Characterization of paxillin LIM domain-associated serine threonine kinases: activation by angiotensin II in vascular smooth muscle cells

Recently we reported a novel means of regulating LIM domain protein function. Paxillin LIM zinc-finger phosphorylation in response to cell adhesion regulates the subcellular localization of this cytoskeletal adaptor protein to focal adhesions, and also modulates cell adhesion to fibronectin (Brown et al. [1998] Mol. Biol. Cell 9:1803-1816). In the present study, we characterize further the protein kinases that phosphorylate paxillin LIM2 on threonine and LIM3 on serine. Analysis of the subcellular distribution of the LIM kinases demonstrated that the LIM3 protein kinase, but not the LIM2 kinase, resides within a detergent-insoluble fraction. The activities of the paxillin LIM domain kinases are differentially regulated during embryogenesis, and analysis of tissue distribution indicated a specificity in expression patterns between the LIM2 and LIM3 kinases. In addition, these protein kinases were refractory to inhibition by a panel of broad-spectrum serine/threonine kinase inhibitors, suggesting a novel derivation. The paxillin protein kinase activities were stimulated in serum-starved CHO.K1 cells by the mitogen phorbol myristate acetate (PMA), and by PMA and angiotensin II in rat aortic smooth muscle cells. In vivo labeling, phosphoamino acid analysis, and phosphopeptide mapping of paxillin immunoprecipitated from angiotensin II-stimulated smooth muscle cells confirmed an induction of paxillin serine/threonine phosphorylation and supports the contention that these newly identified paxillin kinases are dynamic components of growth factor signaling through the cytoskeleton.     

Inhibition of neurite extension by overexpression of individual domains of LIM kinase 1

Lin-11, Isl-1 and Mec-3 (LIM) kinases are serine/threonine kinases that phosphorylate cofilin, an actin depolymerizing protein. LIM kinases have a highly modular structure composed of two N-terminal LIM domains (LIM 1/2), a PSD-95, Dlg and ZO-1 (PDZ) domain and a C-terminal protein kinase domain. Here, we overexpressed individual domains of mouse LIM kinase 1 (LIMK1) in PC12 cells and investigated their effects on neurite outgrowth. Although none of the LIMK1 domains had an effect on spontaneous neurite outgrowth, the N-terminal LIM 1/2 domains strongly inhibited differentiation of PC12 cells after stimulation with both nerve growth factor (NGF) and the Rho-kinase inhibitor Y-27632. In contrast, the overexpressed PDZ domain reduced neurite outgrowth only when differentiation had been induced by Y-27632, but not by NGF. Our data suggest that the different non-catalytic N-terminal domains of LIMK1 contribute to the regulation of neurite extension by using distinct signal transduction pathways.     

Activation of LIM kinases by myotonic dystrophy kinase-related Cdc42-binding kinase alpha

LIM kinases (LIMK1 and LIMK2) regulate actin cytoskeletal reorganization through cofilin phosphorylation downstream of distinct Rho family GTPases. Pak1 and ROCK, respectively, activate LIMK1 and LIMK2 downstream of Rac and Rho; however, an effector protein kinase for LIMKs downstream of Cdc42 remains to be defined. We now report evidence that LIMK1 and LIMK2 activities toward cofilin phosphorylation are stimulated in cells by the co-expression of myotonic dystrophy kinase-related Cdc42-binding kinase alpha (MRCKalpha), an effector protein kinase of Cdc42. In vitro, MRCKalpha phosphorylated the protein kinase domain of LIM kinases, and the site in LIMK2 phosphorylated by MRCKalpha proved to be threonine 505 within the activation segment. Expression of MRCKalpha induced phosphorylation of actin depolymerizing factor (ADF)/cofilin in cells, whereas MRCKalpha-induced ADF/cofilin phosphorylation was inhibited by the co-expression with the protein kinase-deficient form of LIM kinases. These results indicate that MRCKalpha phosphorylates and activates LIM kinases downstream of Cdc42, which in turn regulates the actin cytoskeletal reorganization through the phosphorylation and inactivation of ADF/cofilin.     

The PDZ Domain of the LIM Protein Enigma Binds to β-Tropomyosin

PDZ and LIM domains are modular protein interaction motifs present in proteins with diverse functions. Enigma is representative of a family of proteins composed of a series of conserved PDZ and LIM domains. The LIM domains of Enigma and its most related family member, Enigma homology protein, bind to protein kinases, whereas the PDZ domains of Enigma and family member actin-associated LIM protein bind to actin filaments. Enigma localizes to actin filaments in fibroblasts via its PDZ domain, and actin-associated LIM protein binds to and colocalizes with the actin-binding protein alpha-actinin-2 at Z lines in skeletal muscle. We show that Enigma is present at the Z line in skeletal muscle and that the PDZ domain of Enigma binds to a skeletal muscle target, the actin-binding protein tropomyosin (skeletal beta-TM). The interaction between Enigma and skeletal beta-TM was specific for the PDZ domain of Enigma, was abolished by mutations in the PDZ domain, and required the PDZ-binding consensus sequence (Thr-Ser-Leu) at the extreme carboxyl terminus of skeletal beta-TM. Enigma interacted with isoforms of tropomyosin expressed in C2C12 myotubes and formed an immunoprecipitable complex with skeletal beta-TM in transfected cells. The association of Enigma with skeletal beta-TM suggests a role for Enigma as an adapter protein that directs LIM-binding proteins to actin filaments of muscle cells.     

