Greg Vilk

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. CK2α or CK2α′) together with the regulatory CK2β 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 CK2α or CK2α′ (i.e. GK2α (K68M) or CK2α′(K69M)) together with CK2β. 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 CK2α or CK2α′ 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 CK2α differed significantly from the effects of induced expression of kinase-inactive CK2α′. Of particular interest is the dramatic attenuation of proliferation that is observed following induction of CK2α′(K69M), but not following induction of CK2α(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.

Phosphorylation regulates the stability of the regulatory CK2β subunit

Protein kinase CK2 is a protein serine/threonine kinase that exhibits elevated expression in a number of cancers and displays oncogenic activity in mice. The regulatory CK2β subunit has a central role in assembly of functional tetrameric CK2 complexes where it participates in modulation of catalytic activity and substrate specificity. Since overexpression of CK2β results in elevated levels of CK2 activity, we investigated the molecular mechanisms that control its degradation since perturbations in these pathways could contribute to elevated CK2 in cancer. In this study, we demonstrate that CK2β is degraded by a proteasome-dependent pathway and that it is ubiquitinated. We have also investigated the role of phosphorylation and a putative destruction box in regulating its stability in cells. Importantly, replacement of three serine residues within the autophosphorylation site of CK2β with glutamic acid residues resulted in a significant decrease in its degradation indicating that autophosphorylation is involved in regulating its stability. Notably, although the autophosphorylation site of CK2β is remarkably conserved between species, this is the first functional role ascribed to this site. Furthermore, based on these results, we speculate that alterations in the phosphorylation or dephosphorylation of the regulatory CK2β subunit could underlie the elevated expression of CK2 that is observed in cancer cells.

A Peptide-Based Target Screen Implicates the Protein Kinase CK2 in the Global Regulation of Caspase Signaling

Phosphorylation of caspase substrates by the protein kinase CK2 may underlie its role in tumorigenesis. Protection from Death Caspases are cysteine-dependent proteases that cleave target proteins—including other caspases—at aspartate residues within caspase recognition motifs. Caspase-3, which operates at the point of convergence of extrinsic and intrinsic cell death pathways, is generated as a proenzyme that must be cleaved by upstream caspases to become activated. Noting that phosphorylation of caspase substrates at residues near the caspase recognition motif protects them from cleavage (see the Perspective by Filhol and Cochet), Duncan et al. scanned the human proteome for sequences that contained overlapping target sites for caspases and any of 10 kinases implicated in promoting cell survival or tumorigenesis. The protein kinase CK2 emerged as the kinase with the greatest number of such overlapping sequences, and potential targets of CK2 and caspases were evaluated by a newly developed technique for identifying caspase substrates. In addition to phosphorylating targets of caspase-3, CK2 also phosphorylated procaspase-3, thereby blocking its activation by upstream caspases and thus protecting cells from apoptosis. Together, these data suggest a global role for CK2 in preventing apoptosis, which may underlie its role in tumorigenesis. The convergence of caspase and protein kinase signaling pathways has become increasingly evident, as illustrated by the protection of caspase substrates from cleavage upon undergoing phosphorylation at or near to their caspase recognition motifs. To investigate the global role of phosphorylation in the regulation of caspase signaling, we designed a peptide match program to identify sequences from the human proteome that contained overlapping recognition motifs for caspases and kinases. We identified the protein kinase CK2 as the most prominent kinase with a consensus site for phosphorylation that overlapped with caspase recognition motifs. We then evaluated potential targets of CK2 and caspases by combining peptide array target screens with identification of caspase substrates. We identified numerous shared candidate targets of CK2 and caspases, including procaspase-3, which functions at a level at which both intrinsic and extrinsic apoptotic signals converge. Together, these data support a role for CK2-dependent phosphorylation as a global mechanism for inhibiting caspase signaling pathways.

Regulation of cell proliferation and survival: convergence of protein kinases and caspases.

