Structure-based design and synthesis of small molecule protein-tyrosine phosphatase 1B inhibitors

Protein-tyrosine phosphatase (PTP) inhibitors are attractive as potential signal transduction-directed therapeutics which may be useful in the treatment of a variety of diseases. We have previously reported the X-ray structure of 1,1-difluoro-1-(2-naphthalenyl)methyl] phosphonic acid (4) complexed with the human the protein-tyrosine phosphatase 1B (PTP1B) and its use in the design of an analogue which binds with higher affinity within the catalytic site (Burke, T. R., Jr. et al. Biochemistry 1996, 35, 15989). In the current study, new naphthyldifluoromethyl phosphonic acids were designed bearing acidic functionality intended to interact with the PTP1B Arg47, which is situated just outside the catalytic pocket. This residue has been shown previously to provide key interactions with acidic residues of phosphotyrosyl-containing peptide substrates. Consistent with trends predicted by molecular dynamics calculations, the new analogues bound with 7- to 14-fold higher affinity than the parent 4, in principal validating the design rationale.     

Visualization of the cysteinyl-phosphate intermediate of a protein-tyrosine phosphatase by x-ray crystallography

Protein-tyrosine phosphatases (PTPs) are signal transduction enzymes that catalyze the dephosphorylation of phosphotyrosine residues via the formation of a transient cysteinyl-phosphate intermediate. The mechanism of hydrolysis of this intermediate has been examined by generating a Gln-262 --> Ala mutant of PTP1B, which allows the accumulation and trapping of the intermediate within a PTP1B crystal. The structure of the intermediate at 2.5-A resolution reveals that a conformationally flexible loop (the WPD loop) is closed over the entrance to the catalytic site, sequestering the phosphocysteine intermediate and catalytic site water molecules and preventing nonspecific phosphoryltransfer reactions to extraneous phosphoryl acceptors. One of the catalytic site water molecules, the likely nucleophile, forms a hydrogen bond to the putative catalytic base, Asp-181. In the wild-type enzyme, the nucleophilic water molecule would be coordinated by the side chain of Gln-262. In combination with our previous structural data, we can now visualize each of the reaction steps of the PTP catalytic pathway. The hydrolysis of the cysteinyl-phosphate intermediate of PTPs is reminiscent of GTP hydrolysis by the GTPases, in that both families of enzymes utilize an invariant Gln residue to coordinate the attacking nucleophilic water molecule.     

Electrochemical oxidation of N-acyldopamines and regioselective reactions of their quinones with N-acetylcysteine and thiourea

Affinity selection from peptide libraries is a powerful tool that has been used for determining the sequence specificities of a number of enzymes and protein binding domains, including protein kinases, src homology 2 domains, and PDZ domains. We have extended this approach to protein tyrosine phosphatases using peptide libraries containing a nonhydrolyzable phosphotyrosine analog, difluorophosphonomethylphenylalanine. A size-exclusion method is used to separate enzyme-peptide complexes from free peptide, providing several advantages over the traditional immobilized protein affinity column approach. In addition, the feasibility of using mass spectrometric detection to quantitate peptides rapidly and reproducibly is demonstrated as an alternative to quantitation by peptide sequencing. The validity of this analysis is demonstrated by synthesizing individual peptides and comparing their affinity for enzyme with the predictions from the affinity selection process. As a model for these studies the protein tyrosine phosphatase PTP1B is used, providing additional insights into the sequence specificity of this enzyme. In particular, a selection for aromatic amino acids at the pY - 1 position (immediately N-terminal to the phosphotyrosine), as well as a broad pY + 1 selectivity, is observed in addition to the general preference for acidic residues N-terminal to the phosphotyrosine. The approach described here should prove applicable to protein tyrosine phosphatases in general as well as for the study of nonpeptidyl combinatorial libraries.     

