Subcellular localization of protein kinase CK2

More than 46 years ago, Burnett and Kennedy first described protein kinase CK2 (formerly known as casein kinase 2) in liver extracts. Since then, protein kinase CK2 has been investigated in many organisms from yeast to man. It is now well established that protein kinase CK2 is a pleiotropic and ubiquitous serine or threonine kinase, which is highly conserved during evolution. A great number of studies deal with substrates of CK2, but the fact that over 160 substrates exist is more confusing than elucidatory. The holoenzyme is composed of two regulatory beta-subunits and two catalytic alpha- or alpha'-subunits. There is now increasing evidence for individual functions of the subunits that are different from their functions in the holoenzyme. Furthermore, more and more studies describe interacting partners of the kinase that may be decisive in the regulation of this enzyme. A big step forward has been the determination of the crystal structure of the two subunits of protein kinase CK2. Now the interactions of the catalytic subunit of CK2 with ATP as well as GTP and the interaction between the regulatory subunits can be explained. However, cellular functions of protein kinase CK2 still remain unclear. In the present review we will focus our interest on the subcellular localization of protein kinase CK2. Protein kinase CK2 is found in many organisms and tissues and nearly every subcellular compartment. There is ample evidence that protein kinase CK2 has different functions in these compartments and that the subcellular localization of protein kinase CK2 is tightly regulated. Therefore studying the subcellular localization of protein kinase CK2 may be a key to its function.     

Highlighting protein kinase CK2 movement in living cells

Protein kinase CK2 has traditionally been described as a stable heterotetrameric complex (α < eqid1 > β₂) but new approaches that effectively capture the dynamic behavior of proteins, are bringing a new picture of this complex into focus. To track the spatio-temporal dynamics of CK2 in living cells, we fused its catalytic α and regulatory β subunits with GFP and analog proteins. Beside the mostly nuclear localization of both subunits, and the identification of specific domains on each subunit that triggers their localization, the most significant finding was that the association of both CK2 subunits in a stable tetrameric holoenzyme eliminates their nuclear import (Mol Cell Biol {23}: 975–987, 2003). Molecular movements of both subunits in the cytoplasm and in the nucleus were analyzed using different new and updated fluorescence imaging methods such as: fluorescence recovery after photo bleaching (FRAP), fluorescence loss in photo bleaching (FLIP), fluorescence correlation spectroscopy (FCS), and photoactivation using a biphoton microscope. These fluorescence-imaging techniques provide unprecedented ways to visualize and quantify the mobility of each individual CK2 subunit with high spatial and temporal resolution. Visualization of CK2 heterotetrameric complex formation could also be recorded using the fluorescence resonance energy transfer (FRET) technique. FRET imaging revealed that the assembling of this molecular complex can take place both in the cytoplasmic and nuclear compartments. The spatio–temporal organization of individual CK2 subunits and their dynamic behavior remain now to be correlated with the functioning of this kinase in the complex environment of the cell.     

Inducible expression of protein kinase CK2 in mammalian cells. Evidence for functional specialization of CK2 isoforms.

Protein kinase CK2 (formerly casein kinase II) exhibits elevated expression in a variety of cancers, induces lymphocyte transformation in transgenic mice, and collaborates with Ha-Ras in fibroblast transformation. To systematically examine the cellular functions of CK2, human osteosarcoma U2-OS cells constitutively expressing a tetracycline-regulated transactivator were stably transfected with a bidirectional plasmid encoding either catalytic isoform of CK2 (i.e. CK2alpha or CK2alpha') together with the regulatory CK2beta subunit in order to increase the cellular levels of either CK2 isoform. To interfere with either CK2 isoform, cells were also transfected with kinase-inactive CK2alpha or CK2alpha' (i. e. GK2alpha (K68M) or CK2alpha'(K69M)) together with CK2beta. In these cells, removal of tetracycline from the growth medium stimulated coordinate expression of catalytic and regulatory CK2 subunits. Increased expression of active forms of CK2alpha or CK2alpha' resulted in modest decreases in cell proliferation, suggesting that optimal levels of CK2 are required for optimal proliferation. By comparison, the effects of induced expression of kinase-inactive CK2alpha differed significantly from the effects of induced expression of kinase-inactive CK2alpha'. Of particular interest is the dramatic attenuation of proliferation that is observed following induction of CK2alpha'(K69M), but not following induction of CK2alpha(K68M). These results provide evidence for functional specialization of CK2 isoforms in mammalian cells. Moreover, cell lines exhibiting regulatable expression of CK2 will facilitate efforts to systematically elucidate its cellular functions.     

