The multiple personalities of the regulatory subunit of protein kinase CK2: CK2 dependent and CK2 independent roles reveal a secret identity for CK2beta

Protein kinase CK2 (formerly casein kinase II), an enzyme that participates in a wide variety of cellular processes, has traditionally been classified as a stable tetrameric complex consisting of two catalytic CK2alpha or CK2alpha' subunits and two regulatory CK2beta subunits. While consideration of CK2 as a tetrameric complex remains relevant, significant evidence has emerged to challenge the view that its individual subunits exist exclusively within these complexes. This review will summarize biochemical and genetic evidence indicating that the regulatory CK2beta subunit exists and performs functions independently of CK2 tetramers. For example, unbalanced expression of catalytic and regulatory CK2 subunits has been observed in a variety of tissues and tumors. Furthermore, localization studies including live cell imaging have demonstrated that while the catalytic and regulatory subunits of CK2 exhibit extensive co-localization, independent mobility of the individual CK2 subunits can also be observed within cells. Identification of proteins that interact with CK2beta in the absence of catalytic CK2 subunits reinforces the notion that CK2beta has functions distinct from CK2 and begins to offer insights into these CK2-independent functions. In this respect, the discovery that CK2beta can interact with and modulate the activity of a number of other serine/threonine protein kinases including A-Raf, c-Mos and Chk1 is particularly striking. This review will discuss the interactions between CK2beta and these protein kinases with special emphasis on the properties of CK2beta that mediate these interactions and on the implications of these interactions in yielding new prospects for elucidation of the cellular functions of CK2beta.     

Protein kinase CK2 phosphorylates and activates the SR protein-specific kinase 1

The serine/arginine subfamily of protein kinases has been conserved throughout evolution and its members are thought to play important roles in the regulation of multiple cellular processes. Mammalian SRPK1 has been considered as a constitutively active kinase that is predominantly expressed in testis. In the present study, recombinant GST-SRPK1 was used as substrate to identify potential protein kinase(s) in testis extracts, involved in phosphorylating and thereby regulating the activity of this enzyme. Using a panel of chromatography media, inhibition by heparin, immunoblot analysis, and phosphopeptide mapping, CK2 was determined to be the major kinase that phosphorylates SRPK1. Phosphorylation of SRPK1 by CK2 occurred mainly at Ser(51) and Ser(555) in vitro, and resulted in approximately 6-fold activation of the enzyme. These findings suggest that SRPK1 may be an important cellular target for CK2 action.     

Interactions of protein kinase CK2 subunits

Several approaches have been used to study the interactions of the subunits of protein kinase CK2. The inactive mutant of CK2 that has Asp 156 mutated to Ala (CK2A156) is able to bind the CK2 subunit and to compete effectively in this binding with wild-type subunits and . The interaction between CK2A156 and CK2 was also demonstrated by transfection of epitope-tagged cDNA constructs into COS-7 cells. Immunoprecipitation of epitope-tagged CK2A156 coprecipitated the subunit and vice-versa. The assay of the CK2 activity of the extracts obtained from cells transiently transfected with these different subunits yielded some surprising results: The CK2 specific phosphorylating activity of these cells transfected with the inactive CK2A156 was considerably higher than the control cells transfected with vectors alone. Assays of the immunoprecipitated CK2A156 expressed in these cells, however, demonstrated that the mutant was indeed inactive. It can be concluded that transfection of the inactive CK2A156 affects the endogenous activity of CK2. Transfection experiments with CK2 and subunits and CK2A156 were also used to confirm the interaction of CK2 with the general CDK inhibitor p21WAF1/CIP1 co-transfected into these cells. Finally a search in the SwissProt databank for proteins with properties similar to those derived from the amino acid composition of CK2 indicated that CK2 is related to protein phosphatase 2A and to other phosphatases as well as to a subunit of some ion-transport ATPases.     

