Modulation of catalytic activity in multi-domain protein tyrosine phosphatases

Signaling mechanisms involving protein tyrosine phosphatases govern several cellular and developmental processes. These enzymes are regulated by several mechanisms which include variation in the catalytic turnover rate based on redox stimuli, subcellular localization or protein-protein interactions. In the case of Receptor Protein Tyrosine Phosphatases (RPTPs) containing two PTP domains, phosphatase activity is localized in their membrane-proximal (D1) domains, while the membrane-distal (D2) domain is believed to play a modulatory role. Here we report our analysis of the influence of the D2 domain on the catalytic activity and substrate specificity of the D1 domain using two Drosophila melanogaster RPTPs as a model system. Biochemical studies reveal contrasting roles for the D2 domain of Drosophila Leukocyte antigen Related (DLAR) and Protein Tyrosine Phosphatase on Drosophila chromosome band 99A (PTP99A). While D2 lowers the catalytic activity of the D1 domain in DLAR, the D2 domain of PTP99A leads to an increase in the catalytic activity of its D1 domain. Substrate specificity, on the other hand, is cumulative, whereby the individual specificities of the D1 and D2 domains contribute to the substrate specificity of these two-domain enzymes. Molecular dynamics simulations on structural models of DLAR and PTP99A reveal a conformational rationale for the experimental observations. These studies reveal that concerted structural changes mediate inter-domain communication resulting in either inhibitory or activating effects of the membrane distal PTP domain on the catalytic activity of the membrane proximal PTP domain.     

Mutational analysis of Ca(2+)/calmodulin-dependent protein kinase phosphatase (CaMKP)

Ca(2+)/calmodulin-dependent protein kinase phosphatase (CaMKP) is a member of the serine/threonine protein phosphatases and shares 29% sequence identity with protein phosphatase 2Calpha (PP2Calpha) in its catalytic domain. To investigate the functional domains of CaMKP, mutational analysis was carried out using various recombinant CaMKPs expressed in Escherichia coli. Analysis of N-terminal deletion mutants showed that the N-terminal region of CaMKP played important roles in the formation of the catalytically active structure of the enzyme, and a critical role in polycation stimulation. A chimera mutant, a fusion of the N-terminal domain of CaMKP and the catalytic domain of PP2Calpha, exhibited similar substrate specificity to CaMKP but not to PP2Calpha, suggesting that the N-terminal region of CaMKP is crucial for its unique substrate specificity. Point mutations at Arg-162, Asp-194, His-196, and Asp-400, highly conserved amino acid residues in the catalytic domain of PP2C family, resulted in a significant loss of phosphatase activity, indicating that these amino acid residues may play important roles in the catalytic activity of CaMKP. Although CaMKP(1-412), a C-terminal truncation mutant, retained phosphatase activity, it was found to be much less stable upon incubation at 37 degrees C than wild type CaMKP, indicating that the C-terminal region of CaMKP is important for the maintenance of the catalytically active conformation. The results suggested that the N- and C-terminal sequences of CaMKP are essential for the regulation and stability of CaMKP.     

A JAK1/JAK2 chimera can sustain alpha and gamma interferon responses.

Cell lines that are mutated in interferon (IFN) responses have been critical in establishing an essential role for the JAK family of nonreceptor tyrosine kinases in interferon signalling. Mutant gamma1A cells have previously been shown to be complemented by overexpression of JAK2. Here, it is shown that these cells carry a defect in, and can also be complemented by, the beta-subunit of the IFN-gamma receptor, consistent with the hypothesis that the mutation in these cells affects JAK2-receptor association. In contrast, mutant gamma2A cells lack detectable JAK2 mRNA and protein. By using gamma2A cells, the role of various domains and conserved tyrosine residues of JAK2 in IFN-gamma signalling was examined. Individual mutation of six conserved tyrosine residues, mutation of a potential phosphatase binding site, or mutation of the arginine residue in the proposed SH2-like domain had no apparent effect on signalling in response to IFN-gamma. Results with deletion mutants, however, indicated that association of JAK2 with the IFN-gammaR2 subunit requires the amino-terminal region but not the pseudokinase domain. Consistent with this, in chimeras with JAK1, the JAK2 amino-terminal region was required for receptor association and STAT1 activation. Conversely, a JAK1-JAK2 chimera with the amino-terminal domains of JAK1 linked to the pseudokinase and kinase domains of JAK2 is capable of reconstituting JAK-STAT signalling in response to IFN-alpha and -gamma in mutant U4C cells lacking JAK1. The specificity of the JAKs may therefore lie mainly in their structural interaction with different receptor and signalling proteins rather than in the substrate specificity of their kinase domains.     

