Regulation Of Protein Tyrosine Phosphatases Research Articles

Protein Tyrosine Phosphatase regulation by Reactive Oxygen Species.

Protein Tyrosine Phosphatases (PTPs) help to maintain the balance of protein phosphorylation signals that drive cell division, proliferation, and differentiation. These enzymes are also well-suited to redox-dependent signaling and oxidative stress response due to their cysteine-based catalytic mechanism, which requires a deprotonated thiol group at the active site. This review focuses on PTP structural characteristics, active site chemical properties, and vulnerability to change by reactive oxygen species (ROS). PTPs can be oxidized and inactivated by H2O2 through three non-exclusive mechanisms. These pathways are dependent on the coordinated actions of other H2O2-sensitive proteins, such as peroxidases like Peroxiredoxins (Prx) and Thioredoxins (Trx). PTPs undergo reversible oxidation by converting their active site cysteine from thiol to sulfenic acid. This sulfenic acid can then react with adjacent cysteines to form disulfide bonds or with nearby amides to form sulfenyl-amide linkages. Further oxidation of the sulfenic acid form to the sulfonic or sulfinic acid forms causes irreversible deactivation. Understanding the structural changes involved in both reversible and irreversible PTP oxidation can help with their chemical manipulation for therapeutic intervention. Nonetheless, more information remains unidentified than is presently known about the precise dynamics of proteins participating in oxidation events, as well as the specific oxidation states that can be targeted for PTPs. This review summarizes current information on PTP-specific oxidation patterns and explains how ROS-mediated signal transmission interacts with phosphorylation-based signaling machinery controlled by growth factor receptors and PTPs.

Detecting PTP Protein-Protein Interactions by Fluorescent Immunoprecipitation Analysis (FIPA).

Identifying protein-protein interactions is crucial for revealing protein functions and characterizing cellular processes. Manipulating PPIs has become widespread in treating human diseases such as cancer, autoimmunity, and infections. It has been recently applied to the regulation of protein tyrosine phosphatases (PTPs) previously considered undruggable. A broad panel of methods is available for studying PPIs. To complement the existing toolkit, we developed a simple method called fluorescent immunoprecipitation analysis (FIPA). This method is based on coimmunoprecipitation followed by protein gel electrophoresis and fluorescent imaging to visualize components of a protein complex simultaneously on a gel. The FIPA allows the detection of proteins expressed under native conditions and is compatible with mass spectrometry identification of protein bands.

Macromolecular crowding amplifies allosteric regulation of T-cell protein tyrosine phosphatase

T-cell protein tyrosine phosphatase (TC-PTP) is a negative regulator of T-cell receptor and oncogenic receptor tyrosine kinase signaling and implicated in cancer and autoimmune disease. TC-PTP activity is modulated by an intrinsically disordered C-terminal region (IDR) and suppressed in cells under basal conditions. Invitro structural studies have shown that the dynamic reorganization of IDR around the catalytic domain, driven by electrostatic interactions, can lead to TC-PTP activity inhibition; however, the process has not been studied in cells. Here, by assessing a mutant (378KRKRPR383 mutated into 378EAAAPE383, called TC45E/A) with impaired tail-PTP domain interaction, we obtained evidence that the downmodulation of TC-PTP enzymatic activity by the IDR occurs in cells. However, we found that the regulation of TC-PTP by the IDR is only recapitulated invitro when crowding polymers that mimic the intracellular environment are present in kinetic assays using a physiological phosphopeptide. Our FRET-based assays invitro and in cells confirmed that the effect of the mutant correlates with an impairment of the intramolecular inhibitory remodeling of TC-PTP by the IDR. This work presents an early example of the allosteric regulation of a protein tyrosine phosphatase being controlled by the cellular environment and provides a framework for future studies and targeting of TC-PTP function.

Regulation of CD4+ T Cell Signaling and Immunological Synapse by Protein Tyrosine Phosphatases: Molecular Mechanisms in Autoimmunity.