Protein kinase CK2 interacts with a multi-protein binding domain of p53

p53 is one of the most powerful negative regulators of growth. To manage this in an efficient way it has to interact with a set of different cellular proteins. Most contacts with the cellular environment occur in the N- or the C-terminal domain of the protein. Since we previously found that p53 binds to the regulatory -subunit of CK2 we now analyzed N- and C-terminal domains of p53 separately for the binding of protein kinase CK2, an enzyme which seems to have a certain importance for proliferation processes. With different overlay assays we could map the binding domain of protein kinase CK2 to a sequence between amino acids 325-344, a region which coincides with the interaction domain of some other p53 binding proteins. We also found that the regulatory -subunit of protein kinase CK2 binds independent of the catalytic -subunit to this C-terminal domain of p53.     

The interaction of CK2alpha and CK2beta, the subunits of protein kinase CK2, requires CK2beta in a preformed conformation and is enthalpically driven

The protein kinase CK2 (former name: "casein kinase 2") predominantly occurs as a heterotetrameric holoenzyme composed of two catalytic chains (CK2alpha) and two noncatalytic subunits (CK2beta). The CK2beta subunits form a stable dimer to which the CK2alpha monomers are attached independently. In contrast to the cyclins in the case of the cyclin-dependent kinases CK2beta is no on-switch of CK2alpha; rather the formation of the CK2 holoenzyme is accompanied with an overall change of the enzyme's profile including a modulation of the substrate specificity, an increase of the thermostability, and an allocation of docking sites for membranes and other proteins. In this study we used C-terminal deletion variants of human CK2alpha and CK2beta that were enzymologically fully competent and in particular able to form a heterotetrameric holoenzyme. With differential scanning calorimetry (DSC) we confirmed the strong thermostabilization effect of CK2alpha on CK2beta with an upshift of the CK2alpha melting temperature of more than 9 degrees . Using isothermal titration calorimetry (ITC) we measured a dissociation constant of 12.6 nM. This high affinity between CK2alpha and CK2beta is mainly caused by enthalpic rather than entropic contributions. Finally, we determined a crystal structure of the CK2beta construct to 2.8 A resolution and revealed by structural comparisons with the CK2 holoenzyme structure that the CK2beta conformation is largely conserved upon association with CK2alpha, whereas the latter undergoes significant structural adaptations of its backbone.     

Development and exploitation of CK2 inhibitors

A number of quite specific and fairly potent inhibitors of protein kinase CK2, belonging to the classes of condensed polyphenolic compounds, tetrabromobenzimidazole/triazole derivatives and indoloquinazolines are available to date. The structural basis for their selectivity is provided by a hydrophobic pocket adjacent to the ATP/GTP binding site, which in CK2 is smaller than in the majority of other protein kinases due to the presence of a number of residues whose bulky side chains are generally replaced by smaller ones. Consequently a doubly substituted CK2 mutant V66A,I174A is much less sensitive than CK2 wild type to these classes of inhibitors. The most efficient inhibitors both in terms of potency and selectivity are 4,5,6,7-tetrabromo-1H-benzotriazole, TBB (K_i = 0.4 μM), the TBB derivative 2-dimethylamino-4,5,6,7-tetrabromo-1H-benzimidazole, DMAT (K_i = 0.040 μM), the emodin related coumarinic compound 8-hydroxy-4-methyl-9-nitrobenzo[g]chromen-2-one, NBC (K_i = 0.22 μM) and the indoloquinazoline derivative ([5-oxo-5,6-dihydroindolo-(1,2a)quinazolin-7-yl]acetic acid), IQA (K_i = 0.17 μM). These inhibitors are cell permeable as judged from ability to block CK2 in living cells and they have been successfully employed, either alone or in combination with CK2 mutants refractory to inhibition, to dissect signaling pathways affected by CK2 and to identify the endogenous substrates of this pleitropic kinase. By blocking CK2 these inhibitors display a remarkable pro-apoptotic efficacy on a number of tumor derived cell lines, a property which can be exploited in perspective to develop antineoplastic drugs.     

