Actin Depolymerizing Factor Cofilin Research Articles

Luteinizing Hormone Receptor-Stimulated Progesterone Production by Preovulatory Granulosa Cells Requires Protein Kinase A-Dependent Activation/Dephosphorylation of the Actin Dynamizing Protein Cofilin

Activation of the LH receptor (LHR) on preovulatory granulosa cells stimulates the cAMP/protein kinase A (PKA) pathway to regulate expression of genes required for ovulation and luteinization. LHR signaling also initiates rearrangement of the actin cytoskeleton. Because disruption of the actin cytoskeleton has been causally linked to steroidogenesis in various cell models, we sought to identify the cellular mechanisms that may modulate reorganization of the actin cytoskeleton and to determine whether cytoskeletal reorganization is required for steroidogenesis. Herein we report that LHR signaling in preovulatory granulosa cells promotes rapid dephosphorylation of the actin-depolymerizing factor cofilin at Ser3 that is dependent on PKA. The LHR-stimulated dephosphorylation of cofilin(Ser3) switches on cofilin activity to bind actin filaments and enhance their dynamics. Basal phosphorylation of cofilin(Ser3) is mediated by active/GTP-bound Rho and downstream protein kinases; LHR signaling promotes a decrease in active/GTP-bound Rho by a PKA-dependent mechanism. LHR-dependent Rho inactivation and subsequent activation of cofilin does not involve ERK, epidermal growth factor receptor, or phosphatidylinositol 3-kinase pathways downstream of PKA. To understand the biological significance of cofilin activation, preovulatory granulosa cells were transduced with a mutant cofilin adenoviral vector in which Ser3 was mutated to Glu (S-E cofilin). Inactive S-E cofilin abolished LHR-mediated reorganization of the actin cytoskeleton and caused a 70% decrease in LHR-stimulated progesterone that is obligatory for ovulation. Taken together, these results show that LHR signaling via PKA activates a cofilin-regulated rearrangement of the actin cytoskeleton and that active cofilin is required to initiate progesterone secretion by preovulatory granulosa cells.

Simulation Reveals Fundamental Behavior of the Actin Filament and Arp2/3 Branch Junction

Molecular modeling and simulation now offer unprecedented opportunity to study biological events at the atomic level. Unfortunately, broad application of these approaches is elusive due to the difficulty of simulating biologically relevant length and time scales. I will use our recent investigation into key processes within the actin cytoskeleton to highlight progress we have made on these challenges.The self-assembly of actin into a branched network of filaments is a vital process within the cytoskeleton of eukaryotic cells. This is chiefly regulated by the controlled hydrolysis of actin's bound ATP nucleotide. Although it is well established that ATP hydrolysis induces a change in actin's structure and dynamics, the exact mechanism by which this occurs is still unknown. We have used a novel computational approach to simulate various hydrolysis-induced structural transformations that have been suggested in the literature. Based on these results we are able to suggest a mechanism by which ATP hydrolysis regulates actin's structure and dynamics.Equally important to the dynamics of the cytoskeleton is the process by which actin filaments are depolymerized in a controlled fashion. Recent experimental studies have yielded a number of hypotheses regarding the process by which actin depolymerization factor cofilin severs and depolymerizes filaments. We will present molecular and coarse-grained analyses of cofilin-bound actin filaments, and provide a molecular view of this process.Finally, we have performed simulations of the actin branch junction - a key structural building block in the cytoskeleton. Our simulations reveal how small features of the actin protein give rise to the underlying dynamics of the entire branch junction. Strategies for coarse-graining supramolecular structures will be discussed in context of the branch junction.

LIM-kinase 2, a regulator of actin dynamics, is involved in mitotic spindle integrity and sensitivity to microtubule-destabilizing drugs

LIM-kinase 2 (LIMK2) belongs to the LIMK family of proteins, which comprises LIMK1 and LIMK2. Both proteins regulate actin polymerization through phosphorylation and inactivation of the actin depolymerizing factor cofilin. In this study, we show that the level of LIMK2 protein is increased in neuroblastoma, BE(2)-C cells, selected for resistance to microtubule-destabilizing agents, vincristine and colchicine. However, the level of phosphorylated LIMK1 and LIMK2 was similar in the resistant and parental BE(2)-C cells. In contrast, the level of phospho-cofilin was greatly increased in the drug-resistant cells. Downregulation of LIMK2 expression increases sensitivity of neuroblastoma SH-EP cells to vincristine and vinblastine but not to microtubule-stabilizing agents, while it's overexpression increased its resistance to vincristine. Its vincristine-induced mitotic arrest was moderately inhibited in the LIMK2 knockdown cells, suggesting that the increased drug sensitivity is through an alternative mechanism other then mitotic arrest and apoptosis. Moreover, downregulation of LIMK2 expression induces formation of abnormal mitotic spindles, an effect enhanced in the presence of microtubule-destabilizing agents. LIMK2 is important for normal mitotic spindle formation and altered LIMK2 expression mediates sensitivity to microtubule destabilizing agents. These findings suggest that inhibition of LIMK2 activity may be used for the treatment of tumors resistant to microtubule-destabilizing drugs.