Intramolecular interactions in protein tyrosine phosphatase RPTPmu: kinetic evidence

The receptor-like protein tyrosine phosphatase RPTPmu contains three intracellular domains: the juxtamembrane (JM) and two phosphatase domains (D1 and D2). D1 is catalytically active in vitro. The functional roles of JM and D2 are still unclear. To find out whether and how they modulate the phosphatase activity of D1, we compared the enzymatic characteristics of two constructs, containing a truncated JM and either D1 or both phosphatase domains. p-Nitrophenyl phosphate and two peptide substrates were efficiently dephosphorylated by both constructs. The specificity constant of D1 alone was up to 50% higher. D2 induces (a) decreased K(m) values for peptide substrates, (b) decreased catalytic efficiency for these substrates, (c) shifting of the optimal pH to slightly lower values, and (d) looser binding of competitive inhibitors. These data suggest that the phosphatase activity of D1 is negatively modulated and its ligand binding capacity is sensibly modified by domain D2, having possible functional significance.     

Polyamine-mediated turnover of ornithine decarboxylase in Chinese-hamster ovary cells.

The major secreted isoenzyme of human prostatic acid phosphatase (PAcP) (EC 3.1.3.2), which catalyses p-nitrophenyl phosphate (PNPP) hydrolysis at acid pH values, was found to have phosphotyrosyl protein phosphatase activity since it dephosphorylated three different phosphotyrosine-containing protein substrates. Several lines of evidence are presented to show that the phosphotyrosyl phosphatase and PAcP are the same enzyme. A highly purified PAcP enzyme preparation which contains a single N-terminal peptide sequence was used to test for the phosphotyrosyl phosphatase activity. Both activities comigrated during gel filtration by high performance liquid chromatography. Phosphotyrosyl phosphatase activity and PNPP acid phosphatase activity exhibited similar sensitivities to different effectors. Both phosphatase activities showed the same thermal stability. Specific anti-PAcP antibody reacted to the same extent with both phosphatase activities. PNPP acid phosphatase activity was competitively inhibited by the phosphotyrosyl phosphatase substrate. To characterize further the phosphotyrosyl phosphatase activity, the Km values using different phosphoprotein substrates were determined. The apparent Km values for phosphorylated angiotensin II, anti-pp60src immunoglobulin G and casein were in the nM range for phosphotyrosine residues, which was about 50-fold lower than the Km for phosphoserine residues in casein.     

Coxsackievirus and Adenovirus Receptor Amino-Terminal Immunoglobulin V-Related Domain Binds Adenovirus Type 2 and Fiber Knob from Adenovirus Type 12

The extracellular region of the coxsackievirus and adenovirus receptor (CAR) is predicted to consist of two immunoglobulin (Ig)-related structural domains. We expressed the isolated CAR amino-terminal domain (D1) and a CAR fragment containing both extracellular Ig domains (D1/D2) in Escherichia coli. Both D1 and D1/D2 formed complexes in vitro with the recombinant knob domain of adenovirus type 12 (Ad12) fiber, and D1 inhibited adenovirus type 2 (Ad2) infection of HeLa cells. These results indicate that the adenovirus-binding activity of CAR is localized in the amino-terminal IgV-related domain and confirm our earlier observation that Ad2 and Ad12 bind to the same cellular receptor. Preliminary crystallization studies suggest that complexes of Ad12 knob bound to D1 will be suitable for structure determination.     

An essential role of domain D in the hormone-binding activity of human beta 1 thyroid hormone nuclear receptor

