Lack of association between receptor protein tyrosine phosphatase RPTP mu and cadherins

RPTP mu is a receptor-like protein tyrosine phosphatase that mediates homophilic cell-cell interactions. Surface expression of RPTP mu is restricted to cell-cell contacts and is upregulated with increasing cell density, suggesting a role for RPTP mu in contact-mediated signaling. It was recently reported (Brady-Kalnay, S.M., D.L. Rimm, and N.K. Tonks. 1995. J. Cell Biol. 130:977-986) that RPTP mu binds directly to cadherin/catenin complexes, and thus may regulate the tyrosine phosphorylation of such complexes. Here we report that this concept needs revision. Through reciprocal precipitations using a variety of antibodies against RPTP mu, cadherins, and catenins, we show that RPTP mu does not interact with cadherin/catenin complexes, even when assayed under very mild lysis conditions. We find that the anti- RPTP mu antiserum used by others precipitates cadherins in a nonspecific manner independent of RPTP mu. We conclude that, contrary to previous claims, RPTP mu does not interact with cadherin complexes and thus is unlikely to directly regulate cadherin/catenin function.     

LAR protein tyrosine phosphatase receptor associates with TrkB and modulates neurotrophic signaling pathways

The identities of receptor protein tyrosine phosphatases (PTPs) that associate with Trk protein tyrosine kinase (PTK) receptors and modulate neurotrophic signaling are unknown. The leukocyte common antigen-related (LAR) receptor PTP is present in neurons expressing TrkB, and like TrkB is associated with caveolae and regulates survival and neurite outgrowth. We tested the hypothesis that LAR associates with TrkB and regulates neurotrophic signaling in embryonic hippocampal neurons. Coimmunoprecipitation and coimmunostaining demonstrated LAR interaction with TrkB that is increased by BDNF exposure. BDNF neurotrophic activity was reduced in LAR-/- and LAR siRNA-treated LAR+/+ neurons and was augmented in LAR-transfected neurons. In LAR-/- neurons, BDNF-induced activation of TrkB, Shc, AKT, ERK, and CREB was significantly decreased; while in LAR-transfected neurons, BDNF-induced CREB activation was augmented. Similarly, LAR+/+ neurons treated with LAR siRNA demonstrated decreased activation of Trk and AKT. LAR is known to activate the Src PTK by dephosphorylation of its negative regulatory domain and Src transactivates Trk. In LAR-/- neurons, or neurons treated with LAR siRNA, phosphorylation of the Src regulatory domain was increased (indicating Src inactivation), consistent with a role for Src in mediating LAR's ability to up-regulate neurotrophic signaling. Interactions between LAR, TrkB, and Src were further confirmed by the findings that Src coimmunoprecipitated with LAR, that the Src inhibitor PP2 blocked the ability of LAR to augment TrkB signaling, and that siRNA-induced depletion of Src decreased LAR interaction with TrkB. These studies demonstrate that receptor PTPs can associate with Trk complexes and promote neurotrophic signaling and point to receptor PTP-based strategies as a novel approach for modulating neurotrophin function.     

The receptor protein tyrosine phosphatase mu, PTPmu, regulates histogenesis of the chick retina

The formation of laminae within the retina requires the coordinate regulation of cell differentiation and migration. The cell adhesion molecule and member of the immunoglobulin superfamily, receptor protein tyrosine phosphatase Mu, PTPmu, is expressed in precursor and early, differentiated cells of the prelaminated retina, and later becomes restricted to the inner plexiform, ganglion cell, and optic fiber layers. Since the timing of PTPmu expression correlates with the peak period of retinal lamination, we examined whether this RPTP could be regulating cell adhesion and migration within the retina, and thus influencing retinal development. Chick retinal organ cultures were infected with herpes simplex viruses encoding either an antisense sequence to PTPmu, wild-type PTPmu, or a catalytically inactive mutant form of PTPmu, and homophilic adhesion was blocked by using a function-blocking antibody. All conditions that perturbed PTPmu dramatically disrupted retinal histogenesis. Our findings demonstrate that catalytic activity and adhesion mediated by PTPmu regulate lamination of the retina, emphasizing the importance of adhesion and signaling via receptor protein tyrosine phosphatases in the developing nervous system. To our knowledge, this is the first demonstration that an Ig superfamily RPTP regulates the lamination of any neural tissue.     