T cell activation and effector function is mediated by the formation of a long-lasting interaction established between T cells and antigen-presenting cells (APCs) called immunological synapse (IS). During T cell activation, different signaling molecules as well as the cytoskeleton and the endosomal compartment are polarized to the IS. This molecular dynamics is tightly regulated by phosphorylation networks, which are controlled by protein tyrosine phosphatases (PTPs). While some PTPs are known to be important regulators of adhesion, ligand discrimination or the stimulation threshold, there is still little information about the regulatory role of PTPs in cytoskeleton rearrangements and endosomal compartment dynamics. Besides, spatial and temporal regulation of PTPs and substrates at the IS is only barely known. Consistent with an important role of PTPs in T cell activation, multiple mutations as well as altered expression levels or dynamic behaviors have been associated with autoimmune diseases. However, the precise mechanism for the regulation of T cell activation and effector function by PTPs in health and autoimmunity is not fully understood. Herein, we review the current knowledge about the regulatory role of PTPs in CD4+ T cell activation, IS assembly and effector function. The potential molecular mechanisms mediating the action of these enzymes in autoimmune disorders are discussed.

NMR Relaxation Dispersion

NMR relaxation dispersion experiments are used to characterize millisecond and microsecond motions and the role of these motions in regulation of protein tyrosine phosphatases (PTPs) In a pair of mechanistically indistinguishable PTPs with catalytic rates that vary by 50‐fold these experiments indicate that catalytic activity is regulated by the rate of active site loop closure. Furthermore, it is observed that small molecule binding distant from the active site loop alters the kinetic rates of substrate catalysis as well as the dynamics of loop closure.

Reactive Nitrogen Species and Hydrogen Sulfide as Regulators of Protein Tyrosine Phosphatase Activity

Redox modifications of thiols serve as a molecular code enabling precise and complex regulation of protein tyrosine phosphatases (PTPs) and other proteins. Particular gasotransmitters and even the redox modifications themselves affect each other, of which a typical example is S-nitrosylation-mediated protection against the further oxidation of protein thiols. For a long time, PTPs were considered constitutively active housekeeping enzymes. This view has changed substantially over the last two decades, and the PTP family is now recognized as a group of tightly and flexibly regulated fundamental enzymes. In addition to the conventional ways in which they are regulated, including noncovalent interactions, phosphorylation, and oxidation, the evidence that has accumulated during the past two decades suggests that many of these enzymes are also modulated by gasotransmitters, namely by nitric oxide (NO) and hydrogen sulfide (H2S). The specificity and selectivity of the methods used to detect nitrosylation and sulfhydration remains to be corroborated, because several researchers raised the issue of false-positive results, particularly when using the most widespread biotin switch method. Further development of robust and straightforward proteomic methods is needed to further improve our knowledge of the full extent of the gasotransmitters-mediated changes in PTP activity, selectivity, and specificity. FURTHER DIRECTIONS: Results of the hitherto performed studies on gasotransmitter-mediated PTP signaling await translation into clinical medicine and pharmacotherapeutics. In addition to directly affecting the activity of particular PTPs, the use of reversible S-nitrosylation as a protective mechanism against oxidative stress should be of high interest.

Investigating redox regulation of protein tyrosine phosphatases using low pH thiol labeling and enrichment strategies coupled to MALDI-TOF mass spectrometry

A central feature of the protein tyrosine phosphatase (PTP) catalytic mechanism is an attack of the substrate’s phosphate moiety by a thiolate ion in the signature CX5R motif. In addition to being an effective nucleophile in this form, the thiolate ion is also susceptible to reversible redox regulation. This attribute permits temporal inhibition of PTP activities, which affects numerous cellular processes utilizing kinase-mediated signal propagation. Accumulating evidence has revealed diverse mechanisms adopted by PTPs to avoid irreversible thiol oxidation of the active site Cys residue, often involving structurally proximal thiols within the active site region. Therefore, there has been a significant effort made to develop thiol labeling strategies coupled to mass spectrometry to identify and characterize redox sensitive thiols within PTPs as a necessary step in understanding how a particular PTP is regulated by redox signaling. A common drawback to many current methods is the use of neutral pH labeling techniques, requiring special attention with regards to non-specific thiol oxidation during sample preparation. This study describes the use of rapid, low pH thiol labeling methods to overcome this issue. Mercury immobilized metal affinity chromatography (Hg-IMAC) demonstrated high selectivity and specificity while enriching for thiol-containing peptides from the atypical dual specificity phosphatase hYVH1 (also known as DUSP12). This approach revealed several reversibly oxidized thiols within the catalytic domain of hYVH1. Subsequently, use of another low pH labeling reagent, 4,4-dithiopyridine (4-DTP) helped identify novel disulfide linkages providing evidence that hYVH1 utilizes a disulfide exchange mechanism to prevent irreversible oxidation of the catalytic Cys residue in the active site.