A targeted library of small-molecule, tyrosine, and dual-specificity phosphatase inhibitors derived from a rational core design and random side chain variation

Tyrosine phosphatases (PTPases) dephosphorylate phosphotyrosines while dual-specificity phosphatases (DSPases) dephosphorylate contiguous and semicontiguous phosphothreonine and phosphotyrosine on cyclin dependent kinases and mitogen-activated protein kinases. Consequently, PTPases and DSPases have a central role controlling signal transduction and cell cycle progression. Currently, there are few readily available potent inhibitors of PTPases or DSPases other than vanadate. Using a pharmacophore modeled on natural product inhibitors of phosphothreonine phosphatases, we generated a refined library of novel, phosphate-free, small-molecule compounds synthesized by a parallel, solid-phase combinatorial-based approach. Among the initial 18 members of this targeted diversity library, we identified several inhibitors of DSPases: Cdc25A, -B, and -C and the PTPase PTP1B. These compounds at 100 microM did not significantly inhibit the protein serine/threonine phosphatases PP1 and PP2A. Kinetic studies with two members of this library indicated competitive inhibition for Cdc25 DSPases and noncompetitive inhibition for PTP1B. Compound AC-alphaalpha69 had a Ki of approximately 10 microM for recombinant human Cdc25A, -B, and -C, and a Ki of 0.85 microM for the PTP1B. The marked differences in Cdc25 inhibition as compared to PTP1B inhibition seen with relatively modest chemical modifications in the modular side chains demonstrate the structurally demanding nature of the DSPase catalytic site distinct from the PTPase catalytic site. These results represent the first fundamental advance toward a readily modifiable pharmacophore for synthetic PTPase and DSPase inhibitors and illustrate the significant potential of a combinatorial-based strategy that supplements the rational design of a core structure by a randomized variation of peripheral substituents.     

Novel phosphate mimetics for the design of non-peptidyl inhibitors of protein tyrosine phosphatases

Benzylic alpha,alpha-difluorosulfonates, alpha,alpha-difluorotetrazoles, and alpha,alpha-difluorocarboxylates of type 5 and 6 were synthesized and examined as potential phosphate biosteres for PTP1B inhibition. The alpha,alpha-difluorosulfonates and alpha,alpha-difluorotetrazoles were found to be more effective inhibitors than the analogous compounds bearing the fluoromalonyl group, a phosphate biostere currently being used for PTP inhibition.     

Protein phosphatase 1 is targeted to microtubules by the microtubule-associated protein Tau

Phosphorylation has been implicated in the regulation of microtubule (MT) stability and function by controlling the interactions between MTs and MT-associated proteins. We found previously that protein phosphatase inhibitors selectively break down stable MTs, suggesting that protein phosphatases may be involved in regulating MT stability. To identify the protein phosphatases involved, we examined purified calf brain MTs and found a protein phosphatase activity that copurified with MTs to constant stoichiometry. Western blot analysis and inhibitor profiles demonstrated that the MT-associated phosphatase was a type 1 protein phosphatase (PP1), which we named PP1MT. Recombinant PP1 catalytic subunit (PP1c) did not bind to MTs, whereas PP1MT did bind, suggesting the presence of proteins that target PP1 to MTs. By Sepharose CL-6B chromatography, the phosphatase activity of PP1MT eluted as a large protein complex of approximately 400 kDa. High salt (2 M NaCl) treatment followed by CL-6B chromatography dissociated PP1MT into PP1c and the MT-targeting subunit(s). The MT-targeting subunit was shown to be the MT-associated protein tau by PP1 blot overlays and other assays. Also, recombinant tau reconstituted the binding of PP1c to MTs. These results identify PP1 as the first tau binding protein and suggest that tau is a novel PP1-targeting subunit.     

