymerization of actin in a cell-free system. Cytochalasin B did not alter F-actin content of neutrophils but did decrease actin in cytoskeletons of resting neutrophils. Cytochalasin inhibited the increase in F-actin initiated by the chemoattractant N-formylmethionylleucylphenylalanine. We propose that N-ethylmaleimide blocks the stabilization of G-actin in cytoplasm, interferes with the incorporation of F-actin polymer into the cytoskeleton, and depolymerizes the cytoskeleton. In contrast cytochalasin stabilizes G-actin in the presence of chemotactic peptide. These data suggest that reversible conversion of G-actin to F-actin and incorporation of F-actin into the Triton-insoluble cytoskeleton are important for neutrophil movement.     

Biophysical properties and microfilament assembly in neutrophils: modulation by cyclic AMP

The microfilament lattice, composed primarily of filamentous (F)-actin, determines in large part the mechanical (deformability) properties of neutrophils, and thus may regulate the ability of neutrophils to transit a microvascular bed. Circulating factors may stimulate the neutrophil to become rigid and therefore be retained in the capillaries. We hypothesized that cell stiffening might be attenuated by an increase in intracellular cAMP. A combination of cell filtration and cell poking (mechanical indentation) was used to measure cell deformability. Neutrophils pretreated with dibutyryl cAMP (db-cAMP) or the combination of prostaglandin E2 (PGE2, a stimulator of adenylate cyclase) and isobutylmethylxanthine (IBMX, an inhibitor of phosphodiesterase) demonstrated significant inhibition of the n-formyl-methionyl-leucyl-phenylalanine (fMLP)-inducing stiffening. The inhibition of cell stiffening was associated with an increase in intracellular cAMP as measured by enzyme-linked immunoassay (EIA) and an increase in the activity of the cAMP-dependent kinase (A-kinase). Treatment with PGE2 and IBMX also resulted in a decrease in the F-actin content of stimulated neutrophils as assayed by NBD-phallacidin staining and flow cytometry or by changes in right angle light scattering. Direct addition of cAMP to electropermeabilized neutrophils resulted in attenuation of fMLP-induced actin assembly. Neutrophils stimulated with fMLP demonstrated a rapid redistribution of F-actin from a diffuse cortical location to a peripheral ring as assessed by conventional and scanning confocal fluorescence microscopy. Pretreatment of neutrophils with the combination of IBMX and PGE2 resulted in incomplete development and fragmentation of the cortical ring. We conclude that assembly and redistribution of F-actin may be responsible for cell stiffening after exposure to stimulants and that this response was attenuated by agents that increase intracellular cAMP, by altering the amount and spatial organization of the microfilament component of the cytoskeleton.     

The quantitation of G- and F-actin in cultured cells

An improved method to quantitate the amounts of filamentous (F-actin) and monomeric (globular) actin (G-actin) in cultured cells was developed. Cells are lysed into a myosin-containing buffer and F-actin is removed by centrifugation. The pelleted F-actin is then depolymerized to G-actin in a 1 mM ATP-containing buffer for 1 h before measuring the levels of G-actin using the DNase I inhibition assay. Partitioning of G-actin in the supernatant (greater than 95%) and recovery of actin in both fractions (greater than 85%) were measured by adding [3H]actin to cultured cells. Actin in the separated fractions is stable for at least 72 h at 0 degree C. Asynchronous monolayer cultures of Chinese hamster ovary (CHO) cells contain 2.5 +/- 0.2% of the total protein as actin with 72.4 +/- 5.7% as F-actin. About 10% of this F-actin is not associated with the readily sedimented Triton-cytoskeleton. CHO cells grown in suspension contain 55.8% of the actin as F-actin; following plating about 90 min is required for these cells to flatten and for the F-actin level to reach the monolayer value of about 70%.     

Polymerization of nonfilamentous actin into microfilaments is an important process for porcine oocyte maturation and early embryo development

Actin is one of the major proteins in mammalian oocytes. Most developmental events are dependent on the normal distribution of filamentous (F-) actin. Polymerization of nonfilamentous (G-) actin into F-actin is important for both meiosis and mitosis. This study examined G- and F-actin distribution in pig oocytes and embryos by immunocytochemical staining and confocal microscopy. Actin protein was quantified by electrophoresis and immunoblotting. G-Actin was distributed in the whole cytoplasm of oocytes and embryos irrespective of their stages. F-Actin was distributed at the cortex of oocytes and embryos at all stages, at the joint of blastomeres in the embryos, in the cytoplasm around the germinal vesicle (GV), and in the perinuclear area of 2- to 4-cell-stage embryos. No differences in the amount of actin protein were found among oocytes and embryos. Oocytes cultured in medium with cytochalasin D (CD), an inhibitor of microfilament polymerization, underwent GV breakdown and reached metaphase I but did not proceed to metaphase II. Two- to 4-cell-stage embryos cultured in medium with CD did not develop to blastocysts. When GV-stage oocytes or 2- to 4-cell-stage embryos treated with CD for 6 h were re-cultured in media without CD, oocytes or embryos re-assembled actin filaments and underwent a meiotic maturation or blastocyst formation similar to that of controls. These results indicate that it is the polymerization of G-actin into F-actin, not actin protein synthesis, that is important for both meiosis and mitosis in pig oocytes and embryos.     