Dichotomous effects of the cofilin kinase LIMK1 on the early steps of HIV-1 infection of CD4 T cells

We have previously demonstrated that binding of HIV-1 to the chemokine coreceptor, CXCR4, on resting CD4 T cells activates an actin-depolymerizing factor cofilin to promote the cortical actin dynamic critical for HIV latent infection [1]. The LIM domain kinase 1 (LIMK1) directly phosphorylates cofilin and regulates the actin cytoskeleton. Here, we investigated the role of LIMK1 in HIV-1 infection of resting CD4 T cells and found that HIV-1 infection triggered a rapid, transient activation of LIMK1. We also used siRNA knockdown to inhibit LIMK1 activity and found that knockdown of LIMK1 caused a decrease of F-actin and T cell chemotaxis. LIMK1 also had dichotomous effects on the chemokine coreceptor CXCR4 cycling (Figure ​(Figure1)1) and viral DNA synthesis (Figure ​(Figure2).2). Our findings are consistent with a model suggesting a multi-functional role of the cortical actin in mediating chemokine coreceptor density, HIV-1 DNA synthesis and intracellular migration. Figure 1 Endocytosis of CXCR4 analyzed by Western blot. Figure 2 Real-time PCR analysis HIV-1DNA synthesis in LIMK1 knockdown cells (007-LIMK knockdown cells, NTC-control cells).

LIMK1 acts downstream of BMP signaling in developing retinal ganglion cell axons but not dendrites

The actin cytoskeleton inside extending axonal and dendritic processes must undergo continuous assembly and disassembly. Some extrinsic factors modulate actin turnover through controlling the activity of LIM kinase 1 (LIMK1), which phosphorylates and inactivates the actin depolymerizing factor cofilin. Here, we for the first time examine the function and regulation of LIMK1 in vivo in the vertebrate nervous system. Upon expression of wildtype or kinase-dead forms of the protein, dendrite growth by Xenopus retinal ganglion cells (RGCs) was unchanged. In contrast, maintaining a low, but significant level, of LIMK1 function in the RGC axon is critical for proper extension. Interestingly, bone morphogenetic protein receptor II (BMPRII) is a major regulator of LIMK1 in extending RGC axons, as expression of a BMPRII lacking the LIMK1 binding region caused a dramatic shortening of the axons. Previously, we found that BMPRIIs stimulate dendrite initiation in vivo. Thus, the fact that manipulation of LIMK1 activity failed to alter dendrite growth suggests that BMPs may activate distinct signalling pathways in axons and dendrites.

INTESTINAL CYTOSKELETON DEGRADATION PRECEDES TIGHT JUNCTION LOSS FOLLOWING HEMORRHAGIC SHOCK

Hemorrhagic shock (HS) leads to intestinal barrier loss, causing systemic inflammation, which in turn can ultimately lead to multiorgan dysfunction syndrome. Barrier function is based on tight junctions (TJs) between intact epithelial cells. These TJs are anchored in the cell via the filamentous actin (F-actin) cytoskeleton. We hypothesize that HS causes hypoperfusion, leading to loss of F-actin, via activation of actin-depolymerizing factor/cofilin (AC), and consequently TJ loss. This study is aimed at unraveling the changes in cytoskeleton and TJ integrity after HS in organs commonly affected in multiorgan dysfunction syndrome (liver, kidney, and intestine) and to elucidate the events preceding cytoskeleton loss. Adult rats were subjected to a nonlethal HS and sacrificed, along with unshocked controls, at 15, 30, 60, and 90 min after induction of shock. Cytoskeleton, TJ integrity loss, and its consequences were studied by assessment of globular actin, F-actin, AC, zonula occludens protein 1, claudin 3, and bacterial translocation. In the liver and kidney, TJ and the F-actin cytoskeleton remained intact at all time points studied. However, in the intestine, significant loss of F-actin and increase of globular actin was seen from 15 min after shock. This change preceded statistically significant loss of the TJ proteins claudin 3 and zonula occludens protein 1, which were observed starting at 60 min after induction of shock (P < 0.05 vs. controls). Early after induction of shock (15 and 30 min) the nonactive AC (phosphorylated AC) in the intestine was significantly decreased (by 21% and 27%, P < 0.05 vs. control), whereas total AC remained constant, reflecting an increase in activated AC in the intestine from 15 min after shock. Bacterial translocation to mesenteric lymph nodes, liver, and spleen was present from 30 min after shock. This study shows for the first time that HS results in AC activation, selective intestinal actin cytoskeleton disruption, and TJ loss very early after the onset of shock. Loss of this intestinal barrier results in translocation of toxins and bacteria, which enhances inflammation and leads to infections.

