Purification and characterization of the catalytic domains of the human receptor-linked protein tyrosine phosphatases HPTP beta, leukocyte common antigen (LCA), and leukocyte common antigen-related molecule (LAR).

Human HPTP beta, leukocyte common antigen (LCA), and leukocyte common antigen-related molecule (LAR) are transmembrane receptor-like proteins whose cytoplasmic regions contain either one (HPTP beta) or two (LCA and LAR) domains that are homologous to protein tyrosine phosphatases (PTPases). Whereas the membrane-proximal domain 1 has enzymatic activity, the membrane-distal domain 2 of both LCA and LAR has no detectable catalytic activity. The cytoplasmic regions of HPTP beta, LCA, and LAR were expressed in Escherichia coli and purified to greater than 90% purity. Modulatory effects of various low molecular weight compounds and homo- and copolymers of amino acids were examined. Several polypeptides that contain a high proportion of tyrosine were strongly inhibitory to these PTPases. To determine a possible role for the LAR domain 2, the properties of recombinant LAR PTPases containing both domains 1 and 2 (LAR-D1D2) or only domain 1 (LAR-D1) were compared. In nearly all aspects examined, LAR-D1 and LAR-D1D2 were indistinguishable. However, polycationic polypeptides strongly stimulated the PTPase activity of LAR-D1D2, but not LAR-D1, using the peptide substrate Raytide. Thus, basic polypeptides seem to indirectly alter the catalytic activity of domain 1 by interacting with domain 2. This result suggests that domain 2 has a regulatory function.     

Isolation and characterization of temperature-sensitive and thermostable mutants of the human receptor-like protein tyrosine phosphatase LAR.

Human LAR is a transmembrane receptor-like protein whose cytoplasmic region contains two tandemly duplicated domains homologous to protein tyrosine phosphatases (PTPases). Whereas the membrane-proximal domain I has enzymatic activity, the membrane-distal domain II has no apparent catalytic activity but seems to have a regulatory function. In order to study structure-function relationships of the LAR PTPase, LAR domain I was expressed in Escherichia coli, and mutants that have reduced catalytic activity or reduced thermostability were isolated and characterized. We isolated 18 unique hydroxylamine-induced missense mutations in the LAR domain I segment, of which three were temperature-sensitive. Five additional temperature-sensitive mutations were isolated using N-methyl-N'-nitro-N-nitrosoguanidine. All eight temperature-sensitive mutations are confined within a short segment of the LAR domain I sequence between amino acid positions 1329 and 1407. To examine whether this region is particularly prone to temperature-sensitive mutations, tyrosine at amino acid position 1379 was changed to a phenylalanine by oligonucleotide-directed mutagenesis. This mutant, Y1379-F, was indeed temperature-sensitive. We also isolated a revertant of a temperature-sensitive mutant. The revertant contained a second-site mutation (C1446-Y) that suppresses several temperature-sensitive mutations and also enhances the folding of LAR protein produced in E. coli.     

Distinct functions of the two protein tyrosine phosphatase domains of LAR (leukocyte common antigen-related) on tyrosine dephosphorylation of insulin receptor

Most receptor-like, transmembrane protein tyrosine phosphatases (PTPases), such as CD45 and the leukocyte common antigen-related (LAR) molecule, have two tandemly repeated PTPase domains in the cytoplasmic segment. The role of each PTPase domain in mediating PTPase activity remains unclear; however, it has been proposed that PTPase activity is associated with only the first of the two domains, PTPase domain 1, and the membrane-distal PTPase domain 2, which has no catalytic activity, would regulate substrate specificity. In this paper, we examine the function of each PTPase domain of LAR in vivo using a potential physiological substrate, namely insulin receptor, and LAR mutant proteins in which the conserved cysteine residue was changed to a serine residue in the active site of either or both PTPase domains. LAR associated with and preferentially dephosphorylated the insulin receptor that was tyrosine phosphorylated by insulin stimulation. Its association was mediated by PTPase domain 2, because the mutation of Cys-1813 to Ser in domain 2 resulted in weakening of the association. The Cys-1522 to Ser mutant protein, which is defective in the LAR PTPase domain 1 catalytic site, was tightly associated with tyrosine-phosphorylated insulin receptor, but failed to dephosphorylate it, indicating that LAR PTPase domain 1 is critical for dephosphorylation of tyrosine-phosphorylated insulin receptor. This hypothesis was further confirmed by using LAR mutants in which either PTPase domain 1 or domain 2 was deleted. Moreover, the association of the extracellular domains of both LAR and insulin receptor was supported by using the LAR mutant protein without the two PTPase domains. LAR was phosphorylated by insulin receptor tyrosine kinase and autodephosphorylated by the catalytic activity of the PTPase domain 1. These results indicate that each domain of LAR plays distinct functional roles through phosphorylation and dephosphorylation in vivo.     