Redox regulation of protein kinases

Reactive oxygen species (ROS) have been long regarded as by-products of a cascade of reactions stemming from cellular oxygen metabolism, which, if they accumulate to toxic levels, can have detrimental effects on cellular biomolecules. However, more recently, the recognition of ROS as mediators of cellular communications has led to their classification as signalling mediators in their own right. The prototypic redox-regulated targets downstream of ROS are the protein tyrosine phosphatases, and the wealth of research that has focused on this area has come to shape our understanding of how redox-signalling contributes to and facilitates protein tyrosine phosphorylation signalling cascades. However, it is becoming increasingly apparent that there is more to this system than simply the negative regulation of protein tyrosine phosphatases. Identification of redox-sensitive kinases such as Src led to the slow emergence of a role for redox regulation of tyrosine kinases. A flow of evidence, which has increased exponentially in recent times as a result of the development of new methods for the detection of oxidative modifications, demonstrates that, by concurrent oxidative activation of tyrosine kinases, ROS fine tune the duration and amplification of the phosphorylation signal. A more thorough understanding of the complex regulatory mechanism of redox-modification will allow targeting of both the production of ROS and their downstream effectors for therapeutic purposes. The present review assesses the most relevant recent literature that demonstrates a role for kinase regulation by oxidation, highlights the most significant findings and proposes future directions for this crucial area of redox biology.

Regulation of protein tyrosine phosphatases by reversible oxidation

Oxidation of the catalytic cysteine of protein-tyrosine phosphatases (PTP), which leads to their reversible inactivation, has emerged as an important regulatory mechanism linking cellular tyrosine phosphorylation and signalling by reactive-oxygen or -nitrogen species (ROS, RNS). This review focuses on recent findings about the involved pathways, enzymes and biochemical mechanisms. Both the general cellular redox state and extracellular ligand-stimulated ROS production can cause PTP oxidation. Members of the PTP family differ in their intrinsic susceptibility to oxidation, and different types of oxidative modification of the PTP catalytic cysteine can occur. The role of PTP oxidation for physiological signalling processes as well as in different pathologies is described on the basis of well-investigated examples. Criteria to establish the causal involvement of PTP oxidation in a given process are proposed. A better understanding of mechanisms leading to selective PTP oxidation in a cellular context, and finding ways to pharmacologically modulate these pathways are important topics for future research.

Redox Regulation of Protein Tyrosine Phosphatases: Structural and Chemical Aspects

Protein tyrosine phosphatases (PTPs) are important targets of the H(2)O(2) that is produced during mammalian signal transduction. H(2)O(2)-mediated inactivation of PTPs also may be important in various pathophysiological conditions involving oxidative stress. Here we review the chemical and structural biology of redox-regulated PTPs. Reactions of H(2)O(2) with PTPs convert the catalytic cysteine thiol to a sulfenic acid. In PTPs, the initially generated sulfenic acid residues have the potential to undergo secondary reactions with a neighboring amide nitrogen or cysteine thiol residue to yield a sulfenyl amide or disulfide, respectively. The chemical mechanisms by which formation of sulfenyl amide and disulfide linkages can protect the catalytic cysteine residue against irreversible overoxidation to sulfinic and sulfonic oxidation states are described. Due to the propensity for back-door and distal cysteine residues to engage with the active-site cysteine after oxidative inactivation, differences in the structures of the oxidatively inactivated PTPs may stem, to a large degree, from differences in the number and location of cysteine residues surrounding the active site of the enzymes. PTPs with key cysteine residues in structurally similar locations may be expected to share similar mechanisms of oxidative inactivation.