By analogy with steroid receptors, human placental thyroid hormone nuclear receptor (hTR beta 1) could be divided into four functional domains: A/B (Met1-Leu101), C (Cys102-Ala170), D (Thr171-Lys237), and E (Arg238-Asp456). The E domain was thought to bind thyroid hormone. To evaluate whether domain E alone is sufficient to bind T3 or requires the presence of other domains for functional T3-binding activity, a series of deletion mutants was constructed. The mutants were expressed in Escherichia coli, and the expressed proteins were purified. Analysis of the T3-binding affinity and analog specificity of the purified truncated hTR beta 1 indicated that domain E alone did not have T3-binding activity. Extension of the amino-terminal sequence of domain E to include part of domain D yielded a mutant (Lys201-Asp456) with a Ka for T3 of 0.5 +/- 0.2 x 10(9) M-1. Further extension to include the entire domain D (Met169-Asp456) yielded a mutant with T3-binding activity with a Ka of 0.8 +/- 0.1 x 10(9) M-1. Further extension of the amino-terminal sequence to include domain C increased the affinity for T3 by nearly 2-fold (Ka = 1.5 +/- 0.4 x 10(9) M-1). The Ka for the wild-type hTR beta 1 is 1.5 +/- 0.2 x 10(9) M-1. Furthermore, mutant (Met169-Asp456) binds to 3',5',3-triiodo-L-thyropropionic acid, D-T3, L-T4, and L-T3 with 307%, 37%, 7%, and 0.1%, respectively, of the activity of L-T3. This order of analog affinity is similar to that of the wild-type hTR beta 1.(ABSTRACT TRUNCATED AT 250 WORDS)     

The juxtamembrane regions of the epidermal growth factor receptor and gp185erbB-2 determine the specificity of signal transduction.

The epidermal growth factor receptor (EGFR) and gp185erbB-2 are closely related tyrosine kinases. Despite extensive sequence and structural homology, these two receptors display quantitative and qualitative differences in their ability to couple with mitogenic signalling pathways. By using chimeric molecules between EGFR and erbB-2, we found that the determinants responsible for the specificity of mitogenic signal transduction are located in the amino-terminal half of the tyrosine kinase domain of either receptor. In the EGFR, mutational analysis within this subdomain revealed that deletion of residues 660 to 667 impaired receptor mitogenic activity without affecting its tyrosine kinase properties. This sequence is therefore likely to contribute to the specificity of substrate recognition by the EGFR kinase.     

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.     

The pleckstrin homology domain of protein kinase D interacts preferentially with the eta isoform of protein kinase C

The results presented here demonstrate that protein kinase D (PKD) and PKCeta transiently coexpressed in COS-7 cells form complexes that can be immunoprecipitated from cell lysates using specific antisera to PKD or PKCeta. The presence of PKCeta in PKD immune complexes was initially detected by in vitro kinase assays which reveal the presence of an 80-kDa phosphorylated band in addition to the 110-kDa band corresponding to autophosphorylated PKD. The association between PKD and PKCeta was further verified by Western blot analysis and peptide phosphorylation assays that exploited the distinct substrate specificity between PKCs and PKD. By the same criteria, PKD formed complexes only very weakly with PKCepsilon, and did not bind PKCzeta. When PKCeta was coexpressed with PKD mutants containing either complete or partial deletions of the PH domain, both PKCeta immunoreactivity and PKC activity in PKD immunoprecipitates were sharply reduced. In contrast, deletion of an amino-terminal portion of the molecule, either cysteine-rich region, or the entire cysteine-rich domain did not interfere with the association of PKD with PKCeta. Furthermore, a glutathione S-transferase-PKDPH fusion protein bound preferentially to PKCeta. These results indicate that the PKD PH domain can discriminate between closely related structures of a single enzyme family, e.g. novel PKCs epsilon and eta, thereby revealing a previously undetected degree of specificity among protein-protein interactions mediated by PH domains.     

Chimeras of hepatic lipase and lipoprotein lipase. Domain localization of enzyme-specific properties.

Chimeric molecules between human lipoprotein lipase (LPL) and rat hepatic lipase (HL) were used to identify structural elements responsible for functional differences. Based on the close sequence homology with pancreatic lipase, both LPL and HL are believed to have a two-domain structure composed of an amino-terminal (NH2-terminal) domain containing the catalytic Ser-His-Asp triad and a smaller carboxyl-terminal (COOH-terminal) domain. Experiments with chimeric lipases containing the HL NH2-terminal domain and the LPL COOH-terminal domain (HL/LPL) or the reverse chimera (LPL/HL) showed that the NH2-terminal domain is responsible for the catalytic efficiency (Vmax/Km) of these enzymes. Furthermore, it was demonstrated that the stimulation of LPL activity by apolipoprotein C-II and the inhibition of activity by 1 M NaCl originate in structural features within the NH2-terminal domain. HL and LPL bind to vascular endothelium, presumably by interaction with cell surface heparan sulfate proteoglycans. However, the two enzymes differ significantly in their heparin affinity. Experiments with the chimeric lipases indicated that heparin binding avidity was primarily associated with the COOH-terminal domain. Specifically, both HL and the LPL/HL chimera were eluted from immobilized heparin by 0.75 M NaCl, whereas 1.1 M NaCl was required to elute LPL and the HL/LPL chimera. Finally, HL is more active than LPL in the hydrolysis of phospholipid substrates. However, the ratio of phospholipase to neutral lipase activity in both chimeric lipases was enhanced by the presence of the heterologous COOH-terminal domain, demonstrating that this domain strongly influences substrate specificity. The NH2-terminal domain thus controls the kinetic parameters of these lipases, whereas the COOH-terminal domain modulates substrate specificity and heparin binding.     