The crystal structure of domain 1 of receptor protein-tyrosine phosphatase mu

Receptor-like protein-tyrosine phosphatases (RPTPs) play important roles in regulating intracellular processes. We have been investigating the regulation and function of RPTPmu, a receptor-like PTP related to the Ig superfamily of cell adhesion molecules. Recently, the crystal structure of a dimer of the membrane proximal domain of RPTPalpha (RPTPalpha D1) was described (Bilwes, A. M., den Hertog, J., Hunter, T., and Noel J. P. (1996) Nature 382, 555-559). Within this crystal structure, the catalytic site of each subunit of the dimer is sterically blocked by the insertion of the N-terminal helix-turn-helix segment of the dyad-related monomer. It was proposed that dimerization would lead to inhibition of catalytic activity and may provide a paradigm for the regulation of the RPTP family. We have determined the crystal structure, to 2.3 A resolution, of RPTPmu D1, which shares 46% sequence identity with that of RPTPalpha D1. Although the tertiary structures of RPTPalpha D1 and RPTPmu D1 are very similar, with a root mean square deviation between equivalent Calpha atoms of 1.1 A, the quaternary structures of these two proteins are different. Neither the catalytic site nor the N-terminal helix-turn-helix segment of RPTPmu D1 participates in protein-protein interactions. The catalytic site of RPTPmu D1 is unhindered and adopts an open conformation similar to that of the cytosolic PTP, PTP1B (Barford, D., Flint, A. J., and Tonks, N. K. (1994) Science 263, 1397-1404). We propose that dimerization-induced modulation of RPTP activity may not be a general feature of this family of enzymes.     

Molecular basis for substrate specificity of protein-tyrosine phosphatase 1B

Protein-tyrosine phosphatases can exhibit stringent substrate specificity in vivo, although the molecular basis for this is not well understood. The three-dimensional structure of the catalytically inactive protein-tyrosine phosphate 1B (PTP1B)/C215S complexed with an optimal substrate, DADEpYL-NH2, reveals specific interactions between amino acid residues in the substrate and PTP1B. The goal of this work is to rigorously evaluate the functional significance of Tyr46, Arg47, Asp48, Phe182, and Gln262 in substrate binding and catalysis, using site-directed mutagenesis. Combined with structural information, kinetic analysis of the wild type and mutant PTP1B using p-nitrophenyl phosphate and phosphotyrosine-containing peptides has yielded further insight into PTP1B residues, which recognize general features, as well as specific properties, in peptide substrates. In addition, the kinetic results suggest roles of these residues in E-P hydrolysis, which are not obvious from the structure of PTP1B/peptide complex. Thus, Tyr46 and Asp48 recognize common features of peptide substrates and are important for peptide substrate binding and/or E-P formation. Arg47 acts as a determinant of substrate specificity and is responsible for the modest preference of PTP1B for acidic residues NH2-terminal to phosphotyrosine. Phe182 and the invariant Gln262 are not only important for substrate binding and/or E-P formation but also important for the E-P hydrolysis step.     

Carboxymethyl-phenylalanine as a replacement for phosphotyrosine in SH2 domain binding

The crystal structure of human p56(lck) SH2 domain in complex with an inhibitor containing the singly charged p-(carboxymethyl)phenylalanine residue (cmF) as a phosphotyrosine (Tyr(P) or pY) replacement has been determined at 1.8 A resolution. The binding mode of the acetyl-cmF-Glu-Glu-Ile (cmFEEI) inhibitor is very similar to that of the pYEEI inhibitor, confirming that the cmFEEI inhibitor has a similar mechanism of SH2 domain inhibition despite its significantly reduced potency. Observed conformational differences in the side chain of the cmF residue can be interpreted in terms of maintaining similar interactions with the SH2 domain as the Tyr(P) residue. The crystal structure of the free p56(lck) SH2 domain has been determined at 1.9 A resolution and shows an open conformation for the BC loop and an open phosphotyrosine binding pocket, in contrast to earlier studies on the src SH2 domain that showed mostly closed conformation. The structural information presented here suggests that the carboxymethyl-phenylalanine residue may be a viable Tyr(P) replacement and represents an attractive starting point for the design and development of SH2 domain inhibitors with better pharmaceutical profiles.     