Toxicological Disruption of Signaling Homeostasis: Tyrosine Phosphatases as Targets

The protein tyrosine phosphatases (PTPs) consist of a diverse group of enzymes whose activity opposes that of the tyrosine kinases. As such, the PTPs have critical roles in maintaining signaling quiescence in resting cells and in restoring homeostasis by effecting signal termination. Interest in these enzymes has increased in recent years following the discovery that the activity of PTPs is modulated through redox mechanisms during signaling. The molecular features that enable redox regulation of PTPs during physiological signaling also render them highly susceptible to oxidative and electrophilic inactivation by a broad spectrum of structurally disparate xenobiotic compounds. The loss of PTP activity results in a profound disregulation of protein phosphotyrosine metabolism, leading to widespread and persistent activation of signaling cascades in the cell.

Role of protein-tyrosine phosphatases in regulation of osteoclastic activity.

Osteoclasts, the primary cell type mediating bone resorption, are multinucleated, giant cells derived from hematopoietic cells of monocyte-macrophage lineage. Osteoclast activity is, in a large part, regulated by protein-tyrosine phosphorylation. While information about functional roles of several protein-tyrosine kinases (PTK), including c-Src, in osteoclastic resorption has been accumulated, little is known about the roles of protein-tyrosine phosphatases (PTPs) in regulation of osteoclast activity. Recent evidence implicates important regulatory roles for four PTPs (SHP-1, cyt-PTP-epsilon, PTP-PEST, and PTPoc) in osteoclasts. Cyt-PTP-epsilon, PTP-PEST, and PTP-oc are positive regulators of osteoclast activity, while SHP-1 is a negative regulator. Of these PTPs in osteoclasts, only PTP-oc is a positive regulator of c-Src PTK through dephosphorylation of the inhibitory phosphotyrosine-527 residue. Although some information about mechanisms of action of these PTPs to regulate osteoclast activity is reviewed in this article, much additional work is required to provide more comprehensive details about their functions in osteoclasts.

Redox Regulation of SH2-Domain-Containing Protein Tyrosine Phosphatases by Two Backdoor Cysteines

Protein tyrosine phosphatases (PTPs) are known to be regulated by phosphorylation, localization, and protein-protein interactions. More recently, redox-dependent inactivation has emerged as a critical factor in attenuating PTP activity in response to cellular stimuli. The tandem Src homology 2 domain-containing PTPs (SHPs) belong to the family of nonreceptor PTPs whose activity can be modulated by reversible oxidation in vivo. Herein we have investigated in vitro the kinetic and mechanistic details of reversible oxidation of SHP-1 and SHP-2. We have confirmed the susceptibility of the active site cysteines of SHPs to oxidative inactivation, with rate constants for oxidation similar to other PTPs (2-10 M(-1) s(-1)). Both SHP-1 and SHP-2 can be reduced and reactivated with the reductants DTT and gluthathione, whereas only the catalytic domain of SHP-2 is subject to reactivation by thioredoxin. Stabilization of the reversible oxidation state of the SHPs proceeds via a novel mechanism unlike for other PTPs wherein oxidation yields either a disulfide between the catalytic cysteine and a nearby "backdoor" cysteine or a sulfenylamide bond with the amide backbone nitrogen of the adjacent amino acid. Instead, in the reversibly oxidized and inactivated SHPs, the catalytic cysteine is rereduced while two conserved backdoor cysteines form an intramolecular disulfide. Formation of this backdoor-backdoor disulfide is dependent on the presence of the active site cysteine and can proceed via either active site cysteine-backdoor cysteine intermediate. Removal of both backdoor cysteines leads to irreversible oxidative inactivation, demonstrating that these two cysteines are necessary and sufficient for ensuring reversible oxidation of the SHPs. Our results extend the mechanisms by which redox regulation of PTPs is used to modulate intracellular signaling pathways.

Cysteine S-Nitrosylation Protects Protein-tyrosine Phosphatase 1B against Oxidation-induced Permanent Inactivation