Identification of the catalytic and DNA-binding region of the human immunodeficiency virus type I integrase protein.

The integrase (IN) protein of the human immunodeficiency virus (HIV) is required for specific cleavage of the viral DNA termini, and subsequent integration of the viral DNA into target DNA. To identify the various domains of the IN protein we generated a series of IN deletion mutants as fusions to maltose-binding protein (MBP). The deletion mutants were tested for their ability to bind DNA, to mediate site-specific cleavage of the viral DNA ends, and to carry out integration and disintegration reactions. We found that the DNA-binding region resides between amino acids 200 and 270 of the 288-residues HIV-1 IN protein. The catalytic domain of the protein was mapped between amino acids 50 and 194. For the specific activities of IN, cleavage of the viral DNA and integration, both the DNA-binding domain and the conserved amino-terminal region of IN are required. These regions are dispensable however, for disintegration activity.     

Domains involved in multimer assembly of von willebrand factor (vWF): multimerization is independent of dimerization.

The precursor protein of von Willebrand factor (pro-vWF) consist of four repeated domains, denoted D1-D2-D'-D3-A1-A2-A3-D4-B1-B2-B3-C1-C2. The domains D1 and D2 constitute the amino-terminal pro-polypeptide and the remaining domains mature vWF, generated upon proteolytic processing. We have shown previously that the pro-polypeptide of pro-vWF is obligatory for assembly of pro-vWF dimers into multimers, a process vital for efficient adhesion of platelets to an injured vessel wall. Here, we have employed full length vWF cDNA to construct a series of deletion mutants, based on the homology between the various domains. Specifically, the domains D', D3 or both were deleted and the multimeric pattern of the mutant vWF proteins was analysed after transient expression in COS-1 cells. It is demonstrated that in addition to the pro-polypeptide, both the D' and the D3 domain are required for multimer assembly. Furthermore, by analysing a construct containing only the domains D' and D3 next to the pro-polypeptide it is shown that this is the only part of the vWF protein involved in multimer assembly. Since, the formation of pro-vWF dimers relies on the carboxy-terminal area of mature vWF, it is concluded that multimer assembly is a process independent of dimerization.     

Purification and characterization of purple acid phosphatase PAP1 from dry powder of sweet potato

Purple acid phosphatase (PAP) was purified from sweet potato dry powder, which is used as a food additive. Spectrometric and enzymatic analyses, and analysis of the amino-terminal sequence indicated that the purified purple acid phosphatase was PAP1. High activity in neutral and acidic conditions, broad substrate specificity, and good thermal stability of PAP1 suggest the possibility of practical applications of PAP1.     

Functional analysis of chimeric proteins of the Wilson Cu(I)-ATPase (ATP7B) and ZntA, a Pb(II)/Zn(II)/Cd(II)-ATPase from Escherichia coli

ATP7B, the Wilson disease-associated Cu(I)-transporter, and ZntA from Escherichia coli are soft metal P1-type ATPases with mutually exclusive metal ion substrates. P1-type ATPases have a distinctive amino-terminal domain containing the conserved metal-binding motif GXXCXXC. ZntA has one copy of this motif while ATP7B has six copies. The effect of interchanging the amino-terminal domains of ATP7B and ZntA was investigated. Chimeric proteins were constructed in which either the entire amino-terminal domain of ATP7B or only its sixth metal-binding motif replaced the amino-terminal domain of ZntA. Both chimeras conferred resistance to lead, zinc, and cadmium salts but not to copper salts. The purified chimeras displayed activity with lead, cadmium, zinc, and mercury, which are substrates of ZntA. There was no activity with copper or silver, which are substrates of ATP7B. The chimeras were 2-3-fold less active than ZntA. Thus, the amino-terminal domain of P1-type ATPases cannot alter the metal specificity determined by the transmembrane segment. Also, these results suggest that this domain interacts with the rest of the transporter in a metal ion-specific manner; the amino-terminal domain of ATP7B cannot replace that of ZntA in restoring full catalytic activity.     