Early intestinal tight junction loss after hemorrhagic shock

The intestinal barrier is based on tight junctions (TJ) between intact epithelial cells. These TJ are anchored via the filamentous (F‐)actin cytoskeleton. We hypothesize that hemorrhagic shock (HS) leading to intestinal hypoperfusion, causes loss of F‐actin, via activation of Actin Depolymerizing Factor/Cofilin (AC), and consequently results in TJ loss. This study investigates intestinal AC activation and cytoskeleton severing following HS.Rats were subjected to HS and sacrificed, along with controls, at 15, 30, 60 and 90 min after induction of shock. Intestinal hypoperfusion, activation of AC, actin cytoskeleton severing (degradation of F‐ into globular actin), and TJ integrity loss (Claudin‐3, ZO‐1) were assessed.HS caused intestinal hypoperfusion (−71.7% bloodflow) and activation of AC from 15 min after HS (by 21%, P&lt;0.05 vs controls, student's t‐test (stt)). This was accompanied by actin cytoskeleton severing, followed by intestinal TJ loss from 30 min after HS (Claudin‐3: 100% vs 71%; ZO‐1: 100% vs 41%, p&lt;0.05 vs controls, stt).We show for the first time that HS results rapidly in intestinal hypoperfusion, AC activation, actin depolymerization and subsequent TJ loss. Elucidation of the etiology of barrier failure is a first step in understanding the disease entity, which will be followed by the development of therapeutic interventions to reduce the development of barrier failure.

Hsp90 increases LIM kinase activity by promoting its homo‐dimerization

LIM kinase 1 (LIMK1) is a serine protein kinase that regulates the actin cytoskeleton by phosphorylation and inactivation of actin depolymerizing factor cofilin. LIMK1 activity is regulated by the Rho-GTPases via their serine/threonine kinase effectors Rho-kinase and p21-activated kinases 1 and 4 that phosphorylate LIMK1 on threonine 508 in its activation loop. The purpose of this study was to elucidate the pathway leading to the stability of LIMK1, a protein with a half-life of approximately 20 h. Because the half-life of kinase-dead LIMK1 is only 4 h, it is suggestive that trans- or auto-phosphorylation is responsible for the stabilization of LIMK1. Using known Hsp90 inhibitors, we have shown that the half-life of LIMK1 in cells depends on the presence of active Hsp90. Furthermore, endogenous LIMK1 coimmunoprecipitated with endogenous Hsp90 and this interaction promoted LIMK1 homodimer formation as seen by cross-linking experiments. Hsp90 binds LIMK1 via a recognition sequence within the LIMK1 kinase domain, homologous to that of ErbB-2. Mutation of a proline residue within this sequence to glutamic acid reduces its interaction with Hsp90, inhibits homodimer formation, and reduces its half-life to 4 h. These findings implicate Hsp90 in the stabilization of LIMK1 by promoting homodimer formation and transphosphorylation.

Myelin-Associated Inhibitors Regulate Cofilin Phosphorylation and Neuronal Inhibition through LIM Kinase and Slingshot Phosphatase

Myelin-associated inhibitors (MAIs) signal through a tripartate receptor complex on neurons to limit axon regeneration in the CNS. Inhibitory influences ultimately converge on the cytoskeleton to mediate growth cone collapse and neurite outgrowth inhibition. Rho GTPase and its downstream effector Rho kinase are key signaling intermediates in response to MAIs; however, the links between Rho and the actin cytoskeleton have not been fully defined. We found that Nogo-66, a potent inhibitory fragment of Nogo-A, signals through LIM (LIM is an acronym of the three gene products Lin-11, Isl-1, and Mec-3) kinase and Slingshot (SSH) phosphatase to regulate the phosphorylation profile of the actin depolymerization factor cofilin. Blockade of LIMK1 activation and subsequent cofilin phosphorylation circumvents myelin-dependent inhibition in chick dorsal root ganglion neurons, suggesting that phosphorylation and inactivation of cofilin is critical for neuronal inhibitory responses. Subsequent activation of SSH1 phosphatase mediates cofilin dephosphorylation and reactivation. Overexpression of SSH1 does not mimic the neurite outgrowth inhibitory effects of myelin, suggesting an alternative role in MAI inhibition. We speculate that SSH-mediated persistent cofilin activation may be responsible for maintaining an inhibited neuronal phenotype in response to myelin inhibitors.

