PDGF receptor activation induces p120-catenin phosphorylation at serine 879 via a PKCα-dependent pathway

p120-catenin (p120) is required for cadherin stability and is thought to have a central role in modulating cell-cell adhesion. Several lines of evidence suggest that S/T phosphorylation may regulate p120 activity, but the upstream kinases involved have not been established, nor has a discreet measurable function been assigned to an individual site. To approach these issues, we have generated p120 phospho-specific monoclonal antibodies to several individual phosphorylation sites and are using them to pinpoint upstream kinases and signaling pathways that control p120 activity. Protein Kinase C (PKC) has been implicated as a signaling intermediate in several cadherin-associated cellular activities. Signaling events that activate PKC induce rapid phosphorylation at p120 Serine 879 (S879), suggesting that p120 activity is regulated, in part, by one or more PKC isoforms. Here, we find that physiologic activation of a G-protein coupled receptor (i.e., endothelin receptor), as well as several Receptor Tyrosine Kinases, induce rapid and robust p120 phosphorylation at S879, suggesting that these pathways crosstalk to cadherin complexes via p120. Using Va2 cells and PDGF stimulation, we show for the first time that PDGFR-mediated phosphorylation at this site is dependent on PKCα, a conventional PKC isoform implicated previously in disruption of adherens junctions.     

Expression of the Armadillo family member p120 cas 1B in Xenopus embryos affects head differentiation but not axis formation

 The Armadillo family is formed by proteins which possess an Arm domain comprising multiple copies of a 42-amino-acid motif, the Arm repeat, initially described for the Drosophila segment polarity gene product Armadillo. The Arm domain serves in protein-protein interactions which are required for the family members Armadillo, β-catenin and plakoglobin to mediate cell-cell adhesion and Wnt/Wingless signalling. Similarily, p120 ^cas , the Arm domain containing src substrate, also binds to cadherins and becomes tyrosine phosphorylated in response to a variety of stimuli. However, a putative function of p120 ^cas in adhesion or signalling has not yet been demonstrated. It has also not been shown until now that an Arm domain is a common signal transduction motif. Using Xenopus embryos we show by expression of murine p120 ^cas 1B (mp120 ^cas 1B) in ventral blastomeres that this catenin cannot replace β-catenin function in dorsal axis formation. Thus, the presence of an Arm domain per se is not sufficient to activate the Wnt/Wg pathway. Indeed, injection of mp120 ^cas 1B into dorsal blastomeres led instead to delayed blastopore closure and posteriorized phenotypes with malformed head structures indicative of disturbed gastrulation movements. Because neither convergent extension behaviour nor adhesion to fibronectin was altered in the injected embryos we assume that mp120 ^cas 1B influences motility or orientation of migrating mesodermal cells. Received: 29 September 1997 / Accepted: 15 November 1997     

FERM-containing protein FRMD5 is a p120-catenin interacting protein that regulates tumor progression

FERM family proteins have been known to play an important role in tumor progression. FERM-domain containing protein 5 (FRMD5), a novel putative cytoskeletal protein, is an unknown function protein. Here, we reported that FRMD5 localized at the cell adherens junction and formed a molecular complex with p120-catenin through its C-terminal region. Functionally, we found that knockdown of endogenous FRMD5 promotes lung cancer cell migration and invasion in vitro as well as tumor growth in vivo, suggesting a tumor suppressive effect. These findings indicated that FRMD5 may play a role in p120-catenin-based cell-cell contact and is involved in the regulation of tumor progression.

Structured summary of protein interactions

FRMD5 and p120 catenincolocalize by fluorescence microscopy (View interaction) FRMD5physically interacts with p120 catenin by anti tag coimmunoprecipitation (View interaction)FRMD5 and Beta-catenincolocalize by fluorescence microscopy (View interaction)FRMD5 and gamma-catenincolocalize by fluorescence microscopy (View interaction) FRMD5physically interacts with p120 catenin and E cadherin by anti bait coimmunoprecipitation (View interaction)     

Protective role of p120-catenin in maintaining the integrity of adherens and tight junctions in ventilator-induced lung injury

Background

Ventilator-induced lung injury (VILI) is one of the most common complications for patients with acute lung injury (ALI) or acute respiratory distress syndrome (ARDS). Although p120 is an important protein in the regulation of cell junctions, further mechanisms should be explored for prevention and treatment of VILI.