Protein S-nitrosylation mediated by cellular nitric oxide (NO) plays a primary role in executing biological functions in cGMP-independent NO signaling. Although S-nitrosylation appears similar to Cys oxidation induced by reactive oxygen species, the molecular mechanism and biological consequence remain unclear. We investigated the structural process of S-nitrosylation of protein-tyrosine phosphatase 1B (PTP1B). We treated PTP1B with various NO donors, including S-nitrosothiol reagents and compound-releasing NO radicals, to produce site-specific Cys S-nitrosylation identified using advanced mass spectrometry (MS) techniques. Quantitative MS showed that the active site Cys-215 was the primary residue susceptible to S-nitrosylation. The crystal structure of NO donor-reacted PTP1B at 2.6 A resolution revealed that the S-NO state at Cys-215 had no discernible irreversibly oxidized forms, whereas other Cys residues remained in their free thiol states. We further demonstrated that S-nitrosylation of the Cys-215 residue protected PTP1B from subsequent H(2)O(2)-induced irreversible oxidation. Increasing the level of cellular NO by pretreating cells with an NO donor or by activating ectopically expressed NO synthase inhibited reactive oxygen species-induced irreversible oxidation of endogenous PTP1B. These findings suggest that S-nitrosylation might prevent PTPs from permanent inactivation caused by oxidative stress.

BCL6 Regulates Tonic BCR Signaling in Diffuse Large B-Cell Lymphomas by Repressing the SYK Phosphatase, PTPROt

Diffuse large B-cell lymphoma (DLBCL) is a heterogeneous disease in which subsets of tumors likely rely upon different survival pathways. We previously identified a subset of primary DLBCLs with increased abundance of multiple components of the BCR signaling cascade including the spleen tyrosine kinase, SYK (“BCR-type” tumors). In related studies, we found that BCR-type DLBCL cell lines and primary tumors exhibited tonic B-cell receptor signaling. Since BCR-associated SYK activation initiates downstream events and amplifies the original BCR signal, we previously evaluated the efficacy of targeted SYK inhibition. Inhibition of SYK-dependent tonic BCR signaling induced apoptosis in the majority of “BCR-type” cell lines and primary DLBCLs. Furthermore, an oral SYK inhibitor (FosD) had promising activity in a subset of relapsed/refractory DLBCLs in a recently completed phase I/II clinical trial. “BCR-type” tumors also have more abundant expression of the transcriptional repressor, BCL6, and more frequent BCL6 translocations, greater repression of BCL6 target genes and increased sensitivity to BCL6 inhibitors. Since the same subset of primary DLBCLs relies upon SYK-dependent BCR signaling and BCL6-mediated transcriptional repression, we evaluated potential connections between BCL6 and SYK. SYK is a major substrate of the tissue-specific and developmentally regulated protein tyrosine phosphatase, PTPROt. For this reason, we first assessed the relative expression of BCL6 and PTPROt in two large independent series of transcriptionally profiled primary DLBCLs and two independent groups of highly purified normal B-cell subpopulations (naïve, germinal center, memory). There was a highly significant reciprocal pattern of expression of PTPROt and BCL6 in both normal B cells and primary DLBCLs, prompting speculation that PTPROt might be a target of BCL6-mediated transcriptional repression. We next analyzed the PTPROt promoter region in silico and identified 3 candidate BCL6 binding sites. Using chromatin immunoprecipitation assays in BCR-type DLBCL cell lines, we demonstrated that BCL6 binding sites in the PTPROt promoter were occupied in vivo by the transcription factor. To assess the role of BCL6 in regulating PTPROt transcription, we cotransfected a luciferase reporter vector driven by the PTPROt promoter with constructs encoding either wild-type BCL6 or one of two inactive BCL6 mutants. Wild-type BCL6 suppressed PTPROt-driven luciferase activity in a dose-dependent manner whereas neither BCL6 mutant altered luciferase levels. Consistent with these observations, individual or combined mutations of the BCL6 binding sites in the PTPROt promoter reduced or abolished the response to BCL6. Next, we asked whether PTPROt was a physiologic target of BCL6 in normal B cells. Forced overexpression of BCL6 in normal naïve B cells was associated with a marked reduction in PTPROt transcript abundance. Since PTPROt functions as a SYK phosphatase, we then assessed the consequences of BCL6 depletion on SYK Y352 phosphorylation and BCR signaling in BCR-type DLBCL cell lines. BCL6 siRNA increased PTPROt transcript abundance 10-fold whereas other components of the BCR signaling pathway were unchanged. In cells transduced with BCL6 siRNA, tonic and anti-Ig associated phosphorylation of SYK Y352 and BLNK Y84 were significantly lower than in parental or mock-transduced cells. Taken together, these studies indicate that BCL6 represses the expression of the SYK phosphatase, PTPROt, and augments SYK-dependent tonic BCR signaling. Since BCL6 and SYK are both promising rational therapeutic targets in many DLBCLs, combined inhibition of these functionally related pathways warrants further study.

