A modified pGEX expression system that eliminates degradation products and thrombin from the recombinant protein

Structural versatility that serves the function of the HRD motif in the catalytic loop of protein tyrosine kinase, Src

Site-directed mutagenesis is a traditional approach for structure-function analysis of protein tyrosine kinases, and it requires the generation, expression, purification, and analysis of each mutant enzyme. In this study, we report a versatile high throughput bacterial screening system that can identify functional kinase mutants by immunological detection of tyrosine phosphorylation. Two key features of this screening system are noteworthy. First, instead of blotting bacterial colonies directly from Agar plates to nitrocellulose membrane, the colonies were cultured in 96-well plates, and then spotted in duplicate onto the membrane with appropriate controls. This made the screening much more reliable compared with direct colony blotting transfer. A second feature is the parallel use of a protein tyrosine phosphatase (PTP)-expressing host and a non-PTP-expressing host. Because high activity Src mutants are toxic to the host, the PTP system allowed the identification of Src mutants with high activity, while the non-PTP system identified Src mutants with low activity. This approach was applied to Src mutant libraries randomized in the highly conserved HRD motif in the catalytic loop, and revealed that structurally diverse residues can replace the His and Arg residues, while the Asp residue is irreplaceable for catalytic activity.

Aptabody-aptatope interactions in aptablotting assays

We demonstrate an aptablotting assay method that involves direct and indirect aptabody recognition. Nanoscale single-stranded DNA aptamers against GST and DIG-tags are utilized as aptabodies (GST-2 and DIG-1, respectively), and the GST-2 aptabody binding site, or aptatope, as predicted by a MOE-docking simulation of the protein-aptamer complex, shows the interaction of the GST-2 aptabody at the catalytically active region. The aptabody-aptatope interaction was evaluated by an in vitro enzyme inhibitory analysis. The binding capacity of the GST-2 aptabody was assessed by dot-blot, EMSA and SDS-PAGE/electroblot analyses, and the results showed that the aptabodies interact with both the native mono-/dimeric form and the denatured GST form on a membrane. The use of aptabodies can overcome the obstacles of current immunoblot assays, and these molecules are easily assessable via ELISA systems. Moreover, the hybridization of aptabodies and antibodies (hybrid-aptablotting) may have considerable impacts on the design of bioassay platforms.

Conformational basis for SH2-Tyr(P)527 binding in Src inactivation

Src protein-tyrosine kinase contains a myristoylation motif, a unique region, an Src homology (SH) 3 domain, an SH2 domain, a catalytic domain, and a C-terminal tail. The C-terminal tail contains a Tyr residue, Tyr527. Phosphorylation of Tyr527 triggers Src inactivation, caused by Tyr(P)527 binding to the SH2 domain. In this study, we demonstrated that a conformational contribution, not affinity, is the predominant force for the intramolecular SH2-Tyr(P)527 binding, and we characterized the structural basis for this conformational contribution. First, a phosphopeptide mimicking the C-terminal tail is an 80-fold weaker ligand than the optimal phosphopeptide, pYEEI, and similar to a phosphopeptide containing three Ala residues following Tyr(P) in binding to the Src SH2 domain. Second, the SH2-Tyr(P)527 binding is largely independent of the amino acid sequence surrounding Tyr(P)527, and only slightly decreased by an inactivating mutation in the SH2 domain. Furthermore, even the unphosphorylated C-terminal tail with the sequence of YEEI suppresses Src activity by binding to the SH2 domain. These experiments demonstrate that very weak affinity is sufficient for the SH2-Tyr(P)527 binding in Src inactivation. Third, the effective intramolecular SH2-Tyr(P)527 binding is attributed to a conformational contribution that requires residues Trp260 and Leu255. Although the SH3 domain is essential for Src inactivation by Tyr(P)527, it does not contribute to the SH2-Tyr(P)527 binding. These findings suggest a conformation-based Src inactivation model, which provides a unifying framework for understanding Src activation by a variety of mechanisms.