Methods

Mouse lung epithelial cells (MLE-12), which were transfected with p120 small interfering (si)RNA, p120 cDNA, wild-type E-cadherin juxtamembrane domain or a K83R mutant juxtamembrane domain (K83R-JMD), were subjected to 20 % cyclic stretches for 2 or 4 h. Furthermore, MLE-12 cells and mice, which were pretreated with the c-Src inhibitor PP₂ or RhoA inhibitor Y27632, underwent 20 % cyclic stretches or mechanical stretching, respectively. Moreover, wild-type C57BL/6 mice were transfected with p120 siRNA-liposome complexes before mechanical ventilation. Cell lysates and lung tissues were then analyzed to detect lung injury.

Results

cyclic stretches of 20 % actived c-Src, which induced degradation of E-cadherin, p120 and occludin. However, loss of p120 increased the degradation and endocytosis of E-cadherin. Immunoprecipitation and Immunofluorescence results showed a decrease in the association between p120 and E-cadherin, while gap formation increased in p120 siRNA and K83R-JMD groups after 20 % cyclic stretches. Loss of p120 also reduced the occludin level and decreased the association of occludin and ZO-1 by enhancing RhoA activity. However, the altered levels of occludin and E-cadherin were reversed by PP₂ or Y27632 treatments compared with the cyclic stretch group. Consistently, the expression, redistribution and disassociation of junction proteins were all restored in the p120 overexpression group after 20 % cyclic stretches. Moreover, the role of p120 in VILI was confirmed by increased wet/dry weigh ratio and enhanced production of cytokines (tumor necrosis factor-α and interleukin-six) in p120-depleted mice under mechanical ventilation.

Conclusions

p120 protected against VILI by regulating both adherens and tight junctions. p120 inhibited E-cadherin endocytosis by increasing the association between p120 and juxtamembrane domain of E-cadherin. Furthermore, p120 reduced the degradation of occludin by inhibiting RhoA activity. These findings illustrated further mechanisms of p120 in the prevention of VILI, especially for patients with ALI or ARDS.     

A core function for p120-catenin in cadherin turnover

p120-catenin stabilizes epithelial cadherin (E-cadherin) in SW48 cells, but the mechanism has not been established. Here, we show that p120 acts at the cell surface to control cadherin turnover, thereby regulating cadherin levels. p120 knockdown by siRNA expression resulted in dose-dependent elimination of epithelial, placental, neuronal, and vascular endothelial cadherins, and complete loss of cell-cell adhesion. ARVCF and delta-catenin were functionally redundant, suggesting that proper cadherin-dependent adhesion requires the presence of at least one p120 family member. The data reveal a core function of p120 in cadherin complexes, and strongly predict a dose-dependent loss of E-cadherin in tumors that partially or completely down-regulate p120.     

Regulation by nectin of the velocity of the formation of adherens junctions and tight junctions

Cadherins are key Ca(2+)-dependent cell-cell adhesion molecules at adherens junctions (AJs) in fibroblasts and epithelial cells, whereas claudins are key Ca(2+)-independent cell-cell adhesion molecules at tight junctions (TJs) in epithelial cells. The formation and maintenance of TJs are dependent on the formation and maintenance of AJs. Nectins are Ca(2+)-independent immunoglobulin-like cell-cell adhesion molecules which comprise a family of four members, nectin-1, -2, -3, and -4, and are involved in the formation of AJs in cooperation with cadherins, and the subsequent formation of TJs. We show here that the velocity of the formation of the E-cadherin-based AJs is increased by overexpression of nectin-1 and is reduced by addition of the nectin-1 inhibitors to the medium in L cells stably expressing E-cadherin and Madin-Darby canine kidney cells. Moreover, the velocity of the formation of the claudin-based TJs is increased by overexpression of nectin-1 and is reduced by addition of the nectin-1 inhibitors to the medium in Madin-Darby canine kidney cells. These results indicate that nectins regulate the velocity of the formation of the E-cadherin-based AJs and the subsequent formation of the claudin-based TJs.     