蛋白激酶CK2的研究进展

蛋白激酶CK2是一种真核细胞中普遍存在的信使非依赖性丝／苏氨酸蛋白激酶。近年来,对蛋白激酶CK2的研究也取得了一些重要进展,尤其是蛋白激酶CK2的结构及其作用底物,蛋白激酶CK2与肿瘤及细胞凋亡的关系,越来越引起人们的关注。     

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.     

Cellular regulators of protein kinase CK2

Protein phosphorylation is a key regulatory post-translational modification and is involved in the control of many cellular processes. Protein kinase CK2, formerly known as casein kinase II, which is a ubiquitous and highly conserved protein serine/threonine kinase, plays a central role in the control of a variety of pathways in cell proliferation, transformation, apoptosis and senescence. An understanding of the regulation of such a central protein kinase would greatly help our comprehension of the regulation of many pathways in cellular regulation. A number of reviews have addressed the detection, the development, and the characterization of inhibitors of CK2. The present review focuses on possible natural regulators of CK2, i.e. proteins and other cellular factors that bind to CK2 and thereby regulate its activity.     

The cytosolic protein kinase CK2 phosphorylates cardiac calsequestrin in intact cells

The luminal SR protein CSQ2 contains phosphate on roughly half of the serines found in its C-terminus. The sequence around phosphorylation sites in CSQ2 suggest that the in vivo kinase is protein kinase CK2, even though this enzyme is thought to be present only in the cytoplasm and nucleus. To test whether CSQ2 kinase is CK2, we combined approaches that reduced CK2 activity and CSQ2 phosphorylation in intact cells. Tetrabromocinnamic acid, a specific inhibitor of CK2, inhibited both the CSQ2 kinase and CK2 in parallel across a range of concentrations. In intact primary adult rat cardiomyocytes and COS cells, 24 h of drug treatment reduced phosphorylation of overexpressed CSQ2 by 75%. Down-regulation of CK2α subunits in COS cells using siRNA, produced a 90% decrease in CK2α protein levels, and CK2-silenced COS cells exhibited a twofold reduction in CSQ2 kinase activity. Phosphorylation of CSQ2 overexpressed in CK2-silenced cells was also reduced by a factor of two. These data suggested that CSQ2 in intact cells is phosphorylated by CK2, a cytosolic kinase. When phosphorylation site mutants were analyzed in COS cells, the characteristic rough endoplasmic reticulum form of the CSQ2 glycan (GlcNAc2Man9,8) underwent phosphorylation site dependent processing such that CSQ2-nonPP (Ser to Ala mutant) and CSQ2-mimPP (Ser to Glu mutant) produced apparent lower and greater levels of ER retention, respectively. Taken together, these data suggest CK2 can phosphorylate CSQ2 co-translationally at biosynthetic sites in rough ER, a process that may result in changes in its subsequent trafficking through the secretory pathway.     

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.     

Regulation of taurine transport systems by protein kinase CK2 in mammalian cells

Maintaining cell volume is critical for cellular function yet shift in cell volume is a prerequisite for mitosis and apoptosis. The ubiquitously and evolutionary conserved serine/threonine kinase CK2 promotes cell survival and suppresses apoptosis. The present review describes how mammalian cells regulate the cellular content of the major cellular organic osmolyte, taurine with emphasis on CK2 mediated regulation of active taurine uptake and volume-sensitive taurine release. Furthermore, we discuss how CK2-mediated regulation of taurine homeostasis is potentially involved in cellular functions such as proliferation and survival.     

Induction of ornithine decarboxylase in normal and protein kinase C--depleted human colon carcinoma cells.

To examine the role of protein kinase C (PKC) in induction of human colon adenocarcinoma cell line, DETA/W, by polypeptide growth-promoting factors, ornithine decarboxylase activity (ODC) and DNA synthesis were determined in cells depleted of PKC. PKC depletion was achieved by prolonged cultivation (more than 30 passages) with 10(-6) M phorbol 12-myristate 13-acelate. Lack of PKC in studied cells was proved by measurements of PKC activity and immunoreactivity. Although ODC activities and DNA syntheses in PKC-depleted cells were decreased by about 40-50% compared to normal DETA/W cells, the percentage increase of these mitogen-responsive reactions was quantitatively similar in both cell sublines. These results raise the possibility that not all of the biological responses to growth factors are connected with the activation of calcium-dependent PKC.     