Docking-based Substrate Recognition by the Catalytic Domain of a Protein Tyrosine Kinase, C-terminal Src Kinase (Csk)

Protein tyrosine kinases are key enzymes of mammalian signal transduction. Substrate specificity is a fundamental property that determines the specificity and fidelity of signaling by protein tyrosine kinases. However, how protein tyrosine kinases recognize the protein substrates is not well understood. C-terminal Src kinase (Csk) specifically phosphorylates Src family kinases on a C-terminal Tyr residue, which down-regulates their activities. We have previously determined that Csk recognizes Src using a substrate-docking site away from the active site. In the current study, we identified the docking determinants in Src recognized by the Csk substrate-docking site and demonstrated an interaction between the docking determinants of Src and the Csk substrate-docking site for this recognition. A similar mechanism was confirmed for Csk recognition of another Src family kinase, Yes. Although both Csk and MAP kinases used docking sites for substrate recognition, their docking sites consisted of different substructures in the catalytic domain. These results helped establish a docking-based substrate recognition mechanism for Csk. This model may provide a framework for understanding substrate recognition and specificity of other protein tyrosine kinases.

Structural basis for domain-domain communication in a protein tyrosine kinase, the C-terminal Src kinase

The catalytic activity of protein tyrosine kinases is commonly regulated by domain-domain interactions. The C-terminal Src kinase (Csk) contains a catalytic domain and the regulatory SH3 and SH2 domains. Both the presence of the regulatory domains and binding of specific phosphotyrosine-containing proteins to the SH2 domain activate Csk. The structural basis for both modes of activation is investigated here. First, the SH3-SH2 linker is crucial for Csk activation. Mutagenic and kinetic studies demonstrate that this activation is mediated by a cation-pi interaction between Arg68 and Trp188. Second, Ala scanning and kinetic analyses on residues in the SH2-catalytic domain interface identify three functionally distinct types of residues in mediating the communication between the SH2 and the catalytic domains. Type I residues are important in mediating a ligand-triggered activation of Csk because their mutation severely reduces Csk activation by the SH2 domain ligand. Type II residues are involved in suppressing Csk activity, and their mutation activates Csk, but makes Csk less sensitive to activation by the SH2 ligand. Both type I and type II residues are likely involved in mediating SH2 ligand-triggered activation of Csk. Type III residues are those located in the SH2 domain whose mutation severely decreases Csk catalytic activity without affecting the SH2 ligand-triggered activation. These residues likely mediate SH2 activation of Csk regardless of SH2-ligand interaction. These studies lead us to propose a domain-domain communication model that provides functional insights into the topology of Csk family of protein tyrosine kinases.

Characterization of the interactions between the active site of a protein tyrosine kinase and a divalent metal activator

BACKGROUND

Protein tyrosine kinases are important enzymes for cell signalling and key targets for anticancer drug discovery. The catalytic mechanisms of protein tyrosine kinase-catalysed phosphorylation are not fully understood. Protein tyrosine kinase Csk requires two Mg2+ cations for activity: one (M1) binds to ATP, and the other (M2) acts as an essential activator.

RESULTS

Experiments in this communication characterize the interaction between M2 and Csk. Csk activity is sensitive to pH in the range of 6 to 7. Kinetic characterization indicates that the sensitivity is not due to altered substrate binding, but caused by the sensitivity of M2 binding to pH. Several residues in the active site with potential of binding M2 are mutated and the effect on metal activation studied. An active mutant of Asn319 is generated, and this mutation does not alter the metal binding characteristics. Mutations of Glu236 or Asp332 abolish the kinase activity, precluding a positive or negative conclusion on their role in M2 coordination. Finally, the ability of divalent metal cations to activate Csk correlates to a combination of ionic radius and the coordination number.

CONCLUSION

These studies demonstrate that M2 binding to Csk is sensitive to pH, which is mainly responsible for Csk activity change in the acidic arm of the pH response curve. They also demonstrate critical differences in the metal activator coordination sphere in protein tyrosine kinase Csk and a protein Ser/Thr kinase, the cAMP-dependent protein kinase. They shed light on the physical interactions between a protein tyrosine kinase and a divalent metal activator.

