Actin-remodeling Proteins Research Articles

Emergence of Large-Scale Cell Morphology and Movement from Local Actin Filament Growth Dynamics

Variations in cell migration and morphology are consequences of changes in underlying cytoskeletal organization and dynamics. We investigated how these large-scale cellular events emerge as direct consequences of small-scale cytoskeletal molecular activities. Because the properties of the actin cytoskeleton can be modulated by actin-remodeling proteins, we quantitatively examined how one such family of proteins, enabled/vasodilator-stimulated phosphoprotein (Ena/VASP), affects the migration and morphology of epithelial fish keratocytes. Keratocytes generally migrate persistently while exhibiting a characteristic smooth-edged “canoe” shape, but may also exhibit less regular morphologies and less persistent movement. When we observed that the smooth-edged canoe keratocyte morphology correlated with enrichment of Ena/VASP at the leading edge, we mislocalized and overexpressed Ena/VASP proteins and found that this led to changes in the morphology and movement persistence of cells within a population. Thus, local changes in actin filament dynamics due to Ena/VASP activity directly caused changes in cell morphology, which is coupled to the motile behavior of keratocytes. We also characterized the range of natural cell-to-cell variation within a population by using measurable morphological and behavioral features—cell shape, leading-edge shape, filamentous actin (F-actin) distribution, cell speed, and directional persistence—that we have found to correlate with each other to describe a spectrum of coordinated phenotypes based on Ena/VASP enrichment at the leading edge. This spectrum stretched from smooth-edged, canoe-shaped keratocytes—which had VASP highly enriched at their leading edges and migrated fast with straight trajectories—to more irregular, rounder cells migrating slower with less directional persistence and low levels of VASP at their leading edges. We developed a mathematical model that accounts for these coordinated cell-shape and behavior phenotypes as large-scale consequences of kinetic contributions of VASP to actin filament growth and protection from capping at the leading edge. This work shows that the local effects of actin-remodeling proteins on cytoskeletal dynamics and organization can manifest as global modifications of the shape and behavior of migrating cells and that mathematical modeling can elucidate these large-scale cell behaviors from knowledge of detailed multiscale protein interactions.

Flightless I: An actin-remodelling protein and an important negative regulator of wound repair

Flightless I (FliI) is a member of the gelsolin family of actin-remodelling proteins, and has been identified as having two functional protein family domains: a leucine rich repeat (LRR) domain and a gelsolin-like domain. This unique structure allows FliI to act as an actin-remodelling protein as well as a nuclear receptor co-activator with ability to interact with various other proteins important in cellular signaling. The actin cytoskeleton is an integral component of all cells and the effect of FliI protein on actin remodelling is a vital part of cellular motility, contraction and adhesion. The product of the FliI gene is expected to provide a vital link between the molecules of yet unidentified signal transduction pathways and the actin cytoskeleton. Exact signaling pathways and mechanisms underpinning FliI effects in wound healing are yet to be fully identified however strong research evidence clearly identifies this molecule as a possible new therapeutic target whose manipulation may greatly improve wound healing and could lead to potential innovative medical applications.

Flightless I deficiency enhances wound repair by increasing cell migration and proliferation

Wound healing disorders are a therapeutic problem of increasing clinical importance involving substantial morbidity, mortality, and rising health costs. Our studies investigating flightless I (FliI), a highly conserved actin-remodelling protein, now reveal that FliI is an important regulator of wound repair whose manipulation may lead to enhanced wound outcomes. We demonstrate that FliI-deficient + /- mice are characterized by improved wound healing with increased epithelial migration and enhanced wound contraction. In contrast, FliI-overexpressing mice have significantly impaired wound healing with larger less contracted wounds and reduced cellular proliferation. We show that FliI is secreted in response to wounding and that topical application of antibodies raised against the leucine-rich repeat domain of the FliI protein (FliL) significantly improves wound repair. These studies reveal that FliI affects wound repair via mechanisms involving cell migration and proliferation and that FliI might represent an effective novel therapeutic factor to improve conditions in which wound healing is impaired.

Expression of rotavirus NSP4 alters the actin network organization through the actin remodeling protein cofilin.