Actin polymerization in murine B lymphocytes is stimulated by cytochalasin D but not by anti-immunoglobulin.

One might predict that cytochalasin D, which slows polymerization of actin in solution and which inhibits actin-containing microfilament function in live B lymphocytes, would also prevent actin polymerization in these cells. However, we have used the NBD-Phallacidin flow cytometric assay for F-actin and the DNase I inhibition assay for G-actin to demonstrate that cytochalasin D (at 20 micrograms/ml and higher) stimulates actin polymerization in murine B lymphocytes within the first 30 sec of exposure. A similar response was seen in human neutrophils. Actin polymerization induced in neutrophils by chemotactic peptides has been linked to activation of the polyphosphoinositide-calcium increase-protein kinase C signal transduction pathway. As B lymphocytes also transduce signals using this pathway, we investigated whether cytochalasin D induced actin polymerization by activating this pathway. Cytochalasin D and ionomycin both stimulated a rapid increase in internal calcium (by 1 min) in the B cell which was inhibitable by EGTA, implicating calcium influx. Ionomycin also induced actin polymerization, detectable later, by 10 min. EGTA blocked the ionomycin-induced actin polymerization, but not that induced by cytochalasin D. Cytochalasin D-induced actin polymerization was not associated with detectable hydrolysis of polyphosphoinositides, nor was it inhibited by H7 (a protein kinase C inhibitor) or by HA1004 (an inhibitor of cyclic nucleotide-dependent kinases). Furthermore, anti-immunoglobulin antibodies, which stimulate B lymphocytes through the polyphosphoinositide hydrolysis-calcium increase-protein kinase C pathway, failed to induce actin polymerization in these cells. These antibodies did, however, stimulate the cells to perform activities that involve actin-containing microfilaments. Other primary activators of B lymphocytes (dextran sulfate, PMA, and LPS) and a panel of lymphokines previously shown to enhance B lymphocyte activation (IL-1, IL-2, IL-4, IL-5) were also screened in the F-actin assay and no evidence for actin polymerization was found. We conclude that the actin polymerization response to cytochalasin D in the B cell does not involve the polyphosphoinositide hydrolysis-calcium increase-protein kinase C pathway, nor does it depend on cyclic nucleotide-dependent kinases. Furthermore, our studies failed to provide any evidence that early actin polymerization occurs in murine B lymphocyte activation.     

Characterization and dynamics of cytoplasmic F-actin in higher plant endosperm cells during interphase, mitosis, and cytokinesis

We have identified an F-actin cytoskeletal network that remains throughout interphase, mitosis, and cytokinesis of higher plant endosperm cells. Fluorescent labeling was obtained using actin monoclonal antibodies and/or rhodamine-phalloidin. Video-enhanced microscopy and ultrastructural observations of immunogold-labeled preparations illustrated microfilament-microtubule co-distribution and interactions. Actin was also identified in cell crude extract with Western blotting. During interphase, microfilament and microtubule arrays formed two distinct networks that intermingled. At the onset of mitosis, when microtubules rearranged into the mitotic spindle, microfilaments were redistributed to the cell cortex, while few microfilaments remained in the spindle. During mitosis, the cortical actin network remained as an elastic cage around the mitotic apparatus and was stretched parallel to the spindle axis during poleward movement of chromosomes. This suggested the presence of dynamic cross-links that rearrange when they are submitted to slow and regular mitotic forces. At the poles, the regular network is maintained. After midanaphase, new, short microfilaments invaded the equator when interzonal vesicles were transported along the phragmoplast microtubules. Colchicine did not affect actin distribution, and cytochalasin B or D did not inhibit chromosome transport. Our data on endosperm cells suggested that plant cytoplasmic actin has an important role in the cell cortex integrity and in the structural dynamics of the poorly understood cytoplasm-mitotic spindle interface. F-actin may contribute to the regulatory mechanisms of microtubule-dependent or guided transport of vesicles during mitosis and cytokinesis in higher plant cells.     