Functional Diversity of Csk, Chk, and Src SH2 Domains due to a SingleResidueVariation

The C-terminal Src kinase (Csk) family of protein tyrosine kinases contains two members: Csk and Csk homologous kinase (Chk). Both phosphorylate and inactivate Src family kinases. Recent reports suggest that the Src homology (SH) 2 domains of Csk and Chk may bind to different phosphoproteins, which provides a basis for different cellular functions for Csk and Chk. To verify and characterize such a functional divergence, we compared the binding properties of the Csk, Chk, and Src SH2 domains and investigated the structural basis for the functional divergence. First, the study demonstrated striking functional differences between the Csk and Chk SH2 domains and revealed functional similarities between the Chk and Src SH2 domains. Second, structural analysis and mutagenic studies revealed that the functional differences among the three SH2 domains were largely controlled by one residue, Glu127 in Csk, Ile167 in Chk, and Lys200 in Src. Mutating these residues in the Csk or Chk SH2 domain to the Src counterpart resulted in dramatic gain of function similar to Src SH2 domain, whereas mutating Lys200 in Src SH2 domain to Glu (the Csk counterpart) resulted in loss of Src SH2 function. Third, a single point mutation of E127K rendered Csk responsive to activation by a Src SH2 domain ligand. Finally, the optimal phosphopeptide sequence for the Chk SH2 domain was determined. These results provide a compelling explanation for the functional differences between two homologous protein tyrosine kinases and reveal a new structure-function relationship for the SH2 domains.

Determination of the substrate-docking site of protein tyrosine kinase C-terminal Src kinase

Protein tyrosine kinases (PTK) are key enzymes of mammalian signal transduction. For the fidelity of signal transduction, each PTK phosphorylates only one or a few proteins on specific Tyr residues. Substrate specificity is thought to be mediated by PTK-substrate docking interactions and recognition of the phosphorylation site sequence by the kinase active site. However, a substrate-docking site has not been determined on any PTK. C-terminal Src kinase (Csk) is a PTK that specifically phosphorylates Src family kinases on a C-terminal Tyr. In this study, by sequence alignment and site-specific mutagenesis, we located a substrate-docking site on Csk. Mutations in the docking site disabled Csk to phosphorylate, regulate, and complex with Src but only moderately affected its general kinase activity. A peptide mimicking the docking site potently inhibited (IC50 = 21 microM) Csk phosphorylation of Src but only moderately inhibited (IC50 = 422 microM) its general kinase activity. Determination of the substrate-docking site provides the structural basis of substrate specificity in Csk and a model for understanding substrate specificity in other PTKs.

Expression, purification, and biochemical characterization of Chk, a soluble protein tyrosine kinase

CSK family contains two protein tyrosine kinases: Csk (C-terminal Src kinase) and Chk (Csk homologous kinase). They are responsible for phosphorylating Src family protein tyrosine kinases on a C-terminal Tyr (Tyr527) and negatively regulating their activities. However, Chk and Csk have different expression patterns, mechanisms of regulation, and different biological functions, and appear to play different roles in the development of breast cancer. To obtain pure human Chk for biochemical characterization, its coding region was amplified by polymerase chain reaction and expressed as a fusion protein with glutathione S-transferase in Escherichia coli. The enzyme was highly expressed but unusually prone to proteolytic degradation during purification. Expression of the enzyme as a dual fusion protein with glutathione S-transferase on N-terminus and streptag, a 10 amino acid peptide, on C-terminus allowed purification of the full-length fusion protein. The purified enzyme was able to phosphorylate and inactivate Src. Chk (no inhibition up to 18.5 microM) and Csk (IC(50)= 1 microM) were differentially inhibited by PP2, probably due to the size difference of one residue (Thr265 in Csk versus Met304 in Chk) in the ATP-binding domain. The expression, purification, and initial characterizations of Chk provided an important step toward full characterization of Chk and Csk, two important enzymes in cellular regulation.

Use of epitope mapping to identify a PCR template for protein amplification and detection by enzyme-linked immunosorbent assay of bovine herpesvirus type 1 glycoprotein D