Linking protein kinase CK2 and auxin transport

Studies performed in different organisms have highlighted the importance of protein kinase CK2 in cell growth and cell viability. However, the plant signaling pathways in which CK2 is involved are largely unknown. We have reported that a dominant-negative mutant of CK2 in Arabidopsis thaliana shows phenotypic traits that are typically linked to alterations in auxin-dependent processes. We demonstrated that auxin transport is, indeed, impaired in these mutant plants, and that this correlates with misexpression and mislocalization of PIN efflux transporters and of PINOID. Our data establishes a link between CK2 activity and the regulation of auxin homeostasis in plants, strongly suggesting that CK2 might be required at multiple points of the pathways regulating auxin fluxes.Key words: protein kinase CK2, root development, auxin, PIN, PINOIDThe plant hormone auxin plays critical roles in plant growth and development.¹ The most abundant natural auxin is the indol-3-acetic acid (IAA), which is synthesized in young apical tissues and then transported to the growing zones of the stem and root. The major route for long distance IAA movement is via the vascular tissue, but, additionally, a slower transport via cell-to-cell (called polar transport) is critical to generate auxin gradients within tissues. Formation of correct auxin gradients is thought to be essential for many plant developmental processes.² In recent years, the IAA transporters have been identified, establishing the molecular basis to understand how auxin transport is regulated. In particular, the identification of the family of plasma-resident PIN proteins, the members of which function as IAA efflux carriers, and the knowledge of their polar localization in the plasma membrane (PM), contributed to generate models predicting the direction of IAA fluxes.^3,4The factors that govern PIN targeting to a particular membrane domain are still not understood. It is known that PIN proteins constitutively undergo cycles of exocytosis and endocytosis to and from the PM, using distinct sorting and recycling endosome trafficking pathways.^5–7 Phosphorylation/dephosphorylation by the Ser/Thr kinase PINOID (PID) and the protein phosphatase 2A, respectively, controls PIN proteins apical/basal localization at the PM, via the GNOM-mediated vesicle trafficking system.⁸ Interestingly, PID is a member of the plant AGC kinases, and, as it happens with its mammals AGC counterparts, is activated by a membrane-associated 3-phosphoinositide-dependent kinase (PDK1).⁹ Moreover, a functional similarity between PIN polar localization in response to auxin and glucose receptor (GLUT4) asymmetrical distribution in response to insulin, has been pointed out.¹⁰ In both cases, cargo proteins (GLUT4 and PIN, respectively) are transported from endosomal vesicles to PM and the process is mediated by PDK1-activated AGC kinases.Protein kinase CK2 is a Ser/Thr kinase evolutionary conserved in eukaryotes, which plays key roles in cell survival, cell division and other cellular processes. A loss-of-function mutant of CK2 in Arabidopsis, obtained by overexpression of a CK2α-inactive subunit, confirmed the essential role of this protein kinase for plant viability.¹¹ Moreover, CK2mut plants showed a dramatic decrease of lateral root formation, inhibition of root growth and overproliferation of root hairs. We have further demonstrated that auxin transport is impaired in this plants, which is concomitant with missexpression of most of the PM-resident PIN proteins, and of PID.¹² In addition, PIN proteins accumulated in endosomal vesicles and auxin gradients were disturbed, both in roots and shoots of CK2mut plants. In particular, root columella cells were depleted of auxin, although the maximum at the quiescent center was unchanged. Starch granule staining with lugol revealed that columella cells retained their fate, although their organization and/or cell shape were clearly affected (Fig. 1).Open in a separate windowFigure 1Lugol-stained starch granules in uninduced (−Dex) and Dex-induced (+Dex) CK2mut roots. In the central part of the figure, a sketch of the main morphogenetic characteristics of mutant roots (right plantlet) as compared to wild-type roots (left plantlet) is shown. Note the shorter roots, wavy phenotype, absence of lateral roots and overproliferation of root hairs in mutant plants.Our results strongly suggest that CK2 is a regulator of auxin-dependent responses, most likely by participating in the regulation of auxin transport. Strikingly, depletion of CK2 activity inhibits some auxin-dependent physiological responses whereas it enhances others. For instance, whereas shoot phototropism was completely absent, root gravitropism was enhanced.¹² Figure 2 shows a time-course of DR5rev::GFP-derived signal after changing the gravity vector, in mutant and control Arabidopsis roots. The progressive auxin translocation to the lower side of the root after gravistimulation is more rapid and sustained in mutant than in control roots, which is likely responsible for the enhanced response to gravity found in mutant roots. Based on these results, we postulate that CK2 might act at different points of the auxin-induced regulatory pathway. As far as is known, the core module that regulates auxin transport is constituted by the protein kinase PID and a protein of the NPH3-domain family. NPH3-containing proteins play important roles in phototropic and gravitropic responses, and regulate polarity and endocytosis of PIN proteins.¹³ As has been proposed by other authors, the participation of one AGC kinase and one NPH3-like protein upstream of an ARF factor might be a common theme in response to different stimulus that are signaled by auxin.¹⁴ We propose that one of the functions of CK2 is the regulation of the activity of core proteins (Fig. 3). Mammalian AGC kinases are well known substrates of CK2 and CK2-dependent phosphorylation is critical for a full display of their activity. The PID and the NPH3-containing protein sequences contain numerous acidic-based motifs that are predicted CK2 phosphorylation sites. Moreover, according to Arabidopsis phosphoproteome databases, several members of the NPH3-containing protein family are predicted to be phosphorylated.¹⁵ In addition, we do not discard the possibility that other proteins involved in PIN transport might also be regulated by CK2-dependent phosphorylation. Experiments are in progress in our laboratory to assess the regulatory role of CK2 in auxin transport.Open in a separate windowFigure 2Time course of auxin relocation during root gravitropic response, as visualized by DR5rev::GFP fluorescence. Root pictures were taken at the indicated times after changing the direction of the gravity vector. Translocation of auxin to the lower part of the root is more rapid in Dex-induced CK2mut plants. Arrows indicate asymmetrical DR5::GFP fluorescence.Open in a separate windowFigure 3Proposed model for the role of CK2 in regulating auxin transport. The core module that regulates auxin transport (shown here as a black box) is constituted by the protein kinase PID and a protein of the NPH3-domain family. PID regulates apical-basal targeting of PIN proteins, by phosphorylating conserved Ser residues present in PIN hydrophilic loops.¹⁶ On the other hand, the family of NPH3-containing proteins regulates polarity and endocytosis of PIN proteins.¹³ There is also a functional similarity between the intracellular transport of PIN proteins and that of the glucose receptor (GLUT4),¹⁰ two processes that are signaled by AGC kinases. We propose that CK2 might be a regulator of the activity of the core proteins, by phosphorylating either the AGC kinase and/or the NPH3-containing protein. Mammalian CK2 is a known regulator of the activity of AGC kinases and other proteins participating in signaling pathways, such as in the Wnt/β-catenin signaling pathway.¹⁷     