Serine and Threonine Phosphorylation of the Paxillin LIM Domains Regulates Paxillin Focal Adhesion Localization and Cell Adhesion to Fibronectin

We have previously shown that the LIM domains of paxillin operate as the focal adhesion (FA)-targeting motif of this protein. In the current study, we have identified the capacity of paxillin LIM2 and LIM3 to serve as binding sites for, and substrates of serine/threonine kinases. The activities of the LIM2- and LIM3-associated kinases were stimulated after adhesion of CHO.K1 cells to fibronectin; consequently, a role for LIM domain phosphorylation in regulating the subcellular localization of paxillin after adhesion to fibronectin was investigated. An avian paxillin-CHO.K1 model system was used to explore the role of paxillin phosphorylation in paxillin localization to FAs. We found that mutations of paxillin that mimicked LIM domain phosphorylation accelerated fibronectin-induced localization of paxillin to focal contacts. Further, blocking phosphorylation of the LIM domains reduced cell adhesion to fibronectin, whereas constitutive LIM domain phosphorylation significantly increased the capacity of cells to adhere to fibronectin. The potentiation of FA targeting and cell adhesion to fibronectin was specific to LIM domain phosphorylation as mutation of the amino-terminal tyrosine and serine residues of paxillin that are phosphorylated in response to fibronectin adhesion had no effect on the rate of FA localization or cell adhesion. This represents the first demonstration of the regulation of protein localization through LIM domain phosphorylation and suggests a novel mechanism of regulating LIM domain function. Additionally, these results provide the first evidence that paxillin contributes to “inside-out” integrin-mediated signal transduction.     

The interactome of LIM domain proteins: the contributions of LIM domain proteins to heart failure and heart development

LIM domain proteins all contain at least one double zinc-finger motif. They belong to a large family and here we review those expressed mainly in mammalian hearts, but particularly in cardiomyocytes. These proteins contain between one and five LIM domains and usually these proteins contain other domains that have specific functions such as actin-binding, kinases and nuclear translocation motifs. While several recent reviews have summarised the importance of individual LIM domain proteins, this is the first review of its kind to cover all LIMs associated with the heart. Here we examine 33 LIM proteins (including three that bind to, but do not themselves contain, LIM domains) that are implicated in either the development of the heart, heart disorders and failure, or both. Our analysis is consistent with the view that cardiac LIM domain proteins form multiple extensive networks of multi-protein complexes within the myocardium. This multiplicity of binding partners probably protects the heart as it is challenged to maintain cardiac output, until the imbalance reaches a turning point that results in failure. We believe that the complexity of LIM interactions is properly described by the term LIM interactome.     

Protein kinases from Dictyostelium discoideum with similarity to LIM kinases

We cloned a protein kinase (DdKinY) from Dictyostelium discoideum by low stringency hybridization using the catalytic domain from DdKinX [B.W. Wetterauer et al., Biochim. Biophys. Acta 1265 (1995) 97-101] as a probe. Both kinases have low sequence similarity to other protein kinases in the databases. However, phylogenetic analysis showed that both kinases cluster with vertebrate LIM kinases due to homology within the catalytic domain.     

Elfin is expressed during early heart development

Elfin (previously named CLIM1) is a protein that possesses an N-terminal PDZ domain and a C-terminal LIM domain. It belongs to the family of Enigma proteins. Enigma proteins are a family of cytoplasmic proteins that contain an N-terminal PDZ domain and a series of C-terminal LIM domains. By virtue of these two protein interacting domains, Enigma proteins are capable of protein-protein interactions. It has been proposed that Enigma proteins may act as adapters between kinases and the cytoskeleton. We have previously shown that Elfin is most abundantly expressed in the heart and it colocalizes with alpha-actinin 2 at the Z-disks of the myocardium. In this report, Elfin was shown to localize at the actin stress fibers of myoblasts, as revealed by green fluorescent protein (GFP) tagging. In situ hybridization and immunostaining showed that Elfin expression begins at an early stage in mouse development and is present throughout the developing heart. Taken together, our experimental results suggest that Elfin may play an important role in myofibrillogenesis and heart development.     