Role of antioxidant defenses in the tolerance of severe dehydration by anurans. The case of the leopard frog Rana pipiens

Protein tyrosine phosphatases (PTPs) play a critical role in regulating insulin action in part through dephosphorylation of the active (autophosphorylated) form of the insulin receptor (IRK) and attenuation of its tyrosine kinase activity. Following insulin binding the activated IRK is rapidly internalized into the endosomal apparatus, a major site at which the IRK is dephosphorylated in vivo. Studies in rat liver suggest a complex regulatory process whereby PTPs may act, via selective IRK tyrosine dephosphorylation, to modulate IRK activity in both a positive and negative manner. Use of peroxovanadium (pV) compounds, shown to be powerful PTP inhibitors, has been critical in delineating a close relationship between the IRK and its associated PTP(s) in vivo. Indeed the in vivo administration of pV compounds effected activation of IRK in parallel with an inhibition of IRK-associated PTP activity. This process was accompanied by a lowering of blood glucose levels in both normal and diabetic rats thus implicating the IRK-associated PTP(s) as a suitable target for defining a novel class of insulin mimetic agents. Identification of the physiologically relevant IRK-associated PTP(s) should facilitate the development of drugs suitable for managing diabetes mellitus.     

Recruitment and activation of SHP-1 protein-tyrosine phosphatase by human platelet endothelial cell adhesion molecule-1 (PECAM-1). Identification of immunoreceptor tyrosine-based inhibitory motif-like binding motifs and substrates

Stimulation of platelet aggregation leads to tyrosine phosphorylation of a number of receptors and signaling molecules including platelet endothelial cell adhesion molecule-1 (PECAM-1). In this report, we demonstrate that both protein-tyrosine phosphatases SHP-1 and SHP-2 physically associate with different kinetics of assembly with tyrosine-phosphorylated human PECAM-1 during integrin alphaIIbbeta3-mediated platelet aggregation. Peptido-precipitation analysis revealed that tyrosine-phosphorylated peptides encompassing residues 658-668 and 681-691 of PECAM-1 bound specifically to both protein-tyrosine phosphatases SHP-1 and SHP-2. We further show that the association of SHP-1 with PECAM-1 occurs through the direct interaction of the src homology region 2 domains of SHP-1 with two highly conserved phosphotyrosine binding motifs within PECAM-1 having the sequences NSDVQpY663TEVQV and DTETVpY686SEVRK (where pY represents phosphotyrosine). In vitro dephosphorylation experiments using phosphotyrosyl PECAM-1 peptides encompassing either Tyr-663 or Tyr-686 revealed induction of SHP-1 catalytic activity, suggesting that PECAM-1 serves as a SHP-1 substrate. Surface plasmon resonance studies reveal that recombinant SHP-2 binds PECAM-1 phosphopeptides with 5-fold higher affinity than recombinant SHP-1. These data suggest that in hematopoietic cells such as platelets, PECAM-1 cellular signaling is regulated by the selective recruitment and activation of two distinct protein-tyrosine phosphatases, SHP-1 and SHP-2, via a common immunoreceptor tyrosine-based inhibitory-like motif.     

The second catalytic domain of protein tyrosine phosphatase delta (PTP delta) binds to and inhibits the first catalytic domain of PTP sigma