Endogenous protein kinase CK2 participates in Wnt signaling in mammary epithelial cells

Protein kinase CK2 (formerly casein kinase II) is a serine/threonine kinase overexpressed in many human tumors, transformed cell lines, and rapidly proliferating tissues. Recent data have shown that many cancers involve inappropriate reactivation of Wnt signaling through ectopic expression of Wnts themselves, as has been seen in a number of human breast cancers, or through mutation of intermediates in the Wnt pathway, such as adenomatous polyposis coli or beta-catenin, as described in colon and other cancers. Wnts are secreted factors that are important in embryonic development, but overexpression of certain Wnts, such as Wnt-1, leads to proliferation and transformation of cells. We report that upon stable transfection of Wnt-1 into the mouse mammary epithelial cell line C57MG, morphological changes and increased proliferation are accompanied by increased levels of CK2, as well as of beta-catenin. CK2 and beta-catenin co-precipitate with the Dvl proteins, which are Wnt signaling intermediates. A major phosphoprotein of the size of beta-catenin appears in in vitro kinase reactions performed on the Dvl immunoprecipitates. In vitro translated beta-catenin, Dvl-2, and Dvl-3 are phosphorylated by CK2. The selective CK2 inhibitor apigenin blocks proliferation of Wnt-1-transfected cells, abrogates phosphorylation of beta-catenin, and reduces beta-catenin and Dvl protein levels. These results demonstrate that endogenous CK2 is a positive regulator of Wnt signaling and growth of mammary epithelial cells.     

Heat-induced relocalization of protein kinase CK2. Implication of CK2 in the context of cellular stress

Among various other roles described so far, protein kinase CK2 has been involved in cell cycle, proliferation, and development. Here, we show that in response to specific stresses (heat shock or UV irradiation), a pool of the cellular CK2 content relocalizes in a particular nuclear fraction, increasing the activity of the kinase there. Electron microscopic analysis shows that upon heat shock, CK2alpha and CK2beta subunits are both detected in similar speckle structures occurring in the interchromatin space but are differentially targeted inside the nucleolus. This CK2 relocalization process takes place in a time- and dose-dependent manner and is reversible upon recovery at 37 degrees C. Altogether, this work suggests CK2 be involved in the response to physiological stress in higher eukaryotic cells.     