Crystal structure of the tandem phosphatase domains of RPTP LAR.

Most receptor-like protein tyrosine phosphatases (RPTPs) contain two conserved phosphatase domains (D1 and D2) in their intracellular region. The carboxy-terminal D2 domain has little or no catalytic activity. The crystal structure of the tandem D1 and D2 domains of the human RPTP LAR revealed that the tertiary structures of the LAR D1 and D2 domains are very similar to each other, with the exception of conformational differences at two amino acid positions in the D2 domain. Site-directed mutational changes at these positions (Leu-1644-to-Tyr and Glu-1779-to-Asp) conferred a robust PTPase activity to the D2 domain. The catalytic sites of both domains are accessible, in contrast to the dimeric blocked orientation model previously suggested. The relative orientation of the LAR D1 and D2 domains, constrained by a short linker, is stabilized by extensive interdomain interactions, suggesting that this orientation might be favored in solution.     

Structural diversity and evolution of human receptor-like protein tyrosine phosphatases.

Protein tyrosine phosphatases (PTPases), together with protein tyrosine kinases, regulate the tyrosine phosphorylation that controls cell activities and proliferation. Previously, it has been recognized that both cytosolic PTPases and membrane associated, receptor-like PTPases exist. In order to examine the structural diversity of receptor-like PTPases, we isolated human cDNA clones that cross-hybridized to a Drosophila PTPase cDNA clone, DPTP12, under non-stringent hybridization conditions. The cDNA clones thus isolated included LCA and six other novel receptor-like PTPases, named HPTP alpha, beta, gamma, delta, epsilon, and zeta. The cytoplasmic regions of HPTP alpha and epsilon are highly homologous, and are composed of two tandemly duplicated PTPase-like domains. The extracellular regions of HPTP alpha and epsilon are, respectively, 123 amino acids and 27 amino acids, and do not have obvious similarity to any known protein. The cytoplasmic region of HPTP beta contains only one PTPase domain. The extracellular region of HPTP beta, which is 1599 amino acids, is composed of 16 fibronectin type-III repeats. HPTP delta is very similar to leukocyte common antigen related molecule (LAR), in both the extracellular and cytoplasmic regions. Partial sequences of HPTP gamma and zeta indicate that they are highly homologous and contain two PTPase-like domains. The PTPase-like domains of HPTP alpha, beta and delta expressed in Escherichia coli had tyrosine phosphatase activities.     

Expression and characterization of catalytic and regulatory domains of rat tyrosine hydroxylase.

Phenylalanine hydroxylase, tyrosine hydroxylase, and tryptophan hydroxylase constitute a family of tetrahydropterin-dependent aromatic amino acid hydroxylases. Comparison of the amino acid sequences of these three proteins shows that the C-terminal two-thirds are homologous, while the N-terminal thirds are not. This is consistent with a model in which the C-terminal two-thirds constitute a conserved catalytic domain to which has been appended discrete regulatory domains. To test such a model, two mutant proteins have been constructed, expressed in Escherichia coli, purified, and characterized. One protein contains the first 158 amino acids of rat tyrosine hydroxylase. The second lacks the first 155 amino acid residues of this enzyme. The spectral properties of the two domains suggest that their three-dimensional structures are changed only slightly from intact tyrosine hydroxylase. The N-terminal domain mutant binds to heparin and is phosphorylated by cAMP-dependent protein kinase at the same rate as the holoenzyme but lacks any catalytic activity. The C-terminal domain mutant is fully active, with Vmax and Km values identical to the holoenzyme; these results establish that all of the catalytic residues of tyrosine hydroxylase are located in the C-terminal 330 amino acids. The results with the two mutant proteins are consistent with these two segments of tyrosine hydroxylase being two separate domains, one regulatory and one catalytic.     