The LAR family protein tyrosine phosphatases (PTPs), including LAR, PTP delta, and PTP sigma, are transmembrane proteins composed of a cell adhesion molecule-like ectodomain and two cytoplasmic catalytic domains: active D1 and inactive D2. We performed a yeast two-hybrid screen with the first catalytic domain of PTP sigma (PTP sigma-D1) as bait to identify interacting regulatory proteins. Using this screen, we identified the second catalytic domain of PTP delta (PTP delta-D2) as an interactor of PTP sigma-D1. Both yeast two-hybrid binding assays and coprecipitation from mammalian cells revealed strong binding between PTP sigma-D1 and PTP delta-D2, an association which required the presence of the wedge sequence in PTP sigma-D1, a sequence recently shown to mediate D1-D1 homodimerization in the phosphatase RPTP alpha. This interaction was not reciprocal, as PTP delta-D1 did not bind PTP sigma-D2. Addition of a glutathione S-transferase (GST)-PTP delta-D2 fusion protein (but not GST alone) to GST-PTP sigma-D1 led to approximately 50% inhibition of the catalytic activity of PTP sigma-D1, as determined by an in vitro phosphatase assay against p-nitrophenylphosphate. A similar inhibition of PTP sigma-D1 activity was obtained with coimmunoprecipitated PTP delta-D2. Interestingly, the second catalytic domains of LAR (LAR-D2) and PTP sigma (PTP sigma-D2), very similar in sequence to PTP delta-D2, bound poorly to PTP sigma-D1. PTP delta-D1 and LAR-D1 were also able to bind PTP delta-D2, but more weakly than PTP sigma-D1, with a binding hierarchy of PTP sigma-D1 > PTP delta-D1 > LAR-D1. These results suggest that association between PTP sigma-D1 and PTP delta-D2, possibly via receptor heterodimerization, provides a negative regulatory function and that the second catalytic domains of this and likely other receptor PTPs, which are often inactive, may function instead to regulate the activity of the first catalytic domains.     

Characterization of the myotubularin dual specificity phosphatase gene family from yeast to human

X-linked myotubular myopathy (XLMTM) is a severe congenital muscle disorder due to mutations in the MTM1 gene. The corresponding protein, myotubularin, contains the consensus active site of tyrosine phosphatases (PTP) but otherwise shows no homology to other phosphatases. Myotubularin is able to hydrolyze a synthetic analogue of tyrosine phosphate, in a reaction inhibited by orthovanadate, and was recently shown to act on both phosphotyrosine and phosphoserine. This gene is conserved down to yeast and strong homologies were found with human ESTs, thus defining a new dual specificity phosphatase (DSP) family. We report the presence of novel members of the MTM gene family in Schizosaccharomyces pombe, Caenorhabditis elegans, zebrafish, Drosophila, mouse and man. This represents the largest family of DSPs described to date. Eight MTM-related genes were found in the human genome and we determined the chromosomal localization and expression pattern for most of them. A subclass of the myotubularin homologues lacks a functional PTP active site. Missense mutations found in XLMTM patients affect residues conserved in a Drosophila homologue. Comparison of the various genes allowed construction of a phylogenetic tree and reveals conserved residues which may be essential for function. These genes may be good candidates for other genetic diseases.     

Potent non-peptidyl inhibitors of protein tyrosine phosphatase 1B

The development of inhibitors of protein tyrosine phosphatases (PTPs) has recently been the subject of intensive investigation due to their potential as chemotherapeutics and as tools for studying signal transduction pathways. Here we report the evaluation of a variety of small molecule, non-peptidyl inhibitors of protein tyrosine phosphatase 1B (PTP1B), bearing the alpha, alpha-difluoromethylenephosphonic acid (DFMP) group, a non-hydrolyzable phosphate mimetic. A series of phenyl derivatives bearing a single DFMP group were initially surveyed. In general, these were not significantly more potent inhibitors than the parent compound, alpha, alpha-difluorobenzylphosphonic acid, with the exception being the meta-phenyl substituted species which decreased the IC50 by approximately 17-fold relative to alpha, alpha-difluorobenzylphosphonic acid. However, certain compounds bearing two DFMP moieties were very potent inhibitors. Some of these are among the most potent small molecule inhibitors of any PTP reported to date with the best one exhibiting a Ki of 1.5 microM. The structural basis for these results are discussed. One of the bis-DFMP inhibitors was examined in detail and it was found that the fluorines were essential for potent inhibition. Inhibition was independent of pH between pH 5.5-7.2 suggesting that both the mono and dianionic forms of the individual DFMP groups bind equally well. The trends observed in the inhibitory potency of these compounds with PTP1B were very similar to the trends observed by other workers on the K(m)'s of the analogous phenylphosphate substrates with rat PTP1. This indicates that studies of non-peptidyl substrates with rat PTP1 can be used as a guide for the development of human PTP1B inhibitors.     