Nitric Oxide–Induced F-Actin Disassembly Is Mediated via cGMP, cAMP, and Protein Kinase A Activation in Rat Mesangial Cells

Glomerular mesangial cells contain actin and myosin, and in analogy to vascular smooth muscle cells, they can contract and relax to regulate the glomerular filtration rate. A key molecule that determines hemodynamic properties is nitric oxide, which is produced by nitric oxide synthase isoenzymes located in individual cells of the kidney. The contractility of mesangial cells is based on the interaction of actin microfilament bundles (F-actin) with myosin. We had the notion that nitric oxide influences the shape change of mesangial cells, so we analyzed the signal transduction involved. Chemically unrelated nitric oxide donors induced F-actin dissolution, which was mediated by cGMP but was unrelated to protein kinase G activation. Actin disassembly was achieved with inhibitors of phosphodiesterase-3 and -4 or forskolin-evoked cAMP generation. We assumed that signal transmission involves activation of protein kinase A, and we went on to attenuate F-actin disassembly by protein kinase A inhibition. In conclusion, we found evidence that nitric oxide triggered F-actin dissolution via cGMP generation, inhibition of cAMP-hydrolyzing phosphodiesterase-3, and subsequent protein kinase A activation.     

Nitric oxide-induced F-actin disassembly is mediated via cGMP, cAMP, and protein kinase A activation in rat mesangial cells.

Glomerular mesangial cells contain actin and myosin, and in analogy to vascular smooth muscle cells, they can contract and relax to regulate the glomerular filtration rate. A key molecule that determines hemodynamic properties is nitric oxide, which is produced by nitric oxide synthase isoenzymes located in individual cells of the kidney. The contractility of mesangial cells is based on the interaction of actin microfilament bundles (F-actin) with myosin. We had the notion that nitric oxide influences the shape change of mesangial cells, so we analyzed the signal transduction involved. Chemically unrelated nitric oxide donors induced F-actin dissolution, which was mediated by cGMP but was unrelated to protein kinase G activation. Actin disassembly was achieved with inhibitors of phosphodiesterase-3 and -4 or forskolin-evoked cAMP generation. We assumed that signal transmission involves activation of protein kinase A, and we went on to attenuate F-actin disassembly by protein kinase A inhibition. In conclusion, we found evidence that nitric oxide triggered F-actin dissolution via cGMP generation, inhibition of cAMP-hydrolyzing phosphodiesterase-3, and subsequent protein kinase A activation.     

Microfilaments appear in boar spermatozoa during capacitation in vitro

Boar spermatozoa were incubated in a capacitation medium and examined for the presence of filamentous actin by using the fluorescent probe NBD-phallacidin. F-actin was not observed in uncapacitated sperm, but developed in most regions of the cell during the capacitation period. Fluorescent staining was most intense in the flagellum. When fresh seminal plasma was added to capacitated sperm and the sperm was further incubated, F-actin was no longer observed. In view of previous experiments which indicated that plasma membrane proteins (PMPs), including a major integral PMP, move out of the sperm head into the flagellum during capacitation and that this movement is inhibited by the microfilament poison cytochalasin D (Peterson, Saxena, Saxena, and Russell: Biol. Reprod., in press, '86), we suggest that actin-PMP interactions play a major role in capacitating boar spermatozoa.     

Botulinum C2 toxin ADP-ribosylates actin and disorganizes the microfilament network in intact cells

Botulinum C2 toxin ADP-ribosylates actin in [32P]orthophosphate-labelled intact chick embryo cells (CEC). The toxin-induced rounding up of CEC is correlated with ADP-ribosylation of actin in intact cells in a time and concentration-dependent manner. Both, rounding up of cells and actin ADP-ribosylation, depend on the presence of both components of botulinum C2 toxin (components I and II) and are independent of the ability of CEC to divide. Treatment of CEC with botulinum C2 toxin induced a time-dependent disorganization of the typical architecture of the microfilament network as shown by fluorescein-phalloidin staining. Botulinum C2 toxin decreased the amount of Triton X-100 insoluble actin, while the fraction of Triton soluble actin was increased. Actin, which was 32P-labelled by botulinum C2 toxin in intact CEC, was recovered in the Triton soluble but not in the Triton insoluble actin fraction. It is suggested that in intact CEC botulinum C2 toxin causes ADP-ribosylation of G-actin but not of F-actin thereby leading to an accumulation in the pool of monomeric actin.     