Selective activation of the two catalytic sites in the ATP.Mg-dependent phosphoprotein phosphatase by kinase Fa and Mn2+ ion

1. Although Mn2+ could mimic kinase FA/ATP.Mg to activate ATP.Mg-dependent protein phosphatase, strong indications have been obtained that the Mn2(+)-activated and FA/ATP.Mg-activated phosphatase forms are not identical in terms of their substrate specificities and catalytic properties. 2. Both Mn2(+)-activated and FA/ATP.Mg-activated phosphatase forms readily dephosphorylate 32P-labeled phosphorylase a and myelin basic protein (MBP), however the Mn2(+)-activated phosphatase displays activity preferentially against [32P]MBP and FA/ATP.Mg-activated phosphatase preferentially dephosphorylates [32P]phosphorylase a, representing a unique control mechanism to regulate the substrate specificity of multisubstrate protein phosphatase in mammalian tissues.     

Regulation of the dual specificity protein phosphatase, DsPTP1, through interactions with calmodulin

Reversible phosphorylation is a key mechanism for the control of intercellular events in eukaryotic cells. In animal cells, Ca2+/CaM-dependent protein phosphorylation and dephosphorylation are implicated in the regulation of a number of cellular processes. However, little is known on the functions of Ca2+/CaM-dependent protein kinases and phosphatases in Ca2+ signaling in plants. From an Arabidopsis expression library, we isolated cDNA encoding a dual specificity protein phosphatase 1, which is capable of hydrolyzing both phosphoserine/threonine and phosphotyrosine residues of the substrates. Using a gel overlay assay, we identified two Ca2+-dependent CaM binding domains (CaMBDI in the N terminus and CaMBDII in the C terminus). Specific binding of CaM to two CaMBD was confirmed by site-directed mutagenesis, a gel mobility shift assay, and a competition assay using a Ca2+/CaM-dependent enzyme. At increasing concentrations of CaM, the biochemical activity of dual specificity protein phosphatase 1 on the p-nitrophenyl phosphate (pNPP) substrate was increased, whereas activity on the phosphotyrosine of myelin basic protein (MBP) was inhibited. Our results collectively indicate that calmodulin differentially regulates the activity of protein phosphatase, dependent on the substrate. Based on these findings, we propose that the Ca2+ signaling pathway is mediated by CaM cross-talks with a protein phosphorylation signal pathway in plants via protein dephosphorylation.     

Functional Domains of the Rsp5 Ubiquitin-Protein Ligase

RSP5, an essential gene of Saccharomyces cerevisiae, encodes a hect domain E3 ubiquitin-protein ligase. Hect E3 proteins have been proposed to consist of two broad functional domains: a conserved catalytic carboxyl-terminal domain of approximately 350 amino acids (the hect domain) and a large, nonconserved amino-terminal domain containing determinants of substrate specificity. We report here the mapping of the minimal region of Rsp5 necessary for its essential in vivo function, the minimal region necessary to stably interact with a substrate of Rsp5 (Rpb1, the large subunit of RNA polymerase II), and the finding that the hect domain, by itself, is sufficient for formation of the ubiquitin-thioester intermediate. Mutations within the hect domain that affect either the ability to form a ubiquitin-thioester or to catalyze substrate ubiquitination abrogate in vivo function, strongly suggesting that the ubiquitin-protein ligase activity of Rsp5 is intrinsically linked to its essential function. The amino-terminal region of Rsp5 contains three WW domains and a C2 calcium-binding domain. Two of the three WW domains are required for the essential in vivo function, while the C2 domain is not, and requirements for Rpb1 binding and ubiquitination lie within the region required for in vivo function. Together, these results support the two-domain model for hect E3 function and indicate that the WW domains play a role in the recognition of at least some of the substrates of Rsp5, including those related to its essential function. In addition, we show that haploid yeast strains bearing complete disruptions of either of two other hect E3 genes of yeast, designated HUL4 (YJR036C) and HUL5 (YGL141W), are viable.