The receptor-like protein-tyrosine phosphatase DEP-1 is constitutively associated with a 64-kDa protein serine/threonine kinase

Protein-tyrosine phosphatases (PTPs) are involved in the regulation of diverse cellular processes and may function as positive effectors as well as negative regulators of intracellular signaling. Recent data demonstrate that malignant transformation of cells is frequently associated with changes in PTP expression or activity. Our analysis of PTP expression in mammary carcinoma cell lines resulted in the molecular cloning of a receptor-like PTP, also known as DEP-1. DEP-1 was found to be expressed at varying levels in mammary carcinoma cell lines and A431 cells. In all tumor cell lines analyzed, DEP-1 was constitutively phosphorylated on tyrosine residues. Phosphorylation of DEP-1 increased significantly after treatment of cells with the PTP inhibitor pervanadate. In A431 cells, tyrosine phosphorylation of DEP-1 was also observed after stimulation with epidermal growth factor, however, only after prolonged exposure of the cells to the ligand, suggesting an indirect mechanism of phosphorylation. In addition, DEP-1 coprecipitated with several tyrosine-phosphorylated proteins from pervanadate-treated cells. In vitro binding experiments using a glutathione S-transferase fusion protein containing the catalytically inactive PTP domain of DEP-1 (Gst-DEP-1-C/S) identify these proteins as potential substrates of DEP-1. In addition, we found a 64-kDa serine/threonine kinase to be constitutively associated with DEP-1 in all tumor cell lines tested. The 64-kDa kinase forms a stable complex with DEP-1 and phosphorylates DEP-1 and DEP-1-interacting proteins in vitro. These data suggest a possible mechanism of DEP-1 regulation in tumor cell lines involving serine/threonine and/or tyrosine phosphorylation.     

Regulated binding of PTP1B-like phosphatase to N-cadherin: control of cadherin-mediated adhesion by dephosphorylation of beta-catenin

Cadherins are a family of cell-cell adhesion molecules which play a central role in controlling morphogenetic movements during development. Cadherin function is regulated by its association with the actin containing cytoskeleton, an association mediated by a complex of cytoplasmic proteins, the catenins: alpha, beta, and gamma. Phosphorylated tyrosine residues on beta-catenin are correlated with loss of cadherin function. Consistent with this, we find that only nontyrosine phosphorylated beta-catenin is associated with N-cadherin in E10 chick retina tissue. Moreover, we demonstrate that a PTP1B-like tyrosine phosphatase associates with N-cadherin and may function as a regulatory switch controlling cadherin function by dephosphorylating beta-catenin, thereby maintaining cells in an adhesion-competent state. The PTP1B-like phosphatase is itself tyrosine phosphorylated. Moreover, both direct binding experiments performed with phosphorylated and dephosphorylated molecules, and treatment of cells with tyrosine kinase inhibitors indicate that the interaction of the PTP1B-like phosphatase with N-cadherin depends on its tyrosine phosphorylation. Concomitant with the tyrosine kinase inhibitor-induced loss of the PTP1B-like phosphatase from its association with N-cadherin, phosphorylated tyrosine residues are retained on beta-catenin, the association of N-cadherin with the actin containing cytoskeleton is lost and N-cadherin-mediated cell adhesion is prevented. Tyrosine phosphatase inhibitors also result in the accumulation of phosphorylated tyrosine residues on beta-catenin, loss of the association of N-cadherin with the actin-containing cytoskeleton, and prevent N-cadherin mediated adhesion, presumably by directly blocking the function of the PTP1B-like phosphatase. We previously showed that the binding of two ligands to the cell surface N-acetylgalactosaminylphosphotransferase (GalNAcPTase), the monoclonal antibody 1B11 and a proteoglycan with a 250-kD core protein, results in the accumulation of phosphorylated tyrosine residues on beta-catenin, uncoupling of N-cadherin from its association with the actin containing cytoskeleton, and loss of N-cadherin function. We now report that binding of these ligands to the GalNAcPTase results in the absence of the PTP1B-like phosphatase from its association with N-cadherin as well as the loss of the tyrosine kinase and tyrosine phosphatase activities that otherwise co-precipitate with N-cadherin. Control antibodies and proteoglycans have no such effect. This effect is similar to that observed with tyrosine kinase inhibitors, suggesting that the GalNAcPTase/proteoglycan interaction inhibits a tyrosine kinase, thereby preventing the phosphorylation of the PTP1B-like phosphatase, and its association with N-cadherin. Taken together these data indicate that a PTP1B-like tyrosine phosphatase can regulate N-cadherin function through its ability to dephosphorylate beta-catenin and that the association of the phosphatase with N-cadherin is regulated via the interaction of the GalNAcPTase with its proteoglycan ligand. In this manner the GalNAcPTase-proteoglycan interaction may play a major role in morphogenetic cell and tissue interactions during development.     