Protein Tyrosine Phosphatase Regulation in Fibroblasts from Patients with an Insulin Receptor Gene Mutation

Tyrosine phosphorylation of the insulin receptor is the initial event following receptor binding to insulin, and it induces further tyrosine phosphorylation of various intracellular molecules. This signaling is countered by protein tyrosine phosphatases (PTPases), which reportedly are associated with insulin resistance that can be reduced by regulation of PTPases. Protein tyrosine phosphatase 1B (PTP1B) and leukocyte antigen-related PTPase (LAR) are the PTPases implicated most frequently in insulin resistance and diabetes mellitus. Here, we show that PTP1B and LAR are expressed in human fibroblasts, and we examine the regulation of PTPase activity in fibroblasts from patients with an insulin receptor gene mutation as an in vitro model of insulin resistance. Total PTPase activity was significantly lower in the cytosolic and membrane fractions of fibroblasts with mutations compared with controls (p<0.05). Insulin stimulation of fibroblasts with mutations resulted in a significantly smaller increase in PTP1B activity compared with stimulation of wild-type fibroblasts (p<0.05). This indicates that insulin receptor gene mutations blunt increases in PTPase activity in response to insulin, possibly via a negative feedback mechanism. Our data suggest that the PTPase activity in patients with insulin receptor gene mutation and severe insulin resistance may differ from that in ordinary type 2 diabetes.

Regulation of ROS signal transduction by NADPH oxidase 4 localization.

Reactive oxygen species (ROS) function as intracellular signaling molecules in a diverse range of biological processes. However, it is unclear how freely diffusible ROS dictate specific cellular responses. In this study, we demonstrate that nicotinamide adenine dinucleotide phosphate reduced oxidase 4 (Nox4), a major Nox isoform expressed in nonphagocytic cells, including vascular endothelium, is localized to the endoplasmic reticulum (ER). ER localization of Nox4 is critical for the regulation of protein tyrosine phosphatase (PTP) 1B, also an ER resident, through redox-mediated signaling. Nox4-mediated oxidation and inactivation of PTP1B in the ER serves as a regulatory switch for epidermal growth factor (EGF) receptor trafficking and specifically acts to terminate EGF signaling. Consistent with this notion, PTP1B oxidation could also be modulated by ER targeting of antioxidant enzymes but not their untargeted counterparts. These data indicate that the specificity of intracellular ROS-mediated signal transduction may be modulated by the localization of Nox isoforms within specific subcellular compartments.

Redox-Sensitive Signaling by Angiotensin II Involves Oxidative Inactivation and Blunted Phosphorylation of Protein Tyrosine Phosphatase SHP-2 in Vascular Smooth Muscle Cells From SHR

Angiotensin II (Ang II) signaling in vascular smooth muscle cells (VSMCs) involves reactive oxygen species (ROS) through unknown mechanisms. We propose that Ang II induces phosphorylation of growth signaling kinases by redox-sensitive regulation of protein tyrosine phosphatases (PTP) in VSMCs and that augmented Ang II signaling in spontaneously hypertensive rats (SHRs) involves oxidation/inactivation and blunted phosphorylation of the PTP, SHP-2. PTP oxidation was assessed by the in-gel PTP method. SHP-2 expression and activity were evaluated by immunoblotting and by a PTP activity assay, respectively. SHP-2 and Nox1 were downregulated by siRNA. Ang II induced oxidation of multiple PTPs, including SHP-2. Basal SHP-2 content was lower in SHRs versus WKY. Ang II increased SHP-2 phosphorylation and activity with blunted responses in SHRs. Ang II-induced SHP-2 effects were inhibited by valsartan (AT(1)R blocker), apocynin (NAD(P)H oxidase inhibitor), and Nox1 siRNA. Ang II stimulation increased activation of ERK1/2, p38MAPK, and AKT, with enhanced effects in SHR. SHP-2 knockdown resulted in increased AKT phosphorylation, without effect on ERK1/2 or p38MAPK. Nox1 downregulation attenuated Ang II-mediated AKT activation in SHRs. Hence, Ang II regulates PTP/SHP-2 in VSMCs through AT(1)R and Nox1-based NAD(P)H oxidase via two mechanisms, oxidation and phosphorylation. In SHR Ang II-stimulated PTP oxidation/inactivation is enhanced, basal SHP-2 expression is reduced, and Ang II-induced PTP/SHP-2 phosphorylation is blunted. These SHP-2 actions are associated with augmented AKT signaling. We identify a novel redox-sensitive SHP-2-dependent pathway for Ang II in VSMCs. SHP-2 dysregulation by increased Nox1-derived ROS in SHR is associated with altered Ang II-AKT signaling.