Functions of the ectodomain and cytoplasmic tyrosine phosphatase domains of receptor protein tyrosine phosphatase Dlar in vivo

The receptor protein tyrosine phosphatase (PTPase) Dlar has an ectodomain consisting of three immunoglobulin (Ig)-like domains and nine fibronectin type III (FnIII) repeats and a cytoplasmic domain consisting of two PTPase domains, membrane-proximal PTP-D1 and C-terminal PTP-D2. A series of mutant Dlar transgenes were introduced into the Drosophila genome via P-element transformation and were then assayed for their capacity to rescue phenotypes caused by homozygous loss-of-function genotypes. The Ig-like domains, but not the FnIII domains, are essential for survival. Conversely, the FnIII domains, but not the Ig-like domains, are required during oogenesis, suggesting that different domains of the Dlar ectodomain are involved in distinct functions during Drosophila development. All detectable PTPase activity maps to PTP-D1 in vitro. The catalytically inactive mutants of Dlar were able to rescue Dlar(-/-) lethality nearly as efficiently as wild-type Dlar transgenes, while this ability was impaired in the PTP-D2 deletion mutants DlarDeltaPTP-D2 and Dlar(bypass). Dlar-C1929S, in which PTP-D2 has been inactivated, increases the frequency of bypass phenotype observed in Dlar(-/-) genotypes, but only if PTP-D1 is catalytically active in the transgene. These results indicate multiple roles for PTP-D2, perhaps by acting as a docking domain for downstream elements and as a regulator of PTP-D1.     

RNA interference targeting protein tyrosine phosphatase zeta/receptor-type protein tyrosine phosphatase beta suppresses glioblastoma growth in vitro and in vivo

The protein tyrosine phosphatase zeta/receptor-type protein tyrosine phosphatase beta (PTPzeta/RPTPbeta) and its ligand pleiotrophin (PTN) are overexpressed in human glioblastomas. Both molecules are involved in neuronal cell migration during CNS development. In addition, PTN can induce glioma cell migration which is at least in part mediated through binding to PTPzeta/RPTPbeta. To study the relevance of this ligand-receptor pair for glioma growth in vitro and in vivo, we transfected the human glioblastoma cell line U251-MG with small interfering RNA (siRNA) directed against PTPzeta/RPTPbeta. Stable siRNA transfection resulted in strong down-regulation of PTPzeta/RPTPbeta expression. When injected subcutaneously into nude mice, clones that expressed normal levels of PTPzeta/RPTPbeta (PTPzeta + clones) formed exponentially growing tumours, whereas tumour growth was almost completely abrogated for clones that expressed reduced PTPzeta/RPTPbeta levels (PTPzeta - clones). Similar results were obtained using an orthotopic intracerebral model. Proliferation of PTPzeta - cells in vitro was significantly reduced compared with that of control clones. Matrix-immobilized PTN stimulated the proliferation of PTPzeta + cells but not of PTPzeta - cells. Haptotactic migration induced by PTN was reduced for PTPzeta - clones compared with control clones. Our findings suggest that antagonization of PTPzeta/RPTPbeta expression can inhibit glioma growth in vivo and may thus represent a potentially promising treatment strategy.     

The protein tyrosine phosphatase PTP-BL associates with the midbody and is involved in the regulation of cytokinesis

PTP-BL is a highly modular protein tyrosine phosphatase of unknown function. It consists of an N-terminal FERM domain, five PDZ domains, and a C-terminally located tyrosine phosphatase domain. Here we show that PTP-BL is involved in the regulation of cytokinesis. We demonstrate localization of endogenous PTP-BL at the centrosomes during inter- and metaphase and at the spindle midzone during anaphase. Finally PTP-BL is concentrated at the midbody in cytokinesis. We show that PTP-BL is targeted to the midbody and centrosome by a specific splicing variant of the N-terminus characterized by an insertion of 182 amino acids. Moreover, we demonstrate that the FERM domain of PTP-BL is associated with the contractile ring and can be cosedimented with filamentous actin, whereas the N-terminus can be cosedimented with microtubules. We demonstrate that elevating the expression level of wild-type PTP-BL or expression of PTP-BL with an inactive tyrosine phosphatase domain leads to defects in cytokinesis and to the generation of multinucleate cells. We suggest that PTP-BL plays a role in the regulation of cytokinesis.     