Evidence for a physical association between the Shc-PTB domain and the beta c chain of the granulocyte-macrophage colony-stimulating factor receptor

Granulocyte-macrophage colony-stimulating factor (GM-CSF) regulates the growth and function of several myeloid cell types at different stages of maturation. The effects of GM-CSF are mediated through a high affinity receptor that is composed of two chains: a unique, ligand-specific alpha chain and a beta common chain (beta c) that is also a component of the receptors for interleukin 3 (IL-3) and IL-5. Beta c plays an essential role in the transduction of extra cellular signals to the nucleus through its recruitment of secondary messengers. Several downstream signaling events induced by GM-CSF stimulation have been described, including activation of tyrosine kinases and tyrosine phosphorylation of cellular proteins (including beta c) and activation of the Ras/mitogen-activated protein kinase and the JAK/STAT pathways. A region within the beta c cytoplasmic tail (amino acids 517-763) has been reported to be necessary for tyrosine phosphorylation of the adapter protein, Shc, and for the subsequent GM-CSF-induced activation of Ras. In this paper, we describe a physical association between the tyrosine phosphorylated GM-CSF receptor (GMR)-beta c chain and Shc in vivo. Using a series of cytoplasmic truncation mutants of beta c and various mutant Shc proteins, we demonstrate that the N-terminal phosphotyrosine-binding (PTB) domain of Shc binds to a short region of beta c (amino acids 549-656) that contains Tyr577. Addition of a specific phosphopeptide encoding amino acids surrounding this tyrosine inhibited the interaction between beta c and shc. Moreover, mutation of a key residue within the phosphotyrosine binding pocket of the Shc-PTB domain abrogated its association with beta c. These observations provide an explanation for the previously described requirement for Tyr577 of beta c for GM-CSF-induced tyrosine phosphorylation of Shc and have implications for Ras activation through the GM-CSF, IL-3, and IL-5 receptors.     

Structural basis of functions of the mitochondrial cytochrome bc1 complex

The crystal structure of the cytochrome bc1 complex (ubiquinol-cytochrome c reductase) from bovine heart submitochondria was determined at 2.9 A resolution. The bc1 complex in crystal exists as a closely interacting dimer, suggesting that the dimer is a functional unit. Over half of the mass of the complex, including subunits core 1 and core 2, are on the matrix side of the membrane, while most of the cytochrome b subunit is located within the membrane. There are 13 transmembrane helices in each monomer, eight of them belonging to cytochrome b. Two large cavities are made of the transmembrane helices D, C, F and H in one monomer and helices D' and E' from the other monomer of cytochrome b, and the transmembrane helices of c1, iron-sulfur protein (ISP), and subunits 10 and 11. These cavities provide entrances for ubiquinone or inhibitor and connect the Qi pocket of one monomer and the Qo pocket of the other monomer. Ubiquinol made at the Qi site of one monomer can proceed to the nearby Qo site of the other monomer without having to leave the bc1 complex. The soluble parts of cytochrome c1 and ISP, including their redox prosthetic groups, are located on the cytoplasmic side of the membrane. The distances between the four redox centers in the complex have been determined, and the binding sites for several electron transfer inhibitors have been located. Structural analysis of the protein/inhibitor complexes revealed that the extramembrane domain of the Rieske iron-sulfur protein may undergo substantial movement during the catalytic cycle of the complex. The Rieske protein movement and the larger than expected distance between FeS and cytochrome c1 heme suggest that electron transfer reaction between FeS and cytochrome c1 may involve movements or conformational changes in the soluble domain of iron-sulfur protein. The inhibitory function of E-beta-methoxyacrylate-stilbene and myxothiazol may result from the increase of mobility in ISP, whereas the function of stigmatellin and 5-undecyl-6-hydroxy-4,7-dioxobenzothiazole may result from the immobilization of ISP.     