Rotavirus is a major cause of infantile gastroenteritis with a multifactorial pathogenesis. As with many other pathogens, rotavirus infection and replication leads to rearrangement of the cytoskeleton with disorganization of cytoskeletal elements such as actin and cytokeratin through a calcium-dependent process that has not been fully characterized. The rotavirus enterotoxin NSP4, shown previously to elevate intracellular calcium levels when added exogenously as well as when expressed intracellularly, is a key player in intracellular calcium regulation during rotavirus infection. Here, we investigated the role NSP4 may play in actin rearrangement. Expression of NSP4 fused to enhanced green fluorescent protein (NSP4-EGFP), but not expression of EGFP alone, caused stabilization of long cellular projections in fully confluent HEK 293 cells. Cells expressing NSP4-EGFP for 24 h were also resistant to cell rounding induced by cytochalasin D. Quantification of filamentous actin (F-actin) content by using rhodamine-conjugated phalloidin and flow cytometry showed an elevated F-actin content in NSP4-EGFP-expressing and rotavirus-infected cells in comparison with that in nonexpressing and noninfected cells. Normalization of intracellular calcium levels prevented alterations of F-actin content. Observed changes in F-actin amounts correlated with the increased activation of the actin-remodeling protein cofilin. These calcium-dependent actin rearrangements induced by intracellular NSP4 expression may contribute to rotavirus pathogenesis by interfering with cellular processes dependent on subcortical actin remodeling, including ion transport and viral release.

Phosphatidylinositol 3-Kinase Functions as a Ras Effector in the Signaling Cascade That Regulates Dephosphorylation of the Actin-Remodeling Protein Cofilin after Costimulation of Untransformed Human T Lymphocytes

The activity of cofilin, an actin-remodeling protein, is required for T lymphocyte activation with regard to formation of the immunological synapse, cytokine production, and proliferation. In unstimulated T PBL (PB-T), cofilin is present in its Ser3-phosphorylated inactive form. Costimulation of TCR/CD3 and CD28 induces dephosphorylation and, thus, activation of cofilin. In this study we characterized the signaling cascades leading to cofilin activation in untransformed human PB-T. We show that a Ras-PI3K cascade regulates dephosphorylation of cofilin in PB-T. The GTPase Ras is a central mediator of this pathway; transient expression of an activated form of H-Ras in PB-T triggered the dephosphorylation of cofilin. Inhibition of either MAPK/ERK kinase or PI3K blocked both Ras-induced and costimulation-induced cofilin dephosphorylation in PB-T, showing that the combined activities of both signaling proteins are required to activate cofilin. That Ras functions as a central regulator of cofilin dephosphorylation after costimulation through CD3 x CD28 was finally proven by transient expression of a dominant negative form of H-Ras in primary human PB-T. It clearly inhibited costimulation-induced cofilin dephosphorylation, and likewise, activation of PI3K was diminished. Our data, in addition, demonstrate that regarding the downstream effectors of Ras, a clear difference exists between untransformed human PB-T and the T lymphoma line Jurkat. Thus, in PB-T the Ras signaling cascade is able to activate PI3K, whereas in Jurkat cells this is not the case. In addition to the insights into the regulation of cofilin, this finding discloses a to date unrecognized possibility of PI3K activation in T lymphocytes.

Ras initiates phosphatidyl-inositol-3-kinase (PI3K)/PKB mediated signalling pathways in untransformed human peripheral blood T lymphocytes