Interaction of p190RhoGAP with C-terminal Domain of p120-catenin Modulates Endothelial Cytoskeleton and Permeability

p120-catenin is a multidomain intracellular protein, which mediates a number of cellular functions, including stabilization of cell-cell transmembrane cadherin complexes as well as regulation of actin dynamics associated with barrier function, lamellipodia formation, and cell migration via modulation of the activities of small GTPAses. One mechanism involves p120 catenin interaction with Rho GTPase activating protein (p190RhoGAP), leading to p190RhoGAP recruitment to cell periphery and local inhibition of Rho activity. In this study, we have identified a stretch of 23 amino acids within the C-terminal domain of p120 catenin as the minimal sequence responsible for the recruitment of p190RhoGAP (herein referred to as CRAD; catenin-RhoGAP association domain). Expression of the p120-catenin truncated mutant lacking the CRAD in endothelial cells attenuated effects of barrier protective oxidized phospholipid, OxPAPC. This effect was accompanied by inhibition of membrane translocation of p190RhoGAP, increased Rho signaling, as well as suppressed activation of Rac1 and its cytoskeletal effectors PAK1 (p21-activated kinase 1) and cortactin. Expression of p120 catenin-truncated mutant lacking CRAD also delayed the recovery process after thrombin-induced endothelial barrier disruption. Concomitantly, RhoA activation and downstream signaling were sustained for a longer period of time, whereas Rac signaling was inhibited. These data demonstrate a critical role for p120-catenin (amino acids 820–843) domain in the p120-catenin·p190RhoGAP signaling complex assembly, membrane targeting, and stimulation of p190RhoGAP activity toward inhibition of the Rho pathway and reciprocal up-regulation of Rac signaling critical for endothelial barrier regulation.     

Adhesion-associated and PKC-modulated changes in serine/threonine phosphorylation of p120-catenin

p120-catenin (p120) was originally identified as a tyrosine kinase substrate, and subsequently shown to regulate cadherin-mediated cell-cell adhesion. Binding of the p120 Arm domain to E-cadherin appears to be necessary to maintain adequate cadherin levels for strong adhesion. In contrast, the sequence amino-terminal to the Arm domain confers a negative regulatory function that is likely to be modulated by phosphorylation. Several agents that induce rapid changes in cell-cell adhesion, including PDBu, histamine, thrombin, and LPA, result in significant changes in p120 S/T phosphorylation. In some cases, these changes are PKC-dependent, but the relationship among adhesion, PKC activation, and p120 phosphorylation is unclear, in part because the relevant p120 phosphorylation sites are unknown. As a crucial step toward directly identifying the function of these modifications in adhesion, we have used two-dimensional tryptic mapping and site-directed mutagenesis to pinpoint the constitutive and PKC-modulated sites of p120 S/T phosphorylation. Of eight sites that have been identified, two were selectively phosphorylated in vitro by GSK3 beta, but in vivo treatment of cells with GSK3 beta inhibitors did not eliminate these sites. PKC stimulation in vivo induced potent dephosphorylation at S268, and partial dephosphorylation of several additional sites. Surprisingly, PKC also strongly induced phosphorylation at S873. These data directly link PKC activation to specific changes in p120 phosphorylation, and identify the target sites associated with the mechanism of PKC-dependent adhesive changes induced by agents such as histamine and PDBu.     

The regulatory or phosphorylation domain of p120 catenin controls E-cadherin dynamics at the plasma membrane

In contrast to growth factor-stimulated tyrosine phosphorylation of p120, its relatively constitutive serine/threonine phosphorylation is not well understood. Here we examined the role of serine/threonine phosphorylation of p120 in cadherin function. Expression of cadherins in cadherin-null cells converted them to an epithelial phenotype, induced p120 phosphorylation and localized it to sites of cell contact. Detergent solubility and immunofluorescence confirmed that phosphorylated p120 was at the plasma membrane. E-cadherin constructs incapable of traveling to the plasma membrane did not induce serine/threonine phosphorylation of p120, nor did cadherins constructs incapable of binding p120. However, an E-cadherin cytoplasmic domain construct artificially targeted to the plasma membrane did induce serine/threonine phosphorylation of p120, suggesting phosphorylation occurs independently of signals from cadherin dimerization and trafficking through the ER/Golgi. Solubility assays following calcium switch showed that p120 isoform 3A was more effective at stabilizing E-cadherin at the plasma membrane relative to isoform 4A. Since the major phosphorylation domain of p120 is included in isoform 3A but not 4A, we tested p120 mutated in the known phosphorylation sites in this domain and found that it was even less effective at stabilizing E-cadherin. These data suggest that serine/threonine phosphorylation of p120 influences the dynamics of E-cadherin in junctions.     

p120‐catenin differentially regulates cell migration by Rho‐dependent intracellular and secreted signals

The adherens junction protein p120‐catenin is implicated in the regulation of cadherin stability, cell migration and inflammatory responses in mammalian epithelial tissues. How these events are coordinated to promote wound repair is not understood. We show that p120 catenin regulates the intrinsic migratory properties of primary mouse keratinocytes, but also influences the migratory behavior of neighboring cells by secreted signals. These events are rooted in the ability of p120‐catenin to regulate RhoA GTPase activity, which leads to a two‐tiered control of cell migration. One restrains cell motility via an increase in actin stress fibers, reduction in integrin turnover and an increase in the robustness of focal adhesions. The other is coupled to the secretion of inflammatory cytokines including interleukin‐24, which causally enhances randomized cell movements. Taken together, our results indicate that p120‐RhoA‐GTPase‐mediated signaling can differentially regulate the migratory behavior of epidermal cells, which has potential implications for chronic wound responses and cancer.     