Site-directed mutagenesis of the N-terminal region of IGF binding protein 1; analysis of IGF binding capability.

To define domains involved in IGF binding 60 N-terminal amino acid residues of IGFBP-1 were deleted. This deletion resulted in loss of IGF binding suggesting that the N-terminus may enclose an IGF binding domain. However, most point mutations introduced in this region did not affect IGF binding. In contrast to Cys-34, only substitution of Cys-38 for a tyrosine residue abolished IGF binding. With the determination that all 18 cysteine residues are involved in disulphide bond formation our data suggest that, although not all cysteines contribute to the same extent, the ligand binding site may be spatially organized.     

Catalytic domains of the LAR and CD45 protein tyrosine phosphatases from Escherichia coli expression systems: purification and characterization for specificity and mechanism.

The cytoplasmic domains of two human transmembrane protein tyrosine phosphatases (PTPases), LAR and CD45, have been expressed in Escherichia coli, purified to near-homogeneity, and compared for catalytic efficiency toward several phosphotyrosine-containing peptide substrates. A 615-residue LAR fragment (LAR-D1D2) containing both tandemly repeated PTPase domains shows almost identical specific activity and high catalytic efficiency as the 40-kDa single-domain LAR-D1 fragment, consistent with a single functional active site in the 70-kDa LAR-D1D2 enzyme. A 90-kDa fragment of the human leukocyte CD45 PTPase, containing two similar tandemly repeated PTPase domains, shows parallel specificity to LAR-D1 and LAR-D1D2 with a high kcat/Km value for a phosphotyrosyl undecapeptide. Sufficient purified LAR-D1 and LAR-D1D2 PTPases were available to demonstrate enzymatic exchange of 18O from 18O4 inorganic phosphate into H2(16)O at rates of approximately 1 x 10(-2) s-1. The oxygen-18 exchange probably proceeds via a phosphoenzyme intermediate. Brief incubation of all three PTPase fragments with a [32P]phosphotyrosyl peptide substrate prior to quench with SDS sample buffer and gel electrophoresis led to autoradiographic detection of 32P-labeled enzymes. Pulse/chase studies on the LAR 32P-enzyme showed turnover of the labeled phosphoryl group.     

Active site labeling of a receptor-like protein tyrosine phosphatase.

The inactivation of the cytoplasmic domain of rat LAR, a receptor-like protein tyrosine phosphatase (PTPase), by iodoacetate and not by iodoacetamide suggested that iodoacetate interacts in a highly selective manner with the enzyme. The data indicate that iodoacetate binds at the active site of the enzyme with a stoichiometry of 0.8 mol of iodoacetate bound per mol of rat LAR. A single [14C]iodoacetate-labeled peptide was isolated following endoproteinase Lys-C digestion of the radiolabeled PTPase. Sequence analysis of the active site labeled peptide demonstrates that Cys-1522 contains the radiolabel. This residue has been shown by site-directed mutagenesis to be essential for rat LAR activity (Pot, D. A., Woodford, T. A., Remboutsika, E., Haun, R. S., and Dixon, J. E. (1991) J. Biol. Chem. 266, 19688-19696). Iodoacetate reacts only with the first domain of this double domain PTPase. These results, for the first time, directly identify the highly reactive cysteine residue at the active site of a PTPase and highlight the ability of this residue to participate as a nucleophile in the hydrolysis of phosphate from tyrosine.     

Oncogenic activation of the neu-encoded receptor protein by point mutation and deletion.