Early inhibition of protein phosphatases preferentially blocks phorbol ester-stimulated mitogenic signalling in melanocytes: increase in specific tyrosine phosphoproteins

Inhibition of protein phosphatases has been suggested as an alternative mechanism of tumor promotion (H. Fujiki, Mol. Carcinog. 5:91, 1992). We have now used early melanocyte passages dependent on phorbol esters and serum for growth and later passages with partial phorbol ester independence, to investigate the role of protein phosphatases on melanocyte DNA synthesis. Neither okadaic acid, an inhibitor of ser/thr protein phosphatases, nor vanadate, an inhibitor of tyrosine phosphatases, can stimulate basal or serum-stimulated mitogenesis in contrast to phorbol esters. Moreover, both phosphatase inhibitors are able to suppress serum and phorbol ester-stimulated mitogenesis, if added within 4 hours of growth activation. Inhibition of mitogenesis by either inhibitor correlated with an early increase in a common set of tyrosine phosphoproteins, which included a major 33 Kd species. Our data suggest that protein phosphatase inhibitors are growth suppressors and antagonize phorbol ester effects in cells of melanocytic origin, implying an early requirement for protein phosphatase activity during mitogenic signalling in these cells.     

The tyrosine phosphatase PTP1C associates with Vav, Grb2, and mSos1 in hematopoietic cells

The association of the murine motheaten phenotype of severe hemopoietic dysregulation with loss of PTP1C tyrosine phosphatase activity indicates a critical role for this SH2 domain-containing phosphotyrosine phosphatase in the regulation of hemopoietic cell growth and differentiation. To explore the molecular basis for PTP1C effects on hematopoiesis, we have investigated the possibility that this enzyme interacts with the product of the Vav proto-oncogene, a putative guanine nucleotide exchange factor expressed exclusively in hemopoietic cells. Our data indicate that PTP1C physically associates with Vav in murine spleen cells and in EL4 T lymphoma and P815 mastocytoma cells, and that this interaction is increased following mitogenic stimulation and the induction of both PTP1C and Vav tyrosine phosphorylation. The results also reveal tyrosine phosphatase activity to be present in Vav immunoprecipitates from stimulated splenic and P815 cells and suggest that a major portion of total cellular PTP1C catalytic activity is associated with Vav. As Vav-associated tyrosine phosphatase activity was not detected in PTP1C-deficient motheaten splenic cells, it appears that PTP1C accounts for most, if not all, Vav-coprecipitable tyrosine phosphatase activity in normal cells. The data also demonstrate the capacity of the Vav SH2 domain alone to bind to PTP1C in activated P815 cells, but suggest a role for the two Vav SH3 domains in enhancing this interaction. In addition, the results reveal PTP1C association with two other molecules implicated in Ras activation, the Grb2 adaptor protein and mSos1, a GTP/GDP exchanger for Ras. PTP1C therefore has the capacity to bind and potentially modulate various signaling effectors involved in activation of Ras or Ras-related proteins, and, accordingly, regulation of Ras activation represents a possible mechanism whereby PTP1C influences hemopoietic cellular responses.