Nonenzymatic phosphorylation of tyrosine and serine by ATP is catalyzed by manganese but not magnesium

Many cellular and retroviral protein-tyrosine kinases display either a requirement or a preference for manganese over magnesium for maximal activity. We have observed that peptides and proteins are non-enzymatically phosphorylated at tyrosine and serine by ATP when heated in the presence of MnCl2 at neutral pH. The extent of the reaction is negligible below 50 degrees C but increases rapidly at higher temperatures. The reaction proceeds in the presence of sodium dodecyl sulfate but is blocked by EDTA. No reaction is observed in the absence of Mn2+, even if Mg2+ is present. Manganese therefore acts as a catalyst for the non-enzymatic reaction, but magnesium does not. We propose that the preference for manganese shown by many protein tyrosine kinases is due at least in part to the intrinsic ability of Mn2+ to catalyze the transfer of phosphate from ATP to a phosphate acceptor such as tyrosine. The nonenzymatic phosphorylation reaction also offers a new synthetic pathway for the preparation of radiolabeled peptides containing phosphotyrosine and phosphoserine.     

Atheroma development in apolipoprotein E-null mice is not regulated by phosphorylation of p27(Kip1) on threonine 187

Excessive cellular proliferation is thought to contribute to neointimal lesion development during atherosclerosis and restenosis after angioplasty. Inhibition of cyclin-dependent kinase (CDK) activity by p27 inhibits mammalian cell growth. Mounting evidence indicates that p27 negatively regulates neointimal thickening in animal models of restenosis and atherosclerosis, and its expression in human neointimal lesions is consistent with such a protective role. Cell cycle progression is facilitated by cyclinE/CDK2-dependent phosphorylation of p27 on threonine 187 (T187) during late G1. The purpose of this study was to assess whether this phosphorylation event plays a role during atherosclerosis. To this end, we generated apolipoprotein E-null mice with both p27 alleles replaced by a mutated form non-phosphorylatable at T187 (apoE-/-p27T187A mice) and investigated the kinetics of atheroma development in these animals compared to apoE-/- controls with an intact p27 gene. Fat feeding resulted in comparable level of hypercholesterolemia in both groups of mice. Surprisingly, aortic p27 expression was not increased in fat-fed apoE-/-p27T187A mice compared with apoE-/- controls. Moreover, atheroma size, lesion cellularity, proliferation, and apoptotic rates were undistinguishable in both groups of fat-fed mice. Thus, in contrast to previous studies that highlight the importance of p27 phosphorylation at T187 on the control of p27 expression and function in different tissues and pathophysiological scenarios, our findings demonstrate that this phosphorylation event is not implicated in the control of aortic p27 expression and atheroma progression in hypercholesterolemic mice.     

p120(ctn) acts as an inhibitory regulator of cadherin function in colon carcinoma cells

p120(ctn) binds to the cytoplasmic domain of cadherins but its role is poorly understood. Colo 205 cells grow as dispersed cells despite their normal expression of E-cadherin and catenins. However, in these cells we can induce typical E-cadherin-dependent aggregation by treatment with staurosporine or trypsin. These treatments concomitantly induce an electrophoretic mobility shift of p120(ctn) to a faster position. To investigate whether p120(ctn) plays a role in this cadherin reactivation process, we transfected Colo 205 cells with a series of p120(ctn) deletion constructs. Notably, expression of NH2-terminally deleted p120(ctn) induced aggregation. Similar effects were observed when these constructs were introduced into HT-29 cells. When a mutant N-cadherin lacking the p120(ctn)-binding site was introduced into Colo 205 cells, this molecule also induced cell aggregation, indicating that cadherins can function normally if they do not bind to p120(ctn). These findings suggest that in Colo 205 cells, a signaling mechanism exists to modify a biochemical state of p120(ctn) and the modified p120(ctn) blocks the cadherin system. The NH2 terminus-deleted p120(ctn) appears to compete with the endogenous p120(ctn) to abolish the adhesion-blocking action.     