Intricate networks of protein kinases are intimately involved in the regulation of cellular events related to cell proliferation and survival. In addition to protein kinases, cells also contain networks of proteases including aspartic-acid directed caspases organized in cascades that play a major role in the regulation of cell survival through their involvement in the initiation and execution phases of apoptosis. Perturbations in regulatory protein kinase and caspase networks induce alterations in cell survival and frequently accompany transformation and tumorigenesis. Furthermore, recent studies have documented that caspases or their substrates are subject to phosphorylation in cells illustrating a potential convergence of protein kinase and caspase signaling pathways. Interestingly, a number of caspase substrates are protected from cleavage when they are phosphorylated at sites that are adjacent to caspase cleavage sites. While it is theoretically possible that many distinct protein kinases could protect proteins from caspase-mediated cleavage, protein kinase CK2 is of particular interest because acidic amino acids, including aspartic acid residues that are recognized by caspases, are its dominant specificity determinants.

Protein kinase CK2 catalyzes tyrosine phosphorylation in mammalian cells.

Protein kinase CK2 exhibits oncogenic activity in mice and is over-expressed in a number of tumors or leukemic cells. On the basis of its amino acid sequence and a wealth of experimental information, CK2 has traditionally been classified as a protein serine/threonine kinase. In contrast to this traditional view of CK2, recent evidence has shown that CK2 can also phosphorylate tyrosine residues under some circumstances in vitro and in yeast. In this study, we provide definitive evidence demonstrating that CK2 also exhibits tyrosine kinase activity in mammalian cells. Tyrosine phosphorylation of CK2 in cells and in CK2 immunoprecipitates is dependent on CK2 activity and is inhibited by the CK2 selective inhibitor 4,5,6,7-tetrabromobenzotriazole. Examination of phosphotyrosine profiles in cells reveals a number of proteins, including CK2 itself, which exhibit increased tyrosine phosphorylation when CK2 levels are increased. Peptide arrays to evaluate the specificity determinants for tyrosine phosphorylation by CK2 reveal that its specificity for tyrosine phosphorylation is distinct from its specificity for serine/threonine phosphorylation. Of particular note is the requirement for an aspartic acid immediately C-terminal to the phosphorylatable tyrosine residue. Collectively, these data provide conclusive evidence that CK2 catalyzes the phosphorylation of tyrosine residues in mammalian cells, a finding that adds a new level of complexity to the challenge of elucidating its cellular functions. Furthermore, these results raise the possibility that increased CK2 levels that frequently accompany transformation may contribute to the increased tyrosine phosphorylation that occurs in transformed cells.

A novel technique for the transplantation of pancreatic islets within a vascularized device into the greater omentum to achieve insulin independence

BACKGROUND The greater omentum with its vascularization and blood flow has been considered as a location for islet transplantation; however, there is a need to provide a controlled and protected site for the islets within the omentum that would be applicable to donor islets and future stem cell technologies. Here we describe the use of a novel device implanted within the omentum with a subcutaneous delivery port that offers an environment for donor islets. METHODS A prototype cell pouch device was wrapped in the greater omentum and an islet implantation port was exposed subcutaneously in diabetic Lewis rats. After tissue growth throughout the device, islet isografts were implanted and long-term glucose control was evaluated. RESULTS By using this technique, 7 of 10 diabetic rat recipients showed long-term normal blood glucose levels after minimal islet dose transplants. Histologic assessment revealed collagen formation and vascularization within the device. CONCLUSIONS The implanted device assessed using this technique provides a safe and efficacious environment for the support of pancreatic islets contained within a removable device as a cell therapy in a highly vascularized setting.

Functional specialization of CK2 isoforms and characterization of isoform-specific binding partners.