Infection with bovine herpesvirus type 1 (BHV-1) occurs worldwide and causes serious economic losses due to the deaths of animals, abortions, decreased milk production, and loss of body weight. BHV-1 is frequently found in bovine semen and is transmitted through natural service and artificial insemination. The detection of BHV-1 in bovine semen is a long-standing problem in veterinary virology which is important in disease control schemes. In the present study, ordered deletions of the full-length BHV-1 glycoprotein open reading frame were used to identify an epitope recognized by a specific monoclonal antibody (MAb). A glycoprotein D fragment containing this epitope was then amplified using an in vitro protein amplification assay developed previously (J. Zhou, J. Lyaku, R. A. Fredrickson, and F. S. Kibenge, J. Virol. Methods 79:181-189, 1999), and the resulting peptide was detected by indirect enzyme-linked immunosorbent assay (ELISA) with the specific MAb. This method detected 0.0395 50% tissue culture infective dose of BHV-1 in raw bovine semen, which was 1,000-fold more sensitive than traditional PCR. We therefore conclude that this in vitro protein amplification assay combined with ELISA has superior sensitivity for direct virus detection in clinical samples.

QM, a putative tumor suppressor, regulates proto-oncogene c-yes

The QM gene encodes a 24.5 kDa ribosomal protein L10 known to be highly homologous to a Jun-binding protein (Jif-1), which inhibits the formation of Jun-Jun dimers. Here we have carried out screening with the c-Yes protein and found that a QM homologous protein showed interactions with c-Yes and other Src family members. We have found that two different regions of QM protein were associated with the SH3 domain of c-Yes. The QM protein does not contain canonical SH3 binding motifs or previously reported amino acid fragments showing interaction with SH3 domains. Several c-Yes kinase activity assays indicated that the QM protein reduced c-Yes kinase activity by 70% and that this suppression is related not only to the two SH3 binding regions but also to the C-terminal region of QM. Moreover, our autophosphorylation assays clarified that this regulation resulted from the inhibition of c-Yes autophosphorylation. Immunofluorescence studies showed that the QM proteins and c-Yes are able to interact in various tumor cell lines in vivo. The increases of the c-Yes protein and mRNA levels were detected when the QM was transfected. These results suggest that the QM protein might be a regulator for various signal transduction pathways involving SH3 domain-containing membrane proteins.

Purification of dual-tagged intact recombinant proteins

Large-scale purification of recombinant proteins has been used extensively to assist numerous protein studies, including investigation of function, substrate identification and protein-protein interaction of low abundance proteins. Genetic fusion of affinity tags to these proteins has also been widely used for ease of purification by affinity chromatography. However, this technique sometimes yields unstable and degraded protein products limiting its application. In this study, we show a facile and straightforward method of dual-tagged recombinant protein purification that eliminates contamination by degraded protein products. A 6His-containing BamHI-HindIII fragment from pQE12 was ligated into the pGEX-KG BamHI-HindIII fragment and the protein of interest (p25(nck5a), which is highly susceptible to proteolytic degradation when expressed and purified from bacteria) was cloned into the BamHI site without a termination codon. The resulting plasmid construct, designated as pGST-p25(nck5a)-6His, with GST at the N-terminal and 6His at the C-terminal was expressed in Escherichia coli DH5alpha and purified using a two-step procedure. We show that using Ni(2+)-NTA chromatography as a first purification step and GSH-agarose chromatography as a second step, rather than vice-versa, yields a highly purified intact protein that is free of any contaminating degraded protein product. The purified fusion protein is soluble and fully active.

Characterization of monoclonal antibodies against bovine herpesvirus 1 gD fusion protein expressed in E. coli

A total of 20 hybridoma cell lines secreting monoclonal antibodies (MAbs) against E. coli expressed bovine herpesvirus-1 (BHV-1) gD fusion protein were produced following the fusion of Sp2/0 myeloma cells with splenocytes from BALB/c mice immunized previously with immunoaffinity purified BHV-1 gD fusion protein. An indirect fluorescent antibody test (IFAT) using BHV-1 infected MDBK cells was used for the selection of positive hybridomas secreting specific antibody. The monoclonal antibody isotypes were 11 IgM, six IgG2b, one IgG1 and two IgG3. All MAbs reacted positively with the E. coli expressed BHV-1 gD fusion protein, BHV-1 infected MDBK cell lysates and PCR BHV-1 gD transcription-translation polypeptide antigens by an ELISA.