Activation of human topoisomerase I by protein kinase CK2

The enzymatic studies were performed to reveal a mode of activation of human topoisomerase I by a direct interaction with protein kinase CK2. In the absence of ATP CK2 kinase activated DNA relaxation about twofold. CK2 subunit was identified as solely responsible for the stimulation of relaxing activity by CK2 kinase. CK2 activated the relaxation only at the excess of the substrate over topoisomerase I. At the equimolar ratio of the substrate DNA and topoisomerase I the activation was not observed. There was also no effect of CK2 on camptothecin-induced cleavage of DNA by htopo I. These results identify an accelerated movement of topoisomerase I between substrate molecules as a cause of the activation of DNA relaxation by CK2 kinase.     

Crystal structure of a C-terminal deletion mutant of human protein kinase CK2 catalytic subunit

Protein kinase CK2 (formerly called: casein kinase 2) is a heterotetrameric enzyme composed of two separate catalytic chains (CK2alpha) and a stable dimer of two non-catalytic subunits (CK2beta). CK2alpha is a highly conserved member of the superfamily of eukaryotic protein kinases. The crystal structure of a C-terminal deletion mutant of human CK2alpha was solved and refined to 2.5A resolution. In the crystal the CK2alpha mutant exists as a monomer in agreement with the organization of the subunits in the CK2 holoenzyme. The refined structure shows the helix alphaC and the activation segment, two main regions of conformational plasticity and regulatory importance in eukaryotic protein kinases, in active conformations stabilized by extensive contacts to the N-terminal segment. This arrangement is in accordance with the constitutive activity of the enzyme. By structural superimposition of human CK2alpha in isolated form and embedded in the human CK2 holoenzyme the loop connecting the strands beta4 and beta5 and the ATP-binding loop were identified as elements of structural variability. This structural comparison suggests that the ATP-binding loop may be the key region by which the non-catalytic CK2beta dimer modulates the activity of CK2alpha. The beta4/beta5 loop was found in a closed conformation in contrast to the open conformation observed for the CK2alpha subunits of the CK2 holoenzyme. CK2alpha monomers with this closed beta4/beta5 loop conformation are unable to bind CK2beta dimers in the common way for sterical reasons, suggesting a mechanism to protect CK2alpha from integration into CK2 holoenzyme complexes. This observation is consistent with the growing evidence that CK2alpha monomers and CK2beta dimers can exist in vivo independently from the CK2 holoenzyme and may possess physiological roles of their own.     

Identification of proteins that associate with protein kinase CK2

In order to aid in an understanding of the cellular functions of protein kinase CK2, a search for interacting proteins was carried out using a 32P-labeled CK2 overlay method. Several proteins were found to associate with CK2 by this assay; among them, one protein of 110 kDa appeared to be the most prominent one. The possible association of CK2 with p110 was suggested by experiments involving the co-immunoprecipitation using anti-CK2 antibodies. Further analysis using GST-CK2 fusion proteins demonstrated that the CK2-p110 interaction occurred through the CK2/ subunits. To identify p110, it was purified using a GST-CK2 affinity column, and internal amino acid sequencing was then performed. p110 was found to be nucleolin, a nucleolar protein that may be important for rRNA synthesis; a possible role of CK2 in the control of this process is suggested. Using the same CK2 overlay technique, another interacting protein, insulin receptor substrate 1 (IRS-1), was also identified. By applying a modified overlay method using individual 35S-labeled CK2 subunits, obtained by in vitro translation in rabbit reticulate lysates, it was determined that CK2 associates with IRS-1 through its / subunits; i.e. in keeping with the fact that IRS-1 is a known substrate for CK2. However, further work is needed to examine the association of CK2 with IRS-1 in vivo in order to fully understand the significance of the interaction.     