The rat neu gene, which encodes a receptor-like protein homologous to the epidermal growth factor receptor, is frequently activated by a point mutation altering a valine residue to a glutamic acid residue in its predicted transmembrane domain. Additional point mutations have been constructed in a normal neu cDNA at and around amino acid position 664, the site of the naturally arising mutation. A mutation which causes a substitution of a glutamine residue for the normal valine at residue 664 leads to full oncogenic activation of the neu gene, but five other substitutions do not. Substituted glutamic acid residues at amino acid positions 663 or 665 do not activate the neu gene. Thus only a few specific residues at amino acid residue 664 can activate the oncogenic potential of the neu gene. Deletion of sequences of the transforming neu gene demonstrates that no more than 420 amino acids of the 1260 encoded by the gene are required for full transforming function. Mutagenesis of the transforming clone demonstrates a correlation between transforming activity and tyrosine kinase activity. These data indicate that the activating point mutation induces transformation through (or together with) the activities of the tyrosine kinase.     

Novel putative protein tyrosine phosphatases identified by the polymerase chain reaction

Protein tyrosine phosphatases (PTPases) are a family of enzymes that specifically dephosphorylate phosphotyrosyl residues in selected protein substrates. To more fully understand the regulatory role of protein tyrosine phosphorylation and dephosphorylation in cellular signal transduction, characterization of PTPases is essential. Using the polymerase chain reaction and degenerate oligonucleotide primers corresponding to conserved amino acid sequences within the catalytic domain of PTPases, we have identified 11 PTPase-related human liver cDNA sequences. Five of these have not been described previously. These results indicate that, like protein tyrosine kinases, PTPases may also comprise a gene family with a large number of members.     

Evolution of the multifunctional protein tyrosine phosphatase family

The protein tyrosine phosphatase (PTP) family plays a central role in signal transduction pathways by controlling the phosphorylation state of serine, threonine, and tyrosine residues. PTPs can be divided into dual specificity phosphatases and the classical PTPs, which can comprise of one or two phosphatase domains. We studied amino acid substitutions at functional sites in the phosphatase domain and identified putative noncatalytic phosphatase domains in all subclasses of the PTP family. The presence of inactive phosphatase domains in all subclasses indicates that they were invented multiple times in evolution. Depending on the domain composition, loss of catalytic activity can result in different consequences for the function of the protein. Inactive single-domain phosphatases can still specifically bind substrate and protect it from dephosphorylation by other phosphatases. The inactive domains of tandem phosphatases can be further subdivided. The first class is more conserved, still able to bind phosphorylated tyrosine residues and might recruit multiphosphorylated substrates for the adjacent active domain. The second has accumulated several variable amino acid substitutions in the catalytic center, indicating a complete loss of tyrosine-binding capabilities. To study the impact of substitutions in the catalytic center to the evolution of the whole domain, we examined the evolutionary rates for each individual site and compared them between the classes. This analysis revealed a release of evolutionary constraint for multiple sites surrounding the catalytic center only in the second class, emphasizing its difference in function compared with the first class. Furthermore, we found a region of higher conservation common to both domain classes, suggesting a new regulatory center. We discuss the influence of evolutionary forces on the development of the phosphatase domain, which has led to additional functions, such as the specific protection of phosphorylated tyrosine residues, substrate recruitment, and regulation of the catalytic activity of adjacent domains.     

Cellular Redistribution of Protein Tyrosine Phosphatases LAR and PTPσ by Inducible Proteolytic Processing