Distinctive features of plant protein kinase CK2

In plants, protein kinase CK2 is involved in different processes that control many aspects of metabolism and development. In mammals and yeast the enzyme is a heterotretamer composed of two types of subunits. During years the subunit composition of the maize protein kinase CK2 enzyme has been a source of controversy. We have recently characterized the maize holoenzyme subunits. Our results show that multiple catalytic and regulatory subunits are expressed in maize and are able to specifically interact with other and subunits suggesting a high level of heterogeneity in the typical heterotetrameric structure. Here, we summarize data available on plant CK2 enzymes, in order to clarify the distinctive features and functions of plant protein kinase CK2.     

NKX3.1 is regulated by protein kinase CK2 in prostate tumor cells

Diminished expression of NKX3.1 is associated with prostate cancer progression in humans, and in mice, loss of nkx3.1 leads to epithelial cell proliferation and altered gene expression patterns. The NKX3.1 amino acid sequence includes multiple potential phosphoacceptor sites for protein kinase CK2. To investigate posttranslational regulation of NKX3.1, phosphorylation of NKX3.1 by CK2 was studied. In vitro kinase assays followed by mass spectrometric analyses demonstrated that CK2 phosphorylated recombinant NKX3.1 on Thr89 and Thr93. Blocking CK2 activity in LNCaP cells with apigenin or 5,6-dichlorobenzimidazole riboside led to a rapid decrease in NKX3.1 accumulation that was rescued by proteasome inhibition. Replacing Thr89 and Thr93 with alanines decreased NKX3.1 stability in vivo. Small interfering RNA knockdown of CK2alpha' but not CK2alpha also led to a decrease in NKX3.1 steady-state level. In-gel kinase assays and Western blot analyses using fractionated extracts of LNCaP cells demonstrated that free CK2alpha' could phosphorylate recombinant human and mouse NKX3.1, whereas CK2alpha' liberated from the holoenzyme could not. These data establish CK2 as a regulator of NKX3.1 in prostate tumor cells and provide evidence for functionally distinct pools of CK2alpha' in LNCaP cells.     

Expression and localization of epitope-tagged protein kinase CK2

Protein kinase CK2, formerly known as casein kinase II, is a ubiquitous protein serine/threonine kinase. The enzyme exists in tetrameric complexes composed of two catalytic (CK2α and/or CK2α′) subunits and two subunits (CK2β) that appear to have a role in modulating the activity of the catalytic subunits. With the exception of their unrelated carboxy-terminal domains, the two isozymic forms of mammalian CK2 display extensive sequence identity. Furthermore, CK2α and CK2α′ exhibit remarkable conservation between species, suggesting that they may have unique functions. In the present study, the cDNAs encoding CK2α and CK2α′ were modified by addition of the hemagglutinin tag of the influenza virus at the amino terminus of the respective proteins. The epitope-tagged proteins were transfected into Cos-7 cells and the localization of the expressed proteins determined by indirect immunofluorescence using monoclonal antibodies specific for the epitope tag. The use of transfection favors the formation of homotetrameric complexes (i.e., α₂β₂, α′₂β₂) instead of heterotetrameric complexes (i.e., αα′β₂) that are present in many cells. Epitope-tagged CK2α and CK2α′ displayed kinase activity and the ability to form complexes with CK2β. The results of these studies also indicate definitively that CK2α and CK2α′ are both localized predominantly within the nucleus. Mutation of conserved lysine residues within the ATP binding domains of CK2α and CK2α′ resulted in loss of kinase activity. However, examination of these mutants indicates that kinase activity is not essential for formation of complexes between subunits of CK2 and is not required for nuclear localization of CK2. J. Cell. Biochem. 64: 525–537. © 1997 Wiley-Liss, Inc.     

Murine protein kinase CK2: Gene and oncogene

Protein kinase CK2 (casein kinase II) is a serine-threonine protein kinase with a wide range of substrates, many of which are involved in cell cycle regulation. CK2 activity is elevated in a variety of human tumors and we have used a transgenic mouse model to demonstrate that dysregulated expression of CK2 can induce lymphoma. Thus, CK2 fulfills the definition of an oncogene: A mutated, dysregulated, or mis-expressed gene that contributes to cancer in a dominant fashion. CK2 cooperates in transforming cells with other lymphoid oncogenes such as myc and tal-1, and here we show cooperativity with loss of the tumor suppressor gene p53. To understand more about the physiological and pathological role of CK2, we are cloning the murine CK2 cDNA and gene. CK2 will be used to generate transgenic and knockout mice and the regulatory elements for gene expression will be analyzed.     

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.