Receptor protein tyrosine phosphatase sigma regulates synapse structure, function and plasticity

The mechanisms that regulate synapse formation and maintenance are incompletely understood. In particular, relatively few inhibitors of synapse formation have been identified. Receptor protein tyrosine phosphatase σ (RPTPσ), a transmembrane tyrosine phosphatase, is widely expressed by neurons in developing and mature mammalian brain, and functions as a receptor for chondroitin sulfate proteoglycans that inhibits axon regeneration following injury. In this study, we address RPTPσ function in the mature brain. We demonstrate increased axon collateral branching in the hippocampus of RPTPσ null mice during normal aging or following chemically induced seizure, indicating that RPTPσ maintains neural circuitry by inhibiting axonal branching. Previous studies demonstrated a role for pre-synaptic RPTPσ promoting synaptic differentiation during development; however, subcellular fractionation revealed enrichment of RPTPσ in post-synaptic densities. We report that neurons lacking RPTPσ have an increased density of pre-synaptic varicosities in vitro and increased dendritic spine density and length in vivo. RPTPσ knockouts exhibit an increased frequency of miniature excitatory post-synaptic currents, and greater paired-pulse facilitation, consistent with increased synapse density but reduced synaptic efficiency. Furthermore, RPTPσ nulls exhibit reduced long-term potentiation and enhanced novel object recognition memory. We conclude that RPTPσ limits synapse number and regulates synapse structure and function in the mature CNS.     

The receptor protein-tyrosine phosphatase PTPmu interacts with IQGAP1

The receptor protein-tyrosine phosphatase PTPmu is a member of the Ig superfamily of cell adhesion molecules. The extracellular domain of PTPmu contains motifs commonly found in cell adhesion molecules. The intracellular domain of PTPmu contains two conserved catalytic domains, only the membrane-proximal domain has catalytic activity. The unique features of PTPmu make it an attractive molecule to transduce signals upon cell-cell contact. PTPmu has been shown to regulate cadherin-mediated cell adhesion, neurite outgrowth, and axon guidance. Protein kinase C is a component of the PTPmu signaling pathway utilized to regulate these events. To aid in the further characterization of PTPmu signaling pathways, we used a series of GST-PTPmu fusion proteins, including catalytically inactive and substrate trapping mutants, to identify PTPmu-interacting proteins. We identified IQGAP1, a known regulator of the Rho GTPases, Cdc42 and Rac1, as a novel PTPmu-interacting protein. We show that this interaction is due to direct binding. In addition, we demonstrate that amino acid residues 765-958 of PTPmu, which include the juxtamembrane domain and 35 residues of the first phosphatase domain, mediate the binding to IQGAP1. Furthermore, we demonstrate that constitutively active Cdc42, and to a lesser extent Rac1, enhances the interaction of PTPmu and IQGAP1. These data indicate PTPmu may regulate Rho-GTPase-dependent functions of IQGAP1 and suggest that IQGAP1 is a component of the PTPmu signaling pathway. In support of this, we show that a peptide that competes IQGAP1 binding to Rho GTPases blocks PTPmu-mediated neurite outgrowth.     

Receptor protein tyrosine phosphatase alpha activates Src-family kinases and controls integrin-mediated responses in fibroblasts.