Exploring the Stability Limits of Actin and Its Suprastructures

Actin is the main component of the microfilament system in eukaryotic cells and can be found in distinct morphological states. Global (G)-actin is able to assemble into highly organized, supramolecular cellular structures known as filamentous (F)-actin and bundled (B)-actin. To evaluate the structure and stability of G-, F-, and B-actin over a wide range of temperatures and pressures, we used Fourier transform infrared spectroscopy in combination with differential scanning and pressure perturbation calorimetry, small-angle x-ray scattering, laser confocal scanning microscopy, and transmission electron microscopy. Our analysis was designed to provide new (to our knowledge) insights into the stabilizing forces of actin self-assembly and to reveal the stability of the actin polymorphs, including in conditions encountered in extreme environments. In addition, we sought to explain the limited pressure stability of actin self-assembly observed in vivo. G-actin is not only the least temperature-stable but also the least pressure-stable actin species. Under abyssal conditions, where temperatures as low as 1–4°C and pressures up to 1 kbar are reached, G-actin is hardly stable. However, the supramolecular assemblies of actin are stable enough to withstand the extreme conditions usually encountered on Earth. Beyond ∼3–4 kbar, filamentous structures disassemble, and beyond ∼4 kbar, complete dissociation of F-actin structures is observed. Between ∼1 and 2 kbar, some disordering of actin assemblies commences, in agreement with in vivo observations. The limited pressure stability of the monomeric building block seems to be responsible for the suppression of actin assembly in the kbar pressure range.     

Actin--an inhibitor of eukaryotic elongation factor activities

An inhibitor of diphtheria toxin- and endogenous transferase-dependent ADP-ribosylation of eukaryotic elongation factor 2 (eEF2) has been found in the cytoplasmic fraction from rat liver. We provide evidence that this cytoplasmic inhibitor corresponds to actin, which gives rise also to inhibition of polyphenylalanine (polyPhe) synthesis. Both globular monomeric (G-actin) and filamentous (F-actin) forms of actin appear to be inhibitory on the action of elongation factors 1 and 2 (eEF1 and eEF2) in polyPhe synthesis with the inhibitory effect of G-actin proving to be stronger. Some component(s) in the postribosomal supernatant (S-130) fraction and also DNase I prevent actin-promoted inhibition of polyPhe synthesis.     

Levels of filamentous and globular actin in Chinese hamster ovary cells throughout the cell cycle

Synchronous Chinese hamster ovary (CHO) cells were obtained by mitotic selection and the levels of globular (G) actin, filamentous (F) actin, and cytoskeletal-associated F-actin were determined as cells progressed through the cell cycle. Total actin levels remained quite constant when expressed as a percent of the total protein. An increase in F-actin occurred upon plating the mitotic cells, but this increase was shown to be a result of attachment to the substratum, since cells which remained attached during the second mitosis failed to show these changes. No large variation in the levels of either F-actin or cytoskeletal-associated F-actin occurred throughout the cell cycle. Therefore, changes in the morphology of the CHO cells which are accompanied by a reorganization of actin-containing microfilaments during the cell cycle are not accompanied by significant changes in the size of the monomeric actin pool.     

PHD3-mediated prolyl hydroxylation of nonmuscle actin impairs polymerization and cell motility

Actin filaments play an essential role in cell movement, and many posttranslational modifications regulate actin filament assembly. Here we report that prolyl hydroxylase 3 (PHD3) interacts with nonmuscle actin in human cells and catalyzes hydroxylation of actin at proline residues 307 and 322. Blocking PHD3 expression or catalytic activity by short hairpin RNA knockdown or pharmacological inhibition, respectively, decreased actin prolyl hydroxylation. PHD3 knockdown increased filamentous F-actin assembly, which was reversed by PHD3 overexpression. PHD3 knockdown increased cell velocity and migration distance. Inhibition of PHD3 prolyl hydroxylase activity by dimethyloxalylglycine also increased actin polymerization and cell migration. These data reveal a novel role for PHD3 as a negative regulator of cell motility through posttranslational modification of nonmuscle actins.     

Clearance of a Hirano body-like F-actin aggresome generated by jasplakinolide

We have reported in a variety of mammalian cells the reversible formation of a filamentous actin (F-actin)-enriched aggresome generated by the actin toxin jasplakinolide (Lázaro-Diéguez et al., J Cell Sci 2008; 121:1415-25). Notably, this F-actin aggresome (FAG) resembles in many aspects the pathological Hirano body, which frequently appears in some diseases such as Alzheimer's and alcoholism. Using selective inhibitors, we examined the molecular and subcellular mechanisms that participate in the clearance of the FAG. Chaperones, microtubules, proteasomes and autophagosomes all actively participate to eliminate the FAG. Here we compile and compare these results and discuss the involvement of each process. Because of its simplicity and high reproducibility, our cellular model could help to test pharmacological agents designed to interfere with the mechanisms involved in the clearance of intracellular bodies and, in particular, of those enriched in F-actin.