Most receptor-like protein tyrosine phosphatases (PTPases) display a high degree of homology with cell adhesion molecules in their extracellular domains. We studied the functional significance of processing for the receptor-like PTPases LAR and PTPσ. PTPσ biosynthesis and intracellular processing resembled that of the related PTPase LAR and was expressed on the cell surface as a two-subunit complex. Both LAR and PTPσ underwent further proteolytical processing upon treatment of cells with either calcium ionophore A23187 or phorbol ester TPA. Induction of LAR processing by TPA in 293 cells did require overexpression of PKCα. Induced proteolysis resulted in shedding of the extracellular domains of both PTPases. This was in agreement with the identification of a specific PTPσ cleavage site between amino acids Pro₈₂₁ and Ile₈₂₂. Confocal microscopy studies identified adherens junctions and desmosomes as the preferential subcellular localization for both PTPases matching that of plakoglobin. Consistent with this observation, we found direct association of plakoglobin and β-catenin with the intracellular domain of LAR in vitro. Taken together, these data suggested an involvement of LAR and PTPσ in the regulation of cell contacts in concert with cell adhesion molecules of the cadherin/catenin family. After processing and shedding of the extracellular domain, the catalytically active intracellular portions of both PTPases were internalized and redistributed away from the sites of cell–cell contact, suggesting a mechanism that regulates the activity and target specificity of these PTPases. Calcium withdrawal, which led to cell contact disruption, also resulted in internalization but was not associated with prior proteolytic cleavage and shedding of the extracellular domain. We conclude that the subcellular localization of LAR and PTPσ is regulated by at least two independent mechanisms, one of which requires the presence of their extracellular domains and one of which involves the presence of intact cell–cell contacts. A key element in the regulation of cell–cell and cell– matrix contacts is the tyrosine phosphorylation of proteins that are localized in focal adhesions and at intercellular junctions (for reviews see Kemler, 1993; Clark and Brugge, 1995). While much is known about the protein tyrosine kinases involved in the phosphorylation of cell adhesion components, very little information exists about the identity of protein tyrosine phosphatases (PTPases),¹ which are responsible for the dephosphorylation and thereby regulation of these structural complexes. Probable candidates are those receptor-like PTPases that contain cell adhesion molecule-like extracellular domains and could therefore regulate their intrinsic phosphatase activity in response to cell contact. Recent reports suggest that some PTPases do, in fact, possess properties that resemble those of classical cell adhesion molecules (for review see Brady-Kalnay and Tonks, 1995). A direct involvement in cell–cell contact has so far been demonstrated for PTPμ (Brady-Kalnay et al., 1993; Gebbink et al., 1993) and PTPκ (Sap et al., 1994), for which a homophilic interaction between their extracellular domains was found. The localization of PTPμ (Brady-Kalnay et al., 1995; Gebbink et al., 1995), PTPκ (Fuchs et al., 1996), and PCP-2 (Wang et al., 1996) was restricted to sites of cell–cell contact and surface expression of PTPμ (Gebbink et al., 1995), and PTPκ (Fuchs et al., 1996) was increased in a cell density-dependent manner. Moreover, a direct association of PTPκ (Fuchs et al., 1996) and PTPμ (Brady-Kalnay et al., 1995) with members of the cadherin/catenin family suggests that proteins of the cell adhesion complex represent physiological substrates for these PTPases. A possible regulatory function in cell–matrix adhesion has been proposed for LAR, another receptor-like PTPase, which associated with focal cell–substratum adhesions via the newly identified LAR interacting protein 1, LIP-1 (Serra-Pages et al., 1995).PTPμ (Gebbink et al., 1991), PTPκ (Jiang et al., 1993; Fuchs et al., 1996), PTPδ (Krueger et al., 1990; Mizuno et al., 1993, Pulido et al., 1995a), PCP-2 (Wang et al., 1996), and LAR (Streuli et al., 1988, Pot et al., 1991) are members of the so-called type II receptor-like PTPases. The extracellular domains of these PTPases contain a variable number of Ig-like and fibronectin type III-like (FNIII) domains (for review see Charbonneau and Tonks, 1992). With the exception of PCP-2 (Wang et al., 1996), these PTPases also share characteristics in their biosynthesis. They all underwent proteolytic processing by a furin-like endoprotease and were expressed at the cell surface in two subunits which were not covalently linked (Streuli et al., 1992; Yu et al., 1992; Jiang et al., 1993; Brady-Kalnay and Tonks, 1994; Gebbink et al., 1995; Pulido et al., 1995a; Fuchs et al., 1996). It was shown for LAR that the E subunit, which contains the cell adhesion molecule-like extracellular domain, was shed from the cell surface when cells were grown to a high density (Streuli et al., 1992). This shedding of the E subunit of LAR was the result of an additional proteolytic processing step that could also be induced by treatment of the cells with the phorbol ester TPA (Serra-Pages et al., 1995). An accumulation of E subunits in the supernatant of cells was also observed for PTPμ (Gebbink et al., 1995) and PTPδ (Pulido et al., 1995a), and this suggests a common mechanism in the regulation of type II PTPases. However, the effect of proteolytic processing on either the catalytic activity, the substrate specificity, or the cellular localization of these PTPases has not yet been determined. We report here that PTPσ, a recently identified new member of the family of receptor-like type II PTPases (Pan et al., 1993; Walton et al., 1993; Yan et al., 1993; Ogata et al., 1994; Zhang et al., 1994), underwent biosynthesis and proteolytic processing in a manner that resembled that of the most closely related PTPase LAR. Moreover, further proteolytic processing of PTPσ as well as of LAR could be induced by treatment of the cells with TPA or the calcium ionophore A23187. Transient expression studies indicated that TPA-induced processing of LAR, but not PTPσ, was dependent on the coexpression of PKCα. Inducible processing of both PTPases took place in the extracellular segment of the P subunit in a juxtamembrane position and led to the shedding of the E subunit. Both LAR and PTPσ were predominantly localized in regions of cell–cell contact and accumulated in dot-like structures that could be identified as adherens junctions and desmosomes by colocalization with plakoglobin (Cowin et al., 1986). Moreover, plakoglobin and β-catenin, another component of E-cadherin–containing cell adhesion complexes in adherens junctions, associated directly with the intracellular domain of LAR in vitro. The inducible shedding of the E subunit of LAR and PTPσ was followed by a redistribution of the PTPases within the cell membrane and by an internalization of the cleaved P subunits. It therefore represents a mechanism through which the phosphatase activity of these PTPases could be regulated in response to cell–cell contact. The cell adhesion molecule-like character of LAR and PTPσ was further supported by the fact that the internalization of LAR and PTPσ occurred independently of the proteolytic processing if cells were grown in calcium-depleted growth medium. The analogies in specific localization as well as internalization behavior of PTPσ and LAR, with molecules of the cadherin/catenin family, strongly suggest a direct involvement of PTPσ and LAR in the formation or maintenance of intercellular contacts.     