BACKGROUND: Fyn and c-Src are two of the most widely expressed Src-family kinases. Both are strongly implicated in the control of cytoskeletal organization and in the generation of integrin-dependent signalling responses in fibroblasts. These proteins are representative of a large family of tyrosine kinases, the activity of which is tightly controlled by inhibitory phosphorylation of a carboxyterminal tyrosine residue (Tyr527 in chicken c-Src); this phosphorylation induces the kinases to form an inactive conformation. Whereas the identity of such inhibitory Tyr527 kinases has been well established, no corresponding phosphatases have been identified that, under physiological conditions, function as positive regulators of c-Src and Fyn in fibroblasts. RESULTS: Receptor protein tyrosine phosphatase alpha (RPTPalpha) was inactivated by homologous recombination. Fibroblasts derived from these RPTPalpha-/- mice had impaired tyrosine kinase activity of both c-Src and Fyn, and this was accompanied by a concomitant increase in c-Src Tyr527 phosphorylation. RPTPalpha-/- fibroblasts also showed a reduction in the rate of spreading on fibronectin substrates, a trait that is a phenocopy of the effect of inactivation of the c-src gene. In response to adhesion on a fibronectin substrate, RPTPalpha-/- fibroblasts also exhibited characteristic deficiencies in integrin-mediated signalling responses, such as decreased tyrosine phosphorylation of the c-Src substrates Fak and p 130(cas), and reduced activation of extracellular signal regulated (Erk) MAP kinases. CONCLUSIONS: These observations demonstrate that RPTPalpha functions as a physiological upstream activator of Src-family kinases in fibroblasts and establish this tyrosine phosphatase as a newly identified regulator of integrin signalling.     

Receptor protein tyrosine phosphatase alpha is essential for hippocampal neuronal migration and long-term potentiation

Despite clear indications of their importance in lower organisms, the contributions of protein tyrosine phosphatases (PTPs) to development or function of the mammalian nervous system have been poorly explored. In vitro studies have indicated that receptor protein tyrosine phosphatase alpha (RPTPalpha) regulates SRC family kinases, potassium channels and NMDA receptors. Here, we report that absence of RPTPalpha compromises correct positioning of pyramidal neurons during development of mouse hippocampus. Thus, RPTPalpha is a novel member of the functional class of genes that control radial neuronal migration. The migratory abnormality likely results from a radial glial dysfunction rather than from a neuron-autonomous defect. In spite of this aberrant development, basic synaptic transmission from the Schaffer collateral pathway to CA1 pyramidal neurons remains intact in Ptpra(-/-) mice. However, these synapses are unable to undergo long-term potentiation. Mice lacking RPTPalpha also underperform in the radial-arm water-maze test. These studies identify RPTPalpha as a key mediator of neuronal migration and synaptic plasticity.     

Phosphatidylinositol phosphate kinase type Igamma directly associates with and regulates Shp-1 tyrosine phosphatase

Tyrosine phosphorylation plays a critical role in many regulatory aspects of cellular signaling, and dephosphorylation of phosphotyrosine residues is crucial for termination of signals initiated by tyrosine kinases. Previous work has shown that the tyrosine kinase Src phosphorylates Tyr644 on phosphatidylinositol phosphate kinase type I (PIPKI) gamma661 in a focal adhesion kinase-dependent manner. Phosphorylation of this residue is essential for high affinity binding of PIPKI gamma661 to the focal adhesion protein talin and for targeting of PIPKI gamma661 to focal adhesions. A yeast two-hybrid screen performed with the C-terminal 178-amino acid tail of PIPKI gamma661 identified an interaction with the phosphatase domain of the tyrosine phosphatase Shp-1. The interaction between PIPKI gamma661 and Shp-1 was confirmed via co-immunoprecipitation from HEK293 cell lysates. In addition, Src-phosphorylated PIPKI gamma661 is a substrate for Shp-1, and Shp-1 modulates both the association between PIPKI gamma661 and talin and the targeting of PIPKI gamma661 to focal adhesions in mammalian cells. Finally, we showed that Shp-1 phosphatase activity is inhibited by the product of PIPKI gamma661, phosphatidylinositol 4,5-bisphosphate, in vitro. These combined results suggest a model in which the reciprocal actions of Src tyrosine kinase and Shp-1 tyrosine phosphatase dynamically regulate the association between PIPKI gamma661 and talin.     