Activation of T lymphocytes through costimulation of the T cell receptor/CD3 complex (TCR/CD3) and coreceptors (e.g. CD2 or CD28) leads to production of the growth factor interleukin-2 (IL-2) and subsequent proliferation. For these activation processes, remodelling of the actin cytoskeleton plays an important functional role. We have shown that the activity of the actin-remodelling protein cofilin is crucially involved in T lymphocyte activation processes. In unstimulated human peripheral blood T lymphocytes (PB-T) cofilin exists in its inactive ser-3-phosphorylated form. T lymphocyte activation through costimulation of TCR plus the coreceptors CD28 or CD2, respectively, induces the dephosphorylation of cofilin. Concomitantly, cofilin associates with the actin cytoskeleton. The functional importance of cofilin for T lymphocyte activation was shown employing cell permeable peptides which block binding of cofilin to actin. In human PB-T these peptides impair the formation of the immunological synapse and inhibit the induction of T lymphocyte proliferation and cytokine production. The serine phosphatases PP1 and PP2A dephosphorylate cofilin in T lymphocytes. Importantly, a PKC-Ras-MEK/PI3K-cascade links costimulation of PB-T through TCR/CD3 and CD28 to activation of cofilin through dephosphorylation. Notably, the induction of cofilin dephosphorylation requires the combined activities of two Ras-effectors, namely MEK and PI3K. With respect to PI3K, this result was unexpected since so far it was generally assumed that-unlike in other cell types-Ras is not able to activate PI3K in T lymphocytes, as concluded from experiments performed with the human T-lymphoma line Jurkat. This discrepancy implied that the signalling events upstream of PI3K differ between PB-T and Jurkat cells. In line with this, we found that in PB-T the PI3K-inhibitors wortmannin and LY294002 block activation induced cofilin dephosphorylation and its association with the actin cytoskeleton. In Jurkat cells, however, where cofilin is present mainly in its non-phosphorylated form and permanently associated with the actin cytoskeleton, wortmannin and LY294002 do not block these events. Studies by others employing these PI3K-inhibitors have also led to such contradictory results: While in stimulated PB-T these inhibitors repress expression of IL-2, they even enhance IL-2 expression in Jurkat cells. These findings show that signalling events in Jurkat cells are not representative for signalling processes in untransformed human T lymphocytes. Importantly, our data demonstrate that-rebutting a persistent dogma-a T-cell specific uncoupling of PI3K from Ras does not exist.

Rab13 regulates PKA signaling during tight junction assembly.

The GTPase Rab13 regulates the assembly of functional epithelial tight junctions (TJs) through a yet unknown mechanism. Here, we show that expression of the GTP-bound form of Rab13 inhibits PKA-dependent phosphorylation and TJ recruitment of the vasodilator-stimulated phosphoprotein, an actin remodelling protein. We demonstrate that Rab13GTP directly binds to PKA and inhibits its activity. Interestingly, activation of PKA abrogates the inhibitory effect of Rab13 on the recruitment of vasodilator-stimulated phosphoprotein, ZO-1, and claudin1 to cell–cell junctions. Rab13 is, therefore, the first GTPase that controls PKA activity and provides an unexpected link between PKA signaling and the dynamics of TJ assembly.

Cofilin peptide homologs interfere with immunological synapse formation and T cell activation.

The formation of supramolecular activation clusters within the immunological synapse, crucial for sustained signaling and T lymphocyte activation, requires costimulation-dependent reorganization of the actin cytoskeleton. Here we have identified the actin-remodeling protein cofilin as a key player in this process. Cell-permeable peptides that block costimulation-induced cofilin/F-actin interactions in untransformed human T lymphocytes impair receptor capping and immunological synapse formation at the interface between T cells and antigen-presenting cells. As a consequence, T cell activation, as measured by cytokine production and proliferation, is inhibited.

The ADF/cofilin family: actin-remodeling proteins.

The ADF/cofilins are a family of actin-binding proteins expressed in all eukaryotic cells so far examined. Members of this family remodel the actin cytoskeleton, for example during cytokinesis, when the actin-rich contractile ring shrinks as it contracts through the interaction of ADF/cofilins with both monomeric and filamentous actin. The depolymerizing activity is twofold: ADF/cofilins sever actin filaments and also increase the rate at which monomers leave the filament's pointed end. The three-dimensional structure of ADF/cofilins is similar to a fold in members of the gelsolin family of actin-binding proteins in which this fold is typically repeated three or six times; although both families bind polyphosphoinositide lipids and actin in a pH-dependent manner, they share no obvious sequence similarity. Plants and animals have multiple ADF/cofilin genes, belonging in vertebrates to two types, ADF and cofilins. Other eukaryotes (such as yeast, Acanthamoeba and slime moulds) have a single ADF/cofilin gene. Phylogenetic analysis of the ADF/cofilins reveals that, with few exceptions, their relationships reflect conventional views of the relationships between the major groups of organisms.