Expression and regulation of protein kinase CK2 during the cell cycle

There are indications from genetic, biochemical and cell biological studies that protein kinase CK2 (formerly casein kinase II) has a variety of functions at different stages in the cell cycle. To further characterize CK2 and its potential roles during cell cycle progression, one of the objectives of this study was to systematically examine the expression of all three subunits of CK2 at different stages in the cell cycle. To achieve this objective, we examined levels of CK2, CK2 and CK2 on immunoblots as well as CK2 activity in samples prepared from: (i) elutriated populations of MANCA (Burkitt lymphoma) cells, (ii) serum-stimulated GL30-92/R (primary human fibroblasts) cells and (iii) drug-arrested chicken bursal lymphoma BK3A cells. On immunoblots, we observed a significant and co-ordinate increase in the expression of CK2 and CK2 following serum stimulation of quiescent human fibroblasts. By comparison, no major fluctuations in CK2 activity were detected during any other stages during the cell cycle. Furthermore, we did not observe any dramatic differences between the relative levels of CK2 to CK2 during different stages in the cell cycle. However, we observed a significant increase in the amount of CK2 relative to CK2 in cells arrested with nocodazole. We also examined the activity of CK2 in extracts or in immunoprecipitates prepared from drug-arrested cells. Of particular interest is the observation that the activity of CK2 is not changed in nocodazole-arrested cells. Since CK2 is maximally phosphorylated in these cells, this result suggests that the phosphorylation of CK2 by p34cdc2 does not affect the catalytic activity of CK2. However, the activity of CK2 was increased by incubation with p34cdc2 in vitro. Since this activation was independent of ATP we speculate that p34cdc2 may have an associated factor that stimulates CK2 activity. Collectively, the observations that relative levels of CK2 increase in mitotic cells, that CK2 and CK2 are phosphorylated in mitotic cells and that p34cdc2 affects CK2 activity in vitro suggest that CK2 does have regulatory functions associated with cell division.     

Inclining the purine base binding plane in protein kinase CK2 by exchanging the flanking side-chains generates a preference for ATP as a cosubstrate

Protein kinase CK2 (casein kinase 2) is a highly conserved and ubiquitously found eukaryotic serine/threonine kinase that plays a role in various cellular key processes like proliferation, apoptosis and circadian rhythm. One of its prominent biochemical properties is its ability to use GTP as well as ATP as a cosubstrate (dual-cosubstrate specificity). This feature is exceptional among eukaryotic protein kinases, and its biological significance is unknown. We describe here a mutant of the catalytic subunit of protein kinase CK2 (CK2alpha) from Homo sapiens (hsCK2alpha) with a clear and CK2-atypical preference for ATP compared to GTP. This mutant was designed on the basis of several structures of CK2alpha from Zea mays (zmCK2alpha) in complex with various ATP-competitive ligands. A structural overlay revealed the existence of a "purine base binding plane" harbouring the planar moiety of the respective ligand like the purine base of ATP and GTP. This purine base binding plane is sandwiched between the side-chains of Ile66 (Val66 in hsCK2alpha) and Met163, and it adopts a significantly different orientation than in prominent homologues like cAMP-dependent protein kinase (CAPK). By exchanging these two flanking amino acids (Val66Ala, Met163Leu) in hsCK2alpha(1-335), a C-terminally truncated variant of hsCK2alpha, the cosubstrate specificity shifted in the expected direction so that the mutant strongly favours ATP. A structure determination of the mutant in complex with an ATP-analogue confirmed the predicted change of the purine base binding plane orientation. An unexpected but in retrospect plausible consequence of the mutagenesis was, that the helix alpha D region, which is in the direct neighbourhood of the ATP-binding site, has adopted a conformation that is more similar to CAPK and less favourable for binding of GTP. These findings demonstrate that CK2alpha possesses sophisticated structural adaptations in favour of dual-cosubstrate specificity, suggesting that this property could be of biological significance.     