Dimerization in vivo and inhibition of the nonreceptor form of protein tyrosine phosphatase epsilon

cyt-PTP epsilon is a naturally occurring nonreceptor form of the receptor-type protein tyrosine phosphatase (PTP) epsilon. As such, cyt-PTP epsilon enables analysis of phosphatase regulation in the absence of extracellular domains, which participate in dimerization and inactivation of the receptor-type phosphatases receptor-type protein tyrosine phosphatase alpha (RPTPalpha) and CD45. Using immunoprecipitation and gel filtration, we show that cyt-PTP epsilon forms dimers and higher-order associations in vivo, the first such demonstration among nonreceptor phosphatases. Although cyt-PTP epsilon readily dimerizes in the absence of exogenous stabilization, dimerization is increased by oxidative stress. Epidermal growth factor receptor stimulation can affect cyt-PTP epsilon dimerization and tyrosine phosphorylation in either direction, suggesting that cell surface receptors can relay extracellular signals to cyt-PTP epsilon, which lacks extracellular domains of its own. The inactive, membrane-distal (D2) phosphatase domain of cyt-PTP epsilon is a major contributor to intermolecular binding and strongly interacts in a homotypic manner; the presence of D2 and the interactions that it mediates inhibit cyt-PTP epsilon activity. Intermolecular binding is inhibited by the extreme C and N termini of D2. cyt-PTP epsilon lacking these regions constitutively dimerizes, and its activities in vitro towards para-nitrophenylphosphate and in vivo towards the Kv2.1 potassium channel are markedly reduced. We conclude that physiological signals can regulate dimerization and phosphorylation of cyt-PTP epsilon in the absence of direct interaction between the PTP and extracellular molecules. Furthermore, dimerization can be mediated by the D2 domain and does not strictly require the presence of PTP extracellular domains.     

Receptor tyrosine phosphatase R-PTP-kappa mediates homophilic binding.

Receptor tyrosine phosphatases (R-PTPases) feature PTPase domains in the context of a receptor-like transmembrane topology. The R-PTPase R-PTP-kappa displays an extracellular domain composed of fibronectin type III motifs, a single immunoglobulin domain, as well as a recently defined MAM domain (Y.-P. Jiang, H. Wang, P. D'Eustachio, J.M. Musacchio, J. Schlessinger, and J. Sap, Mol. Cell. Biol. 13:2942-2951, 1993). We report here that R-PTP-kappa can mediate homophilic intercellular interaction. Inducible expression of the R-PTP-kappa protein in heterologous cells results in formation of stable cellular aggregates strictly consisting of R-PTP-kappa-expressing cells. Moreover, the purified extracellular domain of R-PTP-kappa functions as a substrate for adhesion by cells expressing R-PTP-kappa and induces aggregation of coated synthetic beads. R-PTP-kappa-mediated intercellular adhesion does not require PTPase activity or posttranslational proteolytic cleavage of the R-PTP-kappa protein and is calcium independent. The results suggest that R-PTPases may provide a link between cell-cell contact and cellular signaling events involving tyrosine phosphorylation.     

Receptor protein tyrosine phosphatase alpha activates pp60c-src and is involved in neuronal differentiation.

Here we report that protein tyrosine phosphatases (PTPases), like their enzymatic counterpart the protein tyrosine kinases, can play an important role in cell differentiation. Expression of the transmembrane PTPase receptor protein tyrosine phosphatase alpha (RPTP alpha) is transiently enhanced during neuronal differentiation of embryonal carcinoma (EC) and neuroblastoma cells. Retinoic acid induces wild type P19 cells to differentiate into endoderm- and mesoderm-like cells. By contrast, retinoic acid treatment leads to neuronal differentiation of P19 cells, ectopically expressing functional RPTP alpha, as illustrated by their ability to generate action potentials. Endogenous pp60c-src kinase activity is enhanced in the RPTP alpha-transfected cells, which may be due to direct dephosphorylation of the regulatory Tyr residue at position 527 in pp60c-src by RPTP alpha. Our results demonstrate that RPTP alpha is involved in neuronal differentiation and imply a role for pp60c-src in the differentiation process.     