Regulation of neuronal morphology and function by the tumor suppressors Tsc1 and Tsc2

Mutations in the TSC1 or TSC2 tumor suppressor genes lead to tuberous sclerosis complex (TSC), a dominant hamartomatous disorder that often presents with mental retardation, epilepsy and autism. The etiology of these neurological symptoms is unclear and the function of the TSC pathway in neurons is unknown. We found that in post-mitotic, hippocampal pyramidal neurons of mice and rats, loss of Tsc1 or Tsc2 triggered enlargement of somas and dendritic spines and altered the properties of glutamatergic synapses. Furthermore, loss of a single copy of the Tsc1 gene was sufficient to perturb dendritic spine structure. Morphological changes required regulation of the actin-depolymerization factor cofilin at a conserved LIM-kinase phosphorylation site, the phosphorylation of which was increased by loss of Tsc2. Thus, the TSC pathway regulates growth and synapse function in neurons, and perturbations of neuronal structure and function are likely to contribute to the pathogenesis of the neurological symptoms of TSC.

New Cofilin Phosphatase

Control of the actin cytoskeleton is critical for many cellular processes, particularly cell motility. The actin-depolymerizing factor cofilin is inhibited by phosphorylation. To better understand its regulation, Gohla et al. used classical protein-purification techniques to isolate a protein with phosphatase activity toward cofilin phosphorylated on serine 3. The enzyme they isolated is a member of the haloacid dehalogenase (HAD) superfamily of phosphotransferases. These phosphatases have an unusual catalytic mechanism and were not previously implicated in serine dephosphorylation in mammals. The phosphatase, which the authors name chronophin (CIN), appears to be a physiologically relevant regulator of cofilin. Overexpression of CIN decreased amounts of phosphocofilin in HeLa cells. Depletion of CIN by RNA interference increased the amount of phosphocofilin, increased the amount of Factin, stabilized membrane protrusions and stress fibers, and caused abnormalities in cell division. The findings place new emphasis on understanding the HAD proteins and suggest that CIN could be a therapeutic target in diseases where control of the actin cytoskeleton is disrupted. A. Gohla, J. Birkenfeld, G. M. Bokoch, Chronophin, a novel HAD-type serine protein phosphatase, regulates cofilin-dependent actin dynamics. Nat. Cell Biol. 7 , 21-29 (2005). [PubMed]

Rho GTPases Regulate Axon Growth through Convergent and Divergent Signaling Pathways

Rho GTPases are essential regulators of cytoskeletal reorganization, but how they do so during neuronal morphogenesis in vivo is poorly understood. Here we show that the actin depolymerization factor cofilin is essential for axon growth in Drosophila neurons. Cofilin function in axon growth is inhibited by LIM kinase and activated by Slingshot phosphatase. Dephosphorylating cofilin appears to be the major function of Slingshot in regulating axon growth in vivo. Genetic data provide evidence that Rho or Rac/Cdc42, via effector kinases Rok or Pak, respectively, activate LIM kinase to inhibit axon growth. Importantly, Rac also activates a Pak-independent pathway that promotes axon growth, and different RacGEFs regulate these distinct pathways. These genetic analyses reveal convergent and divergent pathways from Rho GTPases to the cytoskeleton during axon growth in vivo and suggest that different developmental outcomes could be achieved by biases in pathway selection.