Regulation of VEGF induced angiogenesis by β3 integrin through recruitment of VEGFR‐2 associated protein tyrosine phosphatase

Angiogenesis, the formation of new blood vessels from preexisting vasculature, occurs in a variety of physiological and pathological conditions. The process of angiogenesis is known to be regulated by vascular endothelial growth factor (VEGF) and its receptors (VEGFR‐2) in coordination with extracellular matrix interacting molecules such as integrins. Integrins have been reported to exhibit extracellular matrix dependent regulation of several tyrosine kinases on endothelial cell surfaces. In this study we have revealed the role of β3 integrin cytoplasmic tyrosine motifs in the regulation of protein tyrosine phosphatase (PTPs), associated with VEGFR‐2, in a tyrosine phosphorylation‐dependent manner. SHP‐2 association with VEGFR‐2 regulates the extent of basal and growth factor‐induced VEGFR‐2 phosphorylation in endothelial cells. Additionally, phosphorylated β3 integrin cytoplasmic tyrosine motifs provide binding sites for SHP‐2 and protect VEGFR‐2 from dephosphorylation. Moreover, DiYF endothelial cells, in which β3 integrin cytoplasmic tyrosine motifs are mutated to phenylalanine, exhibit deficient SHP‐2 binding to β3 integrin and VEGF stimulation, also display a modest decrease in SHP‐2 dissociation from VEGFR‐2 and decreased pathological angiogenesis in vivo. Further, we have also demonstrated that SHP‐2 binds to phosphorylated tyrosine residue 773 of the β3 cytoplasmic domain, and that β3 integrin cytoplasmic‐derived cell permeable prephosphorylated peptide 773Yp reduced VEGF‐induced VEGFR‐2 tyrosine phosphorylation and down stream signaling, endothelial cell migration, tube formation, ex vivo and in vivo angiogenesis. We have for the first time demonstrated this novel mechanism which regulates processes of VEGFR‐2 activation and pathological angiogenesis.

Dynamic changes in the expression of DEP‐1 and other PDGF receptor‐antagonizing PTPs during onset and termination of neointima formation

Growth factor-dependent tissue remodeling, such as restenosis, is believed to be predominantly regulated by changes in expression of receptor-tyrosine-kinases (RTKs) and their ligands. As endogenous antagonists of RTKs, protein-tyrosine-phosphatases (PTPs) are additional candidate regulators of these processes. Using laser-capture-microdissection and quantitative RT-polymerase chain reaction (qRT-PCR), we investigated the layer-specific expression of the four platelet-derived growth factor (PDGF) isoforms, the PDGF-alpha and beta receptors, and five PTPs implied in control of PDGF-receptor signaling 8 and 14 days after balloon injury of the rat carotid. Results were correlated with analyses of PDGF-beta receptor phosphorylation and vascular smooth muscle cell (VSMC) proliferation in vivo. The expression levels of all components, as well as receptor activation and VSMC proliferation, showed specific changes, which varied between media and neointima. Interestingly, PTP expression--particularly, DEP-1 levels--appeared to be the dominating factor determining receptor-phosphorylation and VSMC proliferation. In support of these findings, cultured DEP-1(-/-) cells displayed increased PDGF-dependent cell signaling. Hyperactivation of PDGF-induced signaling was also observed after siRNA-down-regulation of DEP-1 in VSMCs. The results indicate a previously unrecognized role of PDGF-receptor-targeting PTPs in controlling neointima formation. In more general terms, the observations indicate transcriptional regulation of PTPs as an important mechanism for controlling onset and termination of RTK-dependent tissue remodeling.