Crystal structure of cold-active protein-tyrosine phosphatase from a psychrophile, Shewanella sp

The cold-active protein-tyrosine phosphatase (CAPTPase) of a psychrophile, Shewanella sp., shows high catalytic activity below 20 degrees C. The catalytic residue of CAPTPase is histidine, as opposed to the cysteine of known protein-tyrosine phosphatases (PTPases), and the enzyme protein has three amino acid sequences, Asp-Xaa-His, Gly-Asp-Xaa-Xaa-Asp-Arg and Gly-Asn-His-Glu, that are observed in many protein-serine/threonine phosphatases (PS/TPases). We have determined the crystal structures of CAPTPase at 1.82 angstroms and the enzyme bound with a phosphate ion at 1.90 angstroms resolution using X-ray crystallography and the multiple isomorphous replacement method. The final refined models are comprised of 331 amino acid residues, two metal ions, 447 water molecules, and an acetate or phosphate ion in an asymmetric unit. The enzyme protein consists of three beta-sheets, termed Sheet I, Sheet I', and Sheet II, and 14 alpha-helices. The CAPTPase has a different overall structure from known protein-tyrosine phosphatases. The arrangement of two metal ions, a phosphate ion and the adjacent amino acid residues in the catalytic site of CAPTPase is identical to that of PS/TPases. Thus, it was confirmed that the CAPTPase was a novel PTPase with a conformation similar to the catalytic site of PS/TPase. We speculate that the hydrophobic moiety around the catalytic residue of CAPTPase might play an important role in eliciting high activity at low temperature.     

Structure-function analysis of the UDP-N-acetyl-D-galactosamine:polypeptide N-acetylgalactosaminyltransferase. Essential residues lie in a predicted active site cleft resembling a lactose repressor fold