Purification and characterization of the CK2alpha'-based holoenzyme, an isozyme of CK2alpha: a comparative analysis

Protein kinase CK2 (former name: "casein kinase 2") is a pivotal and ubiquitously expressed member of the eukaryotic protein kinase superfamily. It predominantly exists as a heterotetrameric holoenzyme composed of two catalytic subunits (CK2alpha) and two regulatory subunits (CK2beta). In higher animals two paralog catalytic chains-abbreviated CK2alpha and CK2alpha'--exist which can combine with CK2beta to three isoforms of the holoenzyme: CK2alpha(2)beta(2), CK2alpha(2)(')beta(2), and CK2alphaalpha(')beta(2). While CK2alpha and the "normal" holoenzyme CK2alpha(2)beta(2) have been extensively characterized in vitro and in vivo, little is known about the enzymological properties of CK2alpha' and the "alternative" holoenzyme CK2alpha(2)(')beta(2) and about their specific physiological roles. A major reason for this lack of knowledge is the fact that so far CK2alpha' rather than CK2alpha has caused serious stability and solubility problems during standard heterologous expression procedures. To overcome them, we developed a preparation scheme for CK2alpha(2)(')beta(2) from Homo sapiens in catalytically active form based on two critical steps: first expression of human CK2alpha' as a well soluble fusion protein with the maltose binding protein (MBP) and second proteolytic cleavage of CK2alpha'-MBP in the presence of human CK2beta so that CK2alpha' subunits are incorporated into holoenzyme complexes directly after their release from MBP. This successful strategy which may be adopted in comparably difficult cases of protein/protein complex preparation is presented here together with evidence that the CK2alpha'-based and the CK2alpha-based holoenzymes are similar concerning their catalytic activities but are significantly different with respect to some well-known CK2 properties like autophosphorylation and supra-molecular aggregation.     

Intermolecular contact sites in protein kinase CK2

Chemical crosslinking and analysis of CNBr-digested fusion products by immunoblotting with sequence-specific antibodies identifies an interaction between positions 55-70 of subunit (55-70) and 65-80 of subunit (65-80). This has been supported by crosslinking of subunits with peptides 65-80 and 55-70, by binding of subunits to immobilized peptides, and by the hindrance of coprecipitation with peptide-raised antibodies (anti-65-80; anti-55-70). Functionally, 55-70 is a negative regulatory region for the kinase activity of subunit . The opposite, stimulatory property of subunit has been assigned to its C-terminal part. Subdivision of peptide 155-181, that has stimulatory effect, into overlapping peptides and assaying for a binding and binding competition revealed a tight physical contact at 162-175. This region, however, is non-stimulatory indicating binding a necessary but not sufficient quality for stimulation. A contact might exist to regions surrounding C147 and/or C220 at subunit a as indicated by crosslinking and peptide competition. The crosslinking data also confirm a - contact in CK2 holoenzyme. Effects by non-ionic detergents show hydrophobic interactions to play an important role in catalytic activity adjustment.     

Modulation of death receptor-mediated apoptosis by CK2

Protein kinase CK2 has long been known to be involved in cell growth and proliferation. Recent work has also implicated its role in the suppression of apoptosis. We originally documented that removal of survival or growth stimuli resulted in rapid loss of CK2 from the nuclear matrix and chromatin which preceded induction of apoptosis. Further, we demonstrated that overexpression of CK2 in cells promotes suppression of drug-mediated apoptosis. In the present work, we have extended these observations to demonstrate that CK2 can influence apoptosis mediated via the death receptors. Overexpression of CK2 resulted in suppression of apoptosis mediated by TNF-α, TRAIL, and Fas-L in cells responsive to these ligands, whereas downregulation of CK2 resulted in augmentation of apoptosis mediated by these ligands. To our knowledge, this is the first report to show that receptor-mediated apoptosis can be modulated by changes in CK2 in prostate cancer cells. Based on our previous observations together with the evidence presented here, we propose that CK2 has an impact on the process of apoptosis mediated by diverse type of mechanisms thus playing a global role in regulation of apoptotic activity in cells.     

