A modified KESTREL search reveals a basophilic substrate consensus for the Saccharomyces cerevisiae Npr1 protein kinase.

The Saccharomyces cerevisiae nitrogen permease reactivator Npr1 is a hyperphosphorylated protein that belongs to a family of Ser/Thr protein kinases dedicated to the regulation of plasma membrane transporters. Its activity is regulated by the Tor (target of rapamycin) signaling pathway. Inhibition of the Tor proteins by treating yeast cells with the immunosuppressant drug rapamycin promotes rapid dephosphorylation of Npr1. As an alternative to peptide arrays, the substrate requirement of Npr1 was probed with a peptide library that was generated by cleaving yeast cell extracts with CNBr, and after reverse-phase chromatography, the individual fractions were phosphorylated in vitro with recombinant Npr1. In this way, the ribosomal protein Rpl24a was found to be an excellent in vitro substrate for Npr1. Synthetic peptides tailored around the phosphorylation site of Rpl24a show that Npr1 is a Ser/Thr protein kinase with an absolute requirement for a basic residue at the P-3 position and a strong preference for basic P + 1 residues, whereas proline at P + 1 is strongly disfavored. The results obtained with synthetic peptides suggest a (K/R)-X-X-S-(K/R) consensus sequence for Npr1. The availability of a consensus sequence allows a targeted search for physiologically relevant Npr1 substrates involved in the regulation of yeast amino acid permeases.

The regulatory beta subunit of protein kinase CK2 contributes to the recognition of the substrate consensus sequence. A study with an eIF2 beta-derived peptide.

CK2 is a ubiquitous and pleiotropic Ser/Thr-specific protein kinase that phosphorylates more than 300 protein substrates at sites specified by an acidic consensus sequence in which positions n + 3 and n + 1 are particularly important. Recognition of substrates by CK2 is known to rely on basic residues located in the catalytic site of the alpha subunit which make electrostatic contacts with the negative charges in the substrate consensus sequence, thereby assuring optimal binding; the regulatory beta subunit is believed to play a protective and stabilizing role. We describe a biochemical and structural analysis of CK2-mediated phosphorylation of a 22-mer synthetic peptide corresponding to the N-terminal tail of the eukaryotic translation initiation factor eIF2beta. Results demonstrate that this peptide still displays phosphorylation features similar to full-length eIF2beta and the CK2 beta subunit also contributes to recognition of the protein substrate by establishing both polar and hydrophobic interactions with specificity determinants located downstream from the phosphoacceptor site. In particular, the N-terminal domain of the beta subunit appears to be of crucial importance for optimizing high-affinity phosphorylation of the eIF2beta peptide. This domain includes an acidic cluster whose electrostatic contacts with basic residues of the substrate attenuate intrasteric pseudosubstrate inhibition while strengthening substrate-kinase binding.

Coumarin as attractive casein kinase 2 (CK2) inhibitor scaffold: an integrate approach to elucidate the putative binding motif and explain structure-activity relationships.

Casein kinase 2 (CK2) is an ubiquitous, essential, and highly pleiotropic protein kinase whose abnormally high constitutive activity is suspected to underlie its pathogenic potential in neoplasia and other diseases. Recently, using different virtual screening approaches, we have identified several novel CK2 inhibitors. In particular, we have discovered that coumarin moiety can be considered an attractive CK2 inhibitor scaffold. In the present work, we have synthetized and tested a small library of coumarins (more than 60), rationalizing the observed structure-activity relationship. Moreover, the most promising inhibitor, 3,8-dibromo-7-hydroxy-4-methylchromen-2-one (DBC), has been also crystallized in complex with CK2, and the experimental binding mode has been used to derive a linear interaction energy (LIE) model.

Tetrabromocinnamic acid (TBCA) and related compounds represent a new class of specific protein kinase CK2 inhibitors.

Abnormally high constitutive activity of protein kinase CK2, levels of which are elevated in a variety of tumours, is suspected to underlie its pathogenic potential. The most widely employed CK2 inhibitor is 4,5,6,7-tetrabromobenzotriazole (TBB), which exhibits a comparable efficacy toward another kinase, DYRK1 a. Here we describe the development of a new class of CK2 inhibitors, conceptually derived from TBB, which have lost their potency toward DYRK1 a. In particular, tetrabromocinnamic acid (TBCA) inhibits CK2 five times more efficiently than TBB (IC50 values 0.11 and 0.56 microM, respectively), without having any comparable effect on DYRK1 a (IC50 24.5 microM) or on a panel of 28 protein kinases. The usefulness of TBCA for cellular studies has been validated by showing that it reduces the viability of Jurkat cells more efficiently than TBB through enhancement of apoptosis. Collectively taken, the reported data support the view that suitably derivatized tetrabromobenzene molecules may provide powerful reagents for dissecting the cellular functions of CK2 and counteracting its pathogenic potentials.

Identification of ellagic acid as potent inhibitor of protein kinase CK2: a successful example of a virtual screening application.

Casein kinase 2 (CK2) is a ubiquitous, essential, and highly pleiotropic protein kinase whose abnormally high constitutive activity is suspected to underlie its pathogenic potential in neoplasia and other diseases. Using a virtual screening approach, we have identified the ellagic acid, a naturally occurring tannic acid derivative, as a novel potent CK2 inhibitor. At present, ellagic acid represents the most potent known CK2 inhibitor (K(i) = 20 nM).

Autophosphorylation at the regulatory beta subunit reflects the supramolecular organization of protein kinase CK2.

Among the features of protein kinase CK2, autophosphorylation at its beta-subunit(s) upon incubation with ATP/Mg++ was early detected as a rapid and stoichiometric event occurring through an intramolecular mechanism as judged from kinetic analyses. The autophosphorylation site was mapped to Ser2 and, to a lesser extent, Ser3 both fulfilling the CK2 consensus sequence (MSSSEEV). The crystal structure of the heterotetrameric holoenzyme, however, is not compatible with an intramolecular autophosphorylation of the N-terminal stretch of either of the two beta subunits. Here we show that efficient "intramolecular" autophosphorylation of the beta subunit is crucially dependent on the formation of oligomers composed by several holoenzyme heterotetrameric protomers. Increasing ionic strength of the incubation medium promoting dissociation of the supramolecular oligomers abrogates beta subunit autophosphorylation, although CK2 catalytic activity, as judged from the phosphorylation of exogenous substrates, is still quite evident. These findings, in conjunction with graphic modelization, support the view that CK2 autophosphorylation at its beta subunits takes place through an "intraoligomeric" mechanism where the beta subunits of a protomer are phosphorylated by the catalytic subunits of another adjacent protomer. It appears therefore that in vivo beta autophosphorylation is symptomatic of supramolecular CK2 oligomers.