Mutations in the N-terminal regulatory region reduce the catalytic activity of Csk, but do not affect its recognition of Src

In addition to the C-terminal catalytic domain, Csk is a protein tyrosine kinase that has an N-terminal regulatory region that contains SH3 and SH2 domains. The role this region plays relative to the function of the catalytic domain is not clear. To study its role, we introduced either deletion or site-specific mutations within this region and analyzed the effect of such mutations on the catalytic activity of Csk and its ability to phosphorylate/inactivate Src protein tyrosine kinase, its physiological substrate in the cell. Deletion of the SH3 domain and the SH2 domain resulted in reductions of kinase activity by 70 and 96%, respectively. Mutations within the SH2 domain that abolished its ability to bind phosphotyrosine did not result in a significant loss of kinase activity. Mutation of Ser78 to Asp, located between the SH3 and the SH2 domains, resulted in a reduction of over 90% of the catalytic activity. The reduction in specific activity is not the result of any apparent physical instability of the mutants. Kinetic analyses indicate that the mutations did not affect the Km values for ATP-Mg or the polypeptide substrate. The ability of the mutants to phosphorylate and inactivate Src is directly correlated to their kinase activity. These results indicate that the regulatory region is important in optimizing the kinase activity of the catalytic domain, but apparently plays no direct or specific role in substrate recognition.

Separation used for purification of recombinant proteins

The purification of molecules from recombinant cells may be strongly influenced by the molecular biology of gene isolation and expression. At the beginning of the process there may be a demand for information on the minute amounts of proteins and thus for ever increasingly sensitive techniques. Purification of recombinant proteins can differ from conventional purifications in several ways, depending on the solubility of the protein, occurrence in inclusion bodies, creation of fusion proteins with tags that enable simpler purification. Sometimes a (re)naturation step is required to get a bioactive protein. On the other hand, the techniques used in separation are essentially the same as for purification from the natural source and environment.

Expression, purification, and initial characterization of human Yes protein tyrosine kinase from a bacterial expression system

Protein tyrosine kinase Yes is a cellular homolog of v-Yes, the oncogenic protein product of avian sarcoma virus Y73. Yes is a member of the Src family and its activation has been associated with several types of human cancer. Human Yes has not been previously characterized enzymatically. To carry out biochemical characterizations of this enzyme, we expressed it as a fusion protein with glutathione S-transferase in Escherichia coli, to allow purification in a single step. The affinity-purified GST-Yes has a specific activity of 1.3 nmol min-1 mg-1 with polyE4Y as substrate and Km values of 100 microg ml-1 for polyE4Y and 70 microM for ATP-Mg. The enzyme has a preference for magnesium over manganese ion for maximal activity. The divalent metal cation serves two essential functions for the activity of Yes: one as a part of the phosphate-donating substrate ATP-Mg and the other as an essential activator. The enzyme undergoes autophosphorylation without apparent activation. Finally, we show that the enzyme is inactivated by incubation with protein tyrosine kinase Csk in an ATP-Mg-dependent manner, indicating that cellular Yes can be regulated by Csk phosphorylation. These represent the first biochemical characterization of human Yes protein tyrosine kinase.

Csk phosphorylation and inactivation in vitro by the cAMP-dependent protein kinase

Csk is a protein tyrosine kinase that phosphorylates other protein tyrosine kinases of the Src family and down-regulates their activities. It is not known how Csk is regulated. We investigated the possibility that Csk is regulated through phosphorylation by examining if Csk can serve as an in vitro substrate for a panel of protein kinases. We found that Csk was phosphorylated by the cAMP-dependent protein kinase (PKA), but not by protein kinase C, Src, or the fibroblast growth factor receptor kinase. Csk phosphorylation in vitro by PKA is on a serine residue(s) and can reach a stoichiometry of approximately 0.6 mol phosphate per mole of enzyme. Furthermore, incubation with PKA in the presence of ATP and magnesium ion results in a time-dependent decrease in Csk kinase activity. A six-fold decrease in Csk activity (expressed as Vmax/Km ratio) was achieved due to a threefold increase in its Km and a twofold decrease in its Vmax value within 1 h of incubation with the catalytic subunit of PKA and ATP-Mg. Both phosphorylation and inactivation by PKA were blocked by a PKA-specific inhibitor. Csk mutants with a deleted SH2 or SH3 domain retained their ability to be phosphorylated and inactivated by PKA, indicating that the phosphorylation site is located within the catalytic domain. These studies suggest that the cAMP-dependent protein kinase can regulate Csk activity.