Validation of protein kinase CK2 as oncological target

Protein kinase CK2 is a highly conserved enzyme composed of two catalytic subunits α and/or α′ and two regulatory subunits β whose activity is elevated in diverse tumour types as well as in highly proliferating tissues. Several results suggest that the overexpression of either CK2 catalytic subunits or the CK2 holoenzyme contributes to cellular transformation. In a similar vein, experiments performed compromising the intracellular expression of CK2 has led to somehow contradictory results with respect to the ability of this enzyme to control survival and apoptosis. To better elucidate the role of CK2 in programmed cell death, we have depleted cells of CK2 catalytic subunits by the application of antisense oligodeoxynucleotides and siRNAs techniques, respectively. Our results indicate that protein kinase CK2 is characterized by an extremely high stability that might be due to its association with other intracellular proteins, enhanced half-life or lower vulnerability towards proteolytic degradation. In addition, we show that despite the effectiveness of the methods applied in lowering CK2 kinase activity in all cells investigated, CK2 might not by itself be sufficient to trigger enhanced drug-induced apoptosis in cells.     

蛋白激酶CK2与DNA断裂修复

蛋白激酶CK2（酪蛋白激酶Ⅱ）是真核细胞中普遍存在的一种信使非依赖的丝氨酸／苏氨酸蛋白激酶,它底物众多,功能广泛。DNA断裂修复是一个涉及很多种酶和蛋白的过程,CK2在其中起着很重要的作用。     

Visualization and molecular analysis of nuclear import of protein kinase CK2 subunits in living cells

We have generated fusion proteins between the subunits of CK2 and GFP and characterized their behaviour in living cells. The expressed fusion proteins were functional and interacted with endogenous CK2. Imaging of NIH3T3 cells expressing low level of GFP-CK2 or GFP-CK2 showed that both proteins were mostly nuclear in interphase. Both CK2 subunits contain nuclear localization domains that target them independently to the nucleus. Once in the nucleus, both subunits diffused rapidly in the nucleoplasm. In mitotic cells, CK2 subunits were dispersed throughout the cytoplasm and were not associated to chromatin. Our data are compatible with the idea that each subunit can translocate individually to the nucleus to interact with each other or with important cellular partners. Understanding the molecular mechanisms which regulate the dynamic localization of CK2 subunits will be of central importance.     

Localization of individual subunits of protein kinase CK2 to the endoplasmic reticulum and to the Golgi apparatus

The protein kinase CK2 is composed of two catalytic - or - and two regulatory -subunits. In mammalian cells there is ample evidence for the presence of individual CK2 subunits beside the holoenzyme. By immunofluorescence studies using peptide antibodies which allow us to detect the CK2-, - and -subunits we found all three subunits to be co-localized with a 58 KDa Golgi protein which is specific for the Golgi complex. Subfractionation studies using dog pancreas cells revealed the presence of all three subunits of CK2 at the smooth endoplasmic reticulum (sER)/Golgi fraction whereas the rough endoplasmic reticulum (rER) harboured only the catalytic - and -subunits. We found that the microsomal preparation from dog pancreas cells contained CK2 which phosphorylated a CK2 specific synthetic peptide and which was heparin sensitive. Furthermore, we could immunoprecipitate the CK2-subunit that exhibited a kinase activity which phosphorylated a CK2 specific substrate and which was heparin sensitive. Protease digestion experiments revealed that the CK2 subunits were located on the cytosolic side of the rER and the sER/Golgi complex. Thus, we could demonstrate an asymmetric distribution of the CK2 subunits at the rER and sER/Golgi complex. Since the CK2- and -subunits exhibit a substrate specificity which is different from the CK2 holoenzyme one might speculate that the asymmetric distribution of the CK2 holoenzyme and the CK2 catalytic subunits may have regulatory functions.