Mucin-type O-glycosylation is initiated by a family of UDP-GalNAc:polypeptide N-acetylgalactosaminyltransferases (ppGaNTases). Based on sequence relationships with divergent proteins, the ppGaNTases can be subdivided into three putative domains: each putative domain contains a characteristic sequence motif. The 112-amino acid glycosyltransferase 1 (GT1) motif represents the first half of the catalytic unit and contains a short aspartate-any residue-histidine (DXH) or aspartate-any residue-aspartate (DXD)-like sequence. Secondary structure predictions and structural threading suggest that the GT1 motif forms a 5-stranded parallel beta-sheet flanked by 4 alpha-helices, which resembles the first domain of the lactose repressor. Four invariant carboxylates and a histidine residue are predicted to lie at the C-terminal end of three beta-strands and line the active site cleft. Site-directed mutagenesis of murine ppGaNTase-T1 reveals that conservative mutations at these 5 positions result in products with no detectable enzyme activity (D156Q, D209N, and H211D) or <1% activity (E127Q and E213Q). The second half of the catalytic unit contains a DXXXXXWGGENXE motif (positions 310-322) which is also found in beta1,4-galactosyltransferases (termed the Gal/GalNAc-T motif). Mutants of carboxylates within this motif express either no detectable activity, 1% or 2% activity (E319Q, E322Q, and D310N, respectively). Mutagenesis of highly conserved (but not invariant) carboxylates produces only modest alterations in enzyme activity. Mutations in the C-terminal 128-amino acid ricin-like lectin motif do not alter the enzyme's catalytic properties.     

Thermosensitive mutants of the MPTP and hPTP1B protein tyrosine phosphatases: isolation and structural analysis.

A PCR-based random mutagenesis procedure was employed to identify several thermosensitive mutants of the MPTP enzyme, the murine homologue of the human T-cell PTPase and rat PTP-S enzymes. Four mutants with varying degrees of thermosensitivity were characterized for their thermostability and refolding properties following incubation at the nonpermissive temperature. Structure analysis of these mutations based on the hPTP1B co-ordinate structure demonstrates a clear relationship between the position of each mutated amino acid relative to the catalytic cysteine residue and their thermostability. Introduction of two of these mutations in the related enzyme hPTP1B suggests that the structural defects and the resulting thermosensitivity of these mutations may represent an intrinsic property of all PTPase catalytic domains.     

Enzymatic activity of poliovirus RNA polymerases with mutations at the tyrosine residue of the conserved YGDD motif: isolation and characterization of polioviruses containing RNA polymerases with FGDD and MGDD sequences.

The poliovirus RNA-dependent RNA polymerase (3Dpol) shares a region of homology with all RNA polymerases, centered around the amino acid motif YGDD, which has been postulated to be involved in the catalytic activity of the enzyme. Using oligonucleotide site-directed mutagenesis, we substituted the tyrosine at this motif of the poliovirus RNA-dependent RNA polymerase with cysteine, histidine, isoleucine, methionine, phenylalanine, or serine. The enzymes were expressed in Escherichia coli, and in vitro enzyme activity was tested. The phenylalanine and methionine substitutions resulted in enzymes with activity equal to that of the wild-type enzyme. The cysteine substitution resulted in an enzyme with approximately 50% of the wild-type activity, while the serine substitution resulted in an enzyme with approximately 10% of the wild-type activity; the isoleucine and histidine substitutions resulted in background levels of enzyme activity. To assess the effects of the mutants in viral replication, the mutant polymerase genes were subcloned into the infectious cDNA clone of poliovirus. Transfection of poliovirus cDNA containing the phenylalanine mutation in 3Dpol gave rise to virus in all of the transfection trials, while cDNA containing the methionine mutation resulted in virus in only 3 of 40 transfections. Transfection of cDNAs containing the other substitutions at the tyrosine residue did not result in infectious virus. The recovered viruses demonstrated kinetics of replication similar to those of the wild-type virus, as measured by [3H]uridine incorporation at either 37 or 39 degrees C. RNA sequence analysis of the 3Dpol gene of both viruses demonstrated that the tyrosine-to-phenylalanine or tyrosine-to-methionine mutation was still present. No other differences in the 3Dpol gene between the wild-type and phenylalanine-containing virus were found. The virus containing the methionine mutation also contained two other nucleotide changes from the wild-type 3Dpol sequence; one resulted in a glutamic acid-to-aspartic acid change at amino acid 108 of the polymerase, and the other resulted in a C-to-T base change at nucleotide 6724, which did not result in an amino acid change. To confirm that the second amino acid mutation found in the 3Dpol gene of the methionine-substituted virus allowed for replication ability, a mutation corresponding to the glutamic acid-to-aspartic acid change was made in the polymerase containing the methionine substitution, and this double-mutant polymerase was expressed in E. coli. The double-mutant enzyme was as active as the wild-type enzyme under in vitro assay conditions.(ABSTRACT TRUNCATED AT 400 WORDS)     

Insulin receptor protein-tyrosine phosphatases. Leukocyte common antigen-related phosphatase rapidly deactivates the insulin receptor kinase by preferential dephosphorylation of the receptor regulatory domain.