Receptor protein tyrosine phosphatases and cancer

There is general agreement that many cancers are associated with aberrant phosphotyrosine signaling, which can be caused by the inappropriate activities of tyrosine kinases or tyrosine phosphatases. Furthermore, incorrect activation of signaling pathways has been often linked to changes in adhesion events mediated by cell surface receptors. Among these receptors, receptor protein tyrosine phosphatases (RPTPs) both antagonize tyrosine kinases as well as engage extracellular ligands. A recent wealth of data on this intriguing family indicates that its members can fulfill either tumor suppressing or oncogenic roles. The interpretation of these results at a molecular level has been greatly facilitated by the recent availability of structural information on the extra- and intracellular regions of RPTPs. These structures provide a molecular framework to understand how alterations in extracellular interactions can inactivate RPTPs in cancers or why the overexpression of certain RPTPs may also participate in tumor progression.     

Catalytic inactivation of protein tyrosine phosphatase CD45 and protein tyrosine phosphatase 1B by polyaromatic quinones

Polyaromatic quinones, such as the environmental pollutants 9,10-phenanthrenediones, elicit a wide range of responses including growth inhibition, immune suppression, and glucose normalization in diabetic models. Yet the molecular mechanisms behind these effects remain controversial. Here we report that many of them are oxygen-dependent and catalytic inactivators of protein tyrosine phosphatases (PTP). Under aerobic conditions, the PTP inactivation by 2-nitro-9,10-phenanthrenedione followed a pseudo-first-order process, with the rate of inactivation increasing nearly linearly with increasing inhibitor concentration, yielding apparent inactivation rate constants of 4300, 387, and 5200 M(-1) s(-1) at pH 7.2 against CD45, PTP1B, and LAR, respectively. The rate of CD45 inactivation increased approximately 25-fold from pH 6.0 to 7.5, with complete inactivation achieved using a catalytic amount (0.05 molar equiv) of the inhibitor. The quinone-catalyzed CD45 inactivation was prevented by catalase or superoxide dismutase. Inactivated CD45 after (125)I-9,10-phenanthrenedione treatment carried no radioactivity, indicating the absence of a stable inhibitor/enzyme complex. The activity of inactivated CD45 was partially restored ( approximately 10%) by hydroxylamine or dithiothreitol, supporting the presence of a small population of sulfenic acid or sulfenyl-amide species. Treatment of PTP1B with 2-nitro-9,10-phenanthrenedione resulted in the specific and sequential oxidation of the catalytic cysteine to the sulfinic and sulfonic acid. These results suggest that reactive oxygen species and the semiquinone radical, continuously generated during quinone-catalyzed redox cycling, mediate the specific catalytic cysteine oxidation. Naturally occurring quinones may act as efficient regulators of protein tyrosine phosphorylation in biological systems. Aberrant phosphotyrosine homeostasis resulting from continued polyaromatic hydrocarbon quinone exposure may play a significant role in their disease etiology.     

The PTPmu protein-tyrosine phosphatase binds and recruits the scaffolding protein RACK1 to cell-cell contacts

PTPmu, an Ig superfamily receptor protein-tyrosine phosphatase, promotes cell-cell adhesion and interacts with the cadherin-catenin complex. The signaling pathway downstream of PTPmu is unknown; therefore, we used a yeast two-hybrid screen to identify additional PTPmu interacting proteins. The membrane-proximal catalytic domain of PTPmu was used as bait. Sequencing of two positive clones identified the scaffolding protein RACK1 (receptor for activated protein C kinase) as a PTPmu interacting protein. We demonstrate that RACK1 interacts with PTPmu when co-expressed in a recombinant baculovirus expression system. RACK1 is known to bind to the src protein-tyrosine kinase. This study demonstrates that PTPmu association with RACK1 is disrupted by the presence of constituitively active src. RACK1 is thought to be a scaffolding protein that recruits proteins to the plasma membrane via an unknown mechanism. We have shown that the association of endogenous PTPmu and RACK1 in a lung cell line is increased at high cell density. We also demonstrate that the recruitment of RACK1 to both the plasma membrane and cell-cell contact sites is dependent upon the presence of the PTP mu protein in these cells. Therefore, PTPmu may be one of the proteins that recruits RACK1 to points of cell-cell contact, which may be important for PTPmu-dependent signaling in response to cell-cell adhesion.