Development of the procedures for high-yield expression and rapid purification of active recombinant Csk-homologous kinase (CHK): comparison of the catalytic activities of CHK and CSK.

Csk-homologous kinase (CHK) is an important endogenous inhibitor constraining the oncogenic actions of Src-family kinases (SFKs) in cells. It suppresses SFK activity by specifically phosphorylating the conserved regulatory tyrosine near the C-terminus of SFKs. In addition to phosphorylation, CHK employs a novel non-catalytic inhibitory mechanism to suppress SFK activity. This mechanism involves direct binding of CHK to the active forms of SFKs to form stable protein complexes. Since aberrant activation of SFKs contributes to cancer formation and progression, small-molecule inhibitors mimicking the non-catalytic inhibitory mechanism of CHK are potential anti-cancer therapeutics. Elucidation of the catalytic and regulatory properties and the structural basis of the CHK non-catalytic inhibitory mechanism would facilitate the development of these small-molecule inhibitors. To this end, we developed procedures for higher level expression in insect cells of active recombinant CHK with a hexa-histidine tag attached to its C-terminus (referred to as CHK-His(6)) and its rapid purification by a two-step method. Analyses by size-exclusion column chromatography and analytical ultracentrifugation revealed that the purified CHK-His(6) exists as a monomeric species in solution. Biochemical analyses demonstrated that CHK-His(6) exhibits efficiencies comparable to those of CSK in phosphorylating artificial protein and peptide substrates as well as an intact SFK protein. Our results indicate that the recombinant CHK-His(6) can be used for future studies to decipher the three-dimensional structure, and regulatory and catalytic properties of CHK.

Structural elements and allosteric mechanisms governing regulation and catalysis of CSK-family kinases and their inhibition of Src-family kinases.

C-terminal Src kinase (CSK) and CSK-homologous kinase (CHK) are endogenous inhibitors constraining the activity of the oncogenic Src-family kinases (SFKs) in cells. Both kinases suppress SFKs by selectively phosphorylating their consensus C-terminal regulatory tyrosine. In addition to phosphorylation, CHK can suppress SFKs by a unique non-catalytic inhibitory mechanism that involves tight binding of CHK to SFKs to form stable complexes. In this review, we discuss how allosteric regulators, phosphorylation, and inter-domain interactions interplay to govern the activity of CSK and CHK and their ability to inhibit SFKs. In particular, based upon the published results of structural and biochemical analysis of CSK and CHK, we attempt to chart the allosteric networks in CSK and CHK that govern their catalysis and ability to inhibit SFKs. We also discuss how the published three-dimensional structure of CSK complexed with an SFK member sheds light on the structural basis of substrate recognition by protein kinases.

Allosteric networks governing regulation and catalysis of Src-family protein tyrosine kinases: implications for disease-associated kinases.

1. The Src-family protein tyrosine kinases (SFKs) are multidomain oncogenic protein tyrosine kinases. Their overactivation contributes to cancer formation and progression. Thus, synthetic inhibitors of SFKs are being developed as therapeutics for cancer treatment. Understanding the regulatory and catalytic mechanisms of SFKs is necessary for the development of therapeutic SFK inhibitors. 2. Although many upstream regulators and protein substrates of SFKs have been identified, both the mechanisms of activation and catalysis of SFKs are not fully understood. In particular, it is still unclear how the inactive SFKs undergo conformational transition during activation. The mechanism governing the binding of substrates and the release of products during catalysis is another area that requires investigation. 3. Several recent publications indicate the presence of a 'hydrophobic spine' formed by four conserved interacting hydrophobic residues in the kinase domain of SFKs. In the present review, we discuss how the assembly and disassembly of the hydrophobic spine residues may govern conformational transition of SFKs during activation. In addition to regulation of kinase activity, the hydrophobic spine is implicated to be involved in catalysis. It has been postulated recently that perturbation of the hydrophobic spine residues is a key step in catalysis. 4. Further investigations to decipher the roles of the hydrophobic spine residues in regulation and catalysis of SFKs will benefit the development of therapeutic SFK inhibitors for cancer treatment.

C-terminal Src kinase-homologous kinase (CHK), a unique inhibitor inactivating multiple active conformations of Src family tyrosine kinases.

The Src family of protein kinases (SFKs) mediates mitogenic signal transduction, and constitutive SFK activation is associated with tumorigenesis. To prevent constitutive SFK activation, the catalytic activity of SFKs in normal mammalian cells is suppressed mainly by two inhibitors called C-terminal Src kinase (CSK) and CSK-homologous kinase (CHK), which inactivate SFKs by phosphorylating a consensus tyrosine near the C terminus of SFKs (Y(T)). The phosphorylated Y(T) intramolecularly binds to the SH2 domain of SFKs. This interaction, known as pY(T)/SH2 interaction, together with binding between the SH2 kinase linker and the SH3 domain of SFKs (linker/SH3 interaction) stabilizes SFKs in a "closed" inactive conformation. We previously discovered an alternative mechanism CHK employs to inhibit SFKs. This mechanism, referred to as the non-catalytic inhibitory mechanism, involves tight binding of CHK to SFKs; the binding alone is sufficient to inhibit SFKs. Herein, we constructed multiple active conformations of an SFK member, Hck, by systematically disrupting the two inhibitory interactions. We found that CHK employs the non-catalytic mechanism to inactivate these active conformations of Hck. However, CHK does not bind Hck when it adopts the inactive conformation in which both inhibitory interactions are intact. These data indicate that binding of CHK to SFKs via the non-catalytic mechanism is governed by the conformations of SFKs. Although CSK is also an inhibitor of SFKs, it does not inhibit SFKs by a similar non-catalytic mechanism. Thus, the non-catalytic inhibitory mechanism is a unique property of CHK that allows it to down-regulate multiple active conformations of SFKs.