Regulation of growth cone actin dynamics by ADF/cofilin.

Nervous system development is reliant on neuronal pathfinding, the process in which axons are guided to their target cells by specific extracellular cues. The ability of neurons to extend over long distances in response to environmental guidance signals is made possible by the growth cone, a highly motile structure found at the end of neuronal processes. Growth cones detect directional cues and respond with either attractive or repulsive movements. The motility of growth cones is dependent on rapid reorganization of the actin cytoskeleton, presumably mediated by actin-associated proteins under the control of incoming guidance signals. This article reviews how one such family of proteins, the ADF/cofilins, are emerging as key regulators of growth cone actin dynamics. These proteins are essential for rapid actin turnover in a variety of different cell types. ADF/cofilins are heavily co-localized with actin in growth cones and are necessary for neurite outgrowth. ADF/cofilin activities are regulated through reversible phosphorylation by LIM kinases and slingshot phosphatases. LIM kinases are downstream effectors of the Rho GTPases Rho, Rac, and Cdc42. Growing evidence suggests that extracellular guidance cues may locally alter actin dynamics by regulating the activity of LIM kinase and ADF/cofilin phosphatases via the Rho GTPases. In this way, ADF/cofilins and their upstream effectors may be pivotal to our understanding of how guidance information is translated into physical alterations of the growth cone actin cytoskeleton.     

Lim kinases, regulators of actin dynamics

The members of the LIM kinase (LIMK) family, which include LIMK 1 and 2, are serine protein kinases involved in the regulation of actin polymerisation and microtubule disassembly. Their activity is regulated by phosphorylation of a threonine residue within the activation loop of the kinase by p21-activated kinases 1 and 4 and by Rho kinase. LIMKs phosphorylate and inactivate the actin depolymerising factors ADF/cofilin resulting in net increase in the cellular filamentous actin. Hsp90 regulates the levels of the LIM kinase proteins by promoting their homo-dimerisation and trans-phosphorylation. Rnf6 is an E3 ubiquitin ligase responsible for LIMK degradation in neurons. The activity of LIMK1 is also required for microtubule disassembly in endothelial cells. While LIMK1 localizes mainly at focal adhesions, LIMK2 is found in cytoplasmic punctae, suggesting that they may have different cellular functions. LIMK1 was shown to be involved in cancer metastasis, while LIMK2 activation promotes cells cycle progression.     

Regulating actin dynamics in neuronal growth cones by ADF/cofilin and rho family GTPases

Growth cone motility and navigation in response to extracellular signals are regulated by actin dynamics. To better understand actin involvement in these processes we determined how and in what form actin reaches growth cones, and once there, how actin assembly is regulated. A continuous supply of actin is maintained at the axon tip by slow transport, the mobile component consisting of an unassembled form of actin. Actin is co-transported with actin-binding proteins, including ADF and cofilin, structurally related proteins essential for rapid turnover of actin filaments in vivo. ADF and cofilin activity is regulated through phosphorylation by LIM kinases, downstream effectors of the Rho family of GTPases, Cdc42, Rac and Rho. Attractive and repulsive extracellular guidance cues might locally alter actin dynamics by binding specific GTPase-linked receptors, activating LIM kinases, and subsequently modulating the activity of ADF/cofilin. ADF is enriched in growth cones and is required for neurite outgrowth. In addition, signals that influence growth cone behavior alter ADF/cofilin phosphorylation, and overexpression of ADF enhances neurite outgrowth. Growth promoting effects of laminin are mimicked by expression of constitutively active Cdc42 and blocked by expression of the dominant negative Cdc42. Repulsive effects of myelin and sema3D on growth cones are blocked by expression of constitutively active Rac1 and dominant negative Rac1, respectively. Thus a series of complex pathways must exist for regulating effectors of actin dynamics. The bifurcating nature of the ADF/cofilin phosphorylation pathway may provide the integration necessary for this complex regulation.     

Insights into the molecular evolution of the PDZ/LIM family and identification of a novel conserved protein motif

The PDZ and LIM domain-containing protein family is encoded by a diverse group of genes whose phylogeny has currently not been analyzed. In mammals, ten genes are found that encode both a PDZ- and one or several LIM-domains. These genes are: ALP, RIL, Elfin (CLP36), Mystique, Enigma (LMP-1), Enigma homologue (ENH), ZASP (Cypher, Oracle), LMO7 and the two LIM domain kinases (LIMK1 and LIMK2). As conventional alignment and phylogenetic procedures of full-length sequences fell short of elucidating the evolutionary history of these genes, we started to analyze the PDZ and LIM domain sequences themselves. Using information from most sequenced eukaryotic lineages, our phylogenetic analysis is based on full-length cDNA-, EST-derived- and genomic- PDZ and LIM domain sequences of over 25 species, ranging from yeast to humans. Plant and protozoan homologs were not found. Our phylogenetic analysis identifies a number of domain duplication and rearrangement events, and shows a single convergent event during evolution of the PDZ/LIM family. Further, we describe the separation of the ALP and Enigma subfamilies in lower vertebrates and identify a novel consensus motif, which we call 'ALP-like motif' (AM). This motif is highly-conserved between ALP subfamily proteins of diverse organisms. We used here a combinatorial approach to define the relation of the PDZ and LIM domain encoding genes and to reconstruct their phylogeny. This analysis allowed us to classify the PDZ/LIM family and to suggest a meaningful model for the molecular evolution of the diverse gene architectures found in this multi-domain family.     