VEGF treatment induces signaling pathways that regulate both actin polymerization and depolymerization

The angiogenic growth factor vascular endothelial growth factor (VEGF) enhances endothelial cell migration through the activation of multiple signaling transduction pathways. Actin reorganization is an important component in VEGF-induced migration, yet the signaling pathways mediating this process remain unclear. Actin reorganization involves both actin polymerization and depolymerization, and in this study we demonstrate that VEGF-treatment regulates both of these activities. With respect to actin polymerization, our results indicate that the actin nucleation promoting factors (NPF) neural Wiskott-Aldrich syndrome protein (N-WASP) binds the SH2- plus SH3-domain containing adaptor protein Nck in both control and VEGF-treated cells. We had previously showed that VEGF treatment leads to the recruitment of Nck to activated receptor, and our current results indicate a VEGF-dependent redistribution of N-WASP to the cell surface. A Nck dominant-negative blocked Nck recruitment to receptor, blocked N-WASP cellular redistribution and attenuated actin stress fiber formation. With respect to actin depolymerization, VEGF-treatment led to the rapid phosphorylation of the actin depolymerization factor cofilin, and its upstream regulator, LIM-kinase (LIMK). Unlike what is observed in certain other cell types, the p21-activated kinase (PAK), a Nck binding protein, does not mediate VEGF-induced LIMK phosphorylation, as a PAK dominant-negative had no effect on this activity. The PAK dominant-negative also did not affect VEGF-induced actin reorganization. Pharmacological inhibitors of phosphoinositide-3 kinase (PI3-K) and the rho-activated kinase (ROCK) attenuated VEGF-induced LIMK phosphorylation, indicating a role for (PI3-K) and ROCK in the signaling pathways leading to regulation of LIMK activity.

Identification of cofilin and LIM-domain-containing protein kinase 1 as novel interaction partners of 14-3-3 zeta.

Proteins of the 14-3-3 family have been implicated in various physiological processes, and are thought to function as adaptors in various signal transduction pathways. In addition, 14-3-3 proteins may contribute to the reorganization of the actin cytoskeleton by interacting with as yet unidentified actin-binding proteins. Here we show that the 14-3-3 zeta isoform interacts with both the actin-depolymerizing factor cofilin and its regulatory kinase, LIM (Lin-11/Isl-1/Mec-3)-domain-containing protein kinase 1 (LIMK1). In both yeast two-hybrid assays and glutathione S-transferase pull-down experiments, these proteins bound efficiently to 14-3-3 zeta. Deletion analysis revealed consensus 14-3-3 binding sites on both cofilin and LIMK1. Furthermore, the C-terminal region of 14-3-3 zeta inhibited the binding of cofilin to actin in co-sedimentation experiments. Upon co-transfection into COS-7 cells, 14-3-3 zeta-specific immunoreactivity was redistributed into characteristic LIMK1-induced actin aggregations. Our data are consistent with 14-3-3-protein-induced changes to the actin cytoskeleton resulting from interactions with cofilin and/or LIMK1.

Specification of actin filament function and molecular composition by tropomyosin isoforms.

The specific functions of greater than 40 vertebrate nonmuscle tropomyosins (Tms) are poorly understood. In this article we have tested the ability of two Tm isoforms, TmBr3 and the human homologue of Tm5 (hTM5(NM1)), to regulate actin filament function. We found that these Tms can differentially alter actin filament organization, cell size, and shape. hTm5(NM1) was able to recruit myosin II into stress fibers, which resulted in decreased lamellipodia and cellular migration. In contrast, TmBr3 transfection induced lamellipodial formation, increased cellular migration, and reduced stress fibers. Based on coimmunoprecipitation and colocalization studies, TmBr3 appeared to be associated with actin-depolymerizing factor/cofilin (ADF)-bound actin filaments. Additionally, the Tms can specifically regulate the incorporation of other Tms into actin filaments, suggesting that selective dimerization may also be involved in the control of actin filament organization. We conclude that Tm isoforms can be used to specify the functional properties and molecular composition of actin filaments and that spatial segregation of isoforms may lead to localized specialization of actin filament function.

Aip1p interacts with cofilin to disassemble actin filaments.

Actin interacting protein 1 (Aip1) is a conserved component of the actin cytoskeleton first identified in a two-hybrid screen against yeast actin. Here, we report that Aip1p also interacts with the ubiquitous actin depolymerizing factor cofilin. A two-hybrid-based approach using cofilin and actin mutants identified residues necessary for the interaction of actin, cofilin, and Aip1p in an apparent ternary complex. Deletion of the AIP1 gene is lethal in combination with cofilin mutants or act1-159, an actin mutation that slows the rate of actin filament disassembly in vivo. Aip1p localizes to cortical actin patches in yeast cells, and this localization is disrupted by specific actin and cofilin mutations. Further, Aip1p is required to restrict cofilin localization to cortical patches. Finally, biochemical analyses show that Aip1p causes net depolymerization of actin filaments only in the presence of cofilin and that cofilin enhances binding of Aip1p to actin filaments. We conclude that Aip1p is a cofilin-associated protein that enhances the filament disassembly activity of cofilin and restricts cofilin localization to cortical actin patches.