A number of protein-tyrosine phosphatase(s) (PTPases) have been shown to dephosphorylate the insulin receptor in vitro; however, it is not known whether any individual PTPase has specificity for certain phosphotyrosine residues of the receptor that regulate its intrinsic tyrosine kinase activity. We evaluated the deactivation of the insulin receptor kinase by three candidate enzymes that are expressed in insulin-sensitive rat tissues, including the receptor-like PTPases LAR and LRP, and the intracellular enzyme, PTPase1B. Purified insulin receptors were activated by insulin and receptor dephosphorylation, and kinase activity was quantitated after incubation with recombinant PTPases from an Escherichia coli expression system. When related to the level of overall receptor dephosphorylation, LAR deactivated the receptor kinase 3.1 and 2.1 times more rapidly than either PTPase1B or LRP, respectively (p less than 0.03). To assess whether these effects were associated with preferential dephosphorylation of the regulatory (Tyr-1150) domain of the receptor beta-subunit, we performed tryptic mapping of the insulin receptor beta-subunit after dephosphorylation by PTPases. Relative to the rate of initial loss of 32P from receptor C-terminal sites, LAR dephosphorylated the Tris-phosphorylated Tyr-1150 domain 3.5 and 3.7 times more rapidly than either PTPase1B or LRP, respectively (p less than 0.01). The accelerated deactivation of the insulin receptor kinase by LAR and its relative preference for regulatory phosphotyrosine residues further support a potential role for this transmembrane PTPase in the physiological regulation of insulin receptors in intact cells.     

Structure-activity relationship of diacylglycerol kinase theta

Diacylglycerol kinase (DGK) phosphorylates the second messenger diacylglycerol (DAG) to phosphatidic acid (PA). Among the nine mammalian isotypes identified, DGKtheta is the only one with three cysteine-rich domains (CRDs) (instead of two) in its N-terminal regulatory region. We previously reported that DGKtheta binds to and is negatively regulated by active RhoA. We now report that RhoA strongly binds to the C-terminal catalytic domain, which would explain its inhibition of DGK activity. To help finding a physiological function of DGKtheta, we further determined its activity in vitro as a function of 15 different truncations and point mutations in the primary structure. Most of these alterations, located throughout the protein, inactivated the enzyme, suggesting that catalytic activity depends on all of its conserved domains. The most C-terminal CRD is elongated with a stretch of 15 amino acids that is highly conserved among DGK isotypes. Mutation analysis revealed a number of residues in this region that were essential for enzyme activity. We suggest that this CRD extension plays an essential role in the correct folding of the protein and/or in substrate presentation to the catalytic region of the protein.     

CD45 tyrosine phosphatase activity and membrane anchoring are required for T-cell antigen receptor signaling.

T cells that lack the CD45 transmembrane tyrosine phosphatase have a variety of T-cell receptor (TCR) signaling defects that are corrected by reexpression of wild-type CD45 or its intracytoplasmic domains. In this study, a chimeric molecule containing the myristylation sequence of Src and the intracellular portion of CD45, previously shown to restore function in CD45- T cells, was mutagenized to determine if membrane-associated CD45 tyrosine phosphatase activity is required to restore TCR-mediated signaling in CD45- T cells. Abolition of enzymatic activity by substitution of a serine for a critical cysteine in the first catalytic domain resulted in failure of this molecule to restore TCR signaling. Another mutation, in which a single amino acid substitution destroyed the myristylation site, resulted in failure of the chimeric molecule to partition to the plasma membrane. Although expressed at high levels and enzymatically active, this form of intracellular CD45 also failed to restore normal signaling in CD45- T cells. These findings strongly suggest that CD45's function in TCR signaling requires its proximity to membrane-associated tyrosine phosphatase substrates.