FAT1 cadherin is multiply phosphorylated on its ectodomain but phosphorylation is not catalysed by the four-jointed homologue

The interaction between the Drosophila cadherins fat and dachsous is regulated by phosphorylation of their respective ectodomains, a process catalysed by the atypical kinase four-jointed. Given that many signalling functions are conserved between Drosophila and vertebrate Fat cadherins, we sought to determine whether ectodomain phosphorylation is conserved in FAT1 cadherin, and also whether FJX1, the vertebrate orthologue of four-jointed, was involved in such phosphorylation events. Potential Fj consensus phosphorylation motifs were identified in FAT1 and biochemical experiments revealed the presence of phosphoserine and phosphothreonine residues in its extracellular domain. However, silencing FJX1 did not influence the levels of FAT1 ectodomain phosphorylation, indicating that other mechanisms are likely responsible.     

p120‐catenin is a binding partner and substrate for Group B Pak kinases

Pak5 is a member of the Group B p21‐activated kinases, which are effectors of the Rho family GTPases Cdc42 and Rac. Pak5 has been shown to promote cytoskeletal reorganization, inducing filopodia formation and neurite outgrowth in neuroblastoma cells. In this study, we used affinity chromatography followed by SDS–PAGE and mass spectrometry to identify potential downstream effectors of Pak5. Using this approach, we isolated p120‐catenin (p120), a known regulator of cytoskeletal reorganization and Rho GTPases. Using co‐immunoprecipitation assays we found that p120 preferentially interacts with Pak5 among the Group B Paks. Results from immunofluorescence studies revealed that Pak5 and p120 co‐localize in cells. Both Pak5 and constitutively active Pak4, the founding member of the Group B Paks, directly phosphorylate p120 in vitro. The phosphorylation was shown by Western blot and immunofluorescence to take place specifically on serine 288. This study is the first report of an upstream serine/threonine kinase that phosphorylates p120. J. Cell. Biochem. 110: 1244–1254, 2010. Published 2010 Wiley‐Liss, Inc.     

E-Cadherin negatively modulates delta-catenin-induced morphological changes and RhoA activity reduction by competing with p190RhoGEF for delta-catenin

δ-Catenin is a member of the p120-catenin subfamily of armadillo proteins. Here, we describe distinctive features of δ-catenin localization and its association with E-cadherin in HEK293 epithelial cells. In HEK293 cells maintained in low cell densities, approximately 15% of cells overexpressing δ-catenin showed dendrite-like process formation, but there was no detectable change in RhoA activity. In addition, δ-catenin was localized mainly in the cytoplasm and was associated with p190RhoGEF. However, at high cell densities, δ-catenin localization was shifted to the plasma membrane. The association of δ-catenin with E-cadherin was strengthened, whereas its interaction with p190RhoGEF was weakened. In mouse embryonic fibroblast cell, ectopic expression of E-cadherin decreased the effect of δ-catenin on the reduction of RhoA activity as well as on dendrite-like process formation. These results suggest that δ-catenin is more dominantly bound to E-cadherin than to p190RhoGEF, and that δ-catenin’s function is dependent on its cellular binding partner.     

An octapeptide in the juxtamembrane domain of VE-cadherin is important for p120ctn binding and cell proliferation

The cadherins are a family of adhesive proteins involved in cell-cell homophilic interactions. VE-cadherin, expressed in endothelial cells, is involved in morphogenesis, regulation of permeability, and cellular proliferation. The cytoplasmic tails of cadherins contain two major domains, the juxtamembrane domain that plays a role in the intercellular localization of the protein and also serves for binding of p120ctn, and a C-terminal domain that associates with beta- or gamma-catenin. A highly conserved region present in the juxtamembrane domain of the cadherins has been shown to be necessary for p120ctn binding in E-cadherin. Using a mutant VE-cadherin lacking a highly conserved octapeptide, we demonstrated that it is required for p120ctn binding to VE-cadherin as determined by immunoprecipitation and colocalization studies. By immunofluorescence, this mutant protein has a topographical distribution similar to that of the wild-type VE-cadherin and, therefore, we conclude that the topographical distribution of VE-cadherin is independent of this motif. In addition, although cell-cell association is present in cells expressing this mutant form of VE-cadherin, we found that the strength of adhesion is decreased. Finally, our results for the first time demonstrate that the interaction of VE-cadherin with p120 catenin plays an important role in cellular growth, suggesting that the binding of p120 catenin to cadherins may regulate cell proliferation.