Phosphorylated LIM Kinases Colocalize with Gamma-Tubulin in Centrosomes During Early Stages of Mitosis

LIM kinases (LIMK1 and LIMK2) are LIM domain containing serine/threonine kinases that modulate reorganization of actin cytoskeleton through inactivating phosphorylation of cofilin. The Rho family of small GTPases regulates the catalytic activity of LIMK1 and LIMK2 through activating phosphorylation by ROCK or by p21 kinase. Recent studies have suggested that LIMK1 could play a role in modulation of cellular growth by alteration of the cell cycle in breast and prostate tumor cells; however, the direct mitogenic effects of LIMK1 in these tumor cells is yet to be elucidated. Via immunofluorescence, in this study, we show that phosphorylated LIM kinases (pLIMK1/2) are colocalized with γ-tubulin in the centrosomes during the early mitotic phases of human breast and prostate cancer cells (MDA-MB-231 and DU145); apparent colocalization begins in the centrosomes in prophase. As shown by both bright field (MDA-MB-231) and fluorescent immunohistochemistry (MDA-MB-231 and DU145), pLIMK1/2 does not localize to centrosomes during interphase. By bright field immunohistochemistry, the largest area of the centrosome that is stained with pLIMK1/2 occurs at anaphase. In early telophase, reduced staining of pLIMK1/2 at the spindle poles and concomitant accumulation of pLIMK1/2 at the cleavage furrow begins to occur. In late telophase, loss of staining of pLIMK1/2 and of colocalization with γ-tubulin occurs at the poles and pLIMK1/2 became further concentrated at the junction between the two daughter cells. Co-immunoprecipitation studies indicated that γ-tubulin associates with phosphorylated LIMK1 and LIMK2 but not with dephosphorylated LIMK1 or LIMK2. The results suggest that activated LIMK1/2 may associate with γ-tubulin and play a role in mitotic spindle assembly.     

The LIM domains of hic-5 protein recognize specific DNA fragments in a zinc-dependent manner in vitro.

hic-5 protein is a member of the LIM protein family, containing four LIM domains in its C-terminal region. It is mainly localized in focal adhesions and shows striking similarity to paxillin in its LIM domains, although the function of these LIM domains has remained elusive. In the present study, we found that full-length and the C-terminal half of hic-5 protein, including four LIM domains, bound to DNA in a zinc-dependent manner in vitro . Mouse genomic fragments that specifically bound to the hic-5 protein were isolated by successive rounds of hic-5 protein-DNA complex immunoprecipitation and PCR amplification. Seven independent clones were isolated, which contained high amounts of G+A and/or a long A/T tract. A DNA binding protein blot assay revealed the specificity of the interaction between hic-5 protein and the DNA fragment. Using a series of truncated forms of the hic-5 LIM domains, each of the four LIM domains was found to contribute to DNA binding in a distinctive manner.     

Hic-5, a paxillin homologue, binds to the protein-tyrosine phosphatase PEST (PTP-PEST) through its LIM 3 domain

The Hic-5 protein is encoded by a transforming growth factor-beta1- and hydrogen peroxide-inducible gene, hic-5, and has striking similarity to paxillin, especially in their C-terminal LIM domains. Like paxillin, Hic-5 is localized in focal adhesion plaques in association with focal adhesion kinase in cultured fibroblasts. We carried out yeast two-hybrid screening to identify cellular factors that form a complex with Hic-5 using its LIM domains as a bait, and we identified a cytoplasmic tyrosine phosphatase (PTP-PEST) as one of the partners of Hic-5. These two proteins are associated in mammalian cells. From in vitro binding experiments using deletion and point mutations, it was demonstrated that the essential domain in Hic-5 for the binding was LIM 3. As for PTP-PEST, one of the five proline-rich sequences found on PTP-PEST, Pro-2, was identified as the binding site for Hic-5 in in vitro binding assays. Paxillin also binds to the Pro-2 domain of PTP-PEST. In conclusion, Hic-5 may participate in the regulation of signaling cascade through its interaction with distinct tyrosine kinases and phosphatases.