In mammals, protein kinase CK2 has two isozymic forms of its catalytic subunit, designated CK2α and CK2α’. CK2α and CK2α’ exhibit extensive similarity within their catalytic domains but have completely unrelated C-terminal sequences. To systematically examine the cellular functions of each CK2 isoform in mammalian cells, we have generated human osteosarcoma U2-OS cell lines with the expression of active or inactive versions of each CK2 isoform under the control of an inducible promoter [22]. Examination of these cell lines provides evidence for functional specialization of CK2 isoforms at the cellular level in mammals with indications that CK2α’ is involved in the control of proliferation and/or cell survival. To understand the molecular basis for functional differences between CK2α and CK2α’, we have undertaken studies to identify proteins that interact specifically with each isoform of CK2 and could contribute to the regulation of their independent functions. A novel pleckstrin-homology domain containing protein, designated CK2-interacting protein 1 (i.e. CKIP-1) was isolated using the yeast two hybrid system as a protein that interacts with CK2α but not CK2α’ [23]. When expressed in cells as a fusion with green fluorescent protein, CKIP-1 localizes to the cell membrane and to the nucleus. In this study, we present evidence from deletion analysis of CKIP-1 suggesting that a C-terminal region containing a putative leucine zipper has a role in regulating its nuclear localization. Collectively, our data supports a model whereby CKIP-1 is a non-enzymatic regulator of CK2α that regulates the cellular functions of CK2α by targeting or anchoring CK2α to specific cellular localization or by functioning as an adapter to integrate CK2α-mediated signaling events with components of other signal transduction pathways. (Mol Cell Biochem 227: 21-29, 2001)

Interaction between CK2α and CK2β, the Subunits of Protein Kinase CK2: Thermodynamic Contributions of Key Residues on the CK2α Surface

The protein Ser/Thr kinase CK2 (former name: casein kinase II) exists predominantly as a heterotetrameric holoenzyme composed of two catalytic subunits (CK2α) bound to a dimer of noncatalytic subunits (CK2β). We undertook a study to further understand how these subunits interact to form the tetramer. To this end, we used recombinant, C-terminal truncated forms of human CK2 subunits that are able to form the holoenzyme. We analyzed the interaction thermodynamics between the binding of CK2α and CK2β as well as the impact of changes in temperature, pH, and the ionization enthalpy of the buffer using isothermal titration calorimetry (ITC). With structure-guided alanine scanning mutagenesis we truncated individual side chains in the hydrophobic amino acid cluster located within the CK2α interface to identify experimentally the amino acids that dominate affinity. The ITC results indicate that Leu41 or Phe54 single mutations were most disruptive to binding of CK2β. Additionally, these CK2α mutants retained their kinase activity. Furthermore, the substitution of Leu41 in combination with Phe54 showed that the individual mutations were not additive, suggesting that the cooperative action of both residues played a role. Interestingly, the replacement of Ile69, which has a central position in the interaction surface of CK2α, only had modest effects. The differences between Leu41, Phe54, and Ile69 in interaction relevance correlate with solvent accessibility changes during the transition from unbound to CK2β-bound CK2α. Identifying residues on CK2α that play a key role in CK2α/CK2β interactions is important for the future generation of small molecule drug design.

Localization of phosphorylated CK2α to the mitotic spindle requires the peptidyl-prolyl isomerase Pin1

CK2 is a serine/threonine kinase with many substrates, largely unknown modes of regulation and essential roles in mitotic progression. CK2α, a catalytic subunit of CK2, is phosphorylated in mitosis, and here we examine the effect of phosphorylation on CK2α localization. Using phosphospecific antibodies, we show that CK2α localizes to the mitotic spindle in a phosphorylation-dependent manner. Mitotic spindle localization requires the unique C-terminus of CK2α, and involves a novel regulatory mechanism in which phosphorylation of CK2α facilitates binding to the peptidyl-prolyl isomerase Pin1, which is required for CK2α mitotic spindle localization. This could explain how the constitutive activity of CK2α might be targeted towards mitotic substrates. Furthermore, because Pin1 has many important spindle substrates, this might represent a general mechanism for localization of mitotic signalling proteins.

Inducible expression of the regulatory protein kinase CK2β subunit: Incorporation into complexes with catalytic CK2 subunits and re‐examination of the effects of CK2β on cell proliferation

The regulatory subunit of protein kinase CK2, designated CK2β, exists both free in cells and in complexes with the CK2 catalytic subunits. Growing evidence suggests that CK2β has functions dependent and independent of the CK2 catalytic subunits. There have been indications that CK2β has functions associated with DNA damage responses and in the control of cell proliferation. For example, transient and stable constitutive overexpression of CK2β in mammalian cells was previously shown to perturb cell cycle progression and to attenuate proliferation. To systematically investigate the molecular mechanisms responsible for these effects of CK2β on cell proliferation, we generated human osteosarcoma U2OS cell lines with tetracycline‐regulated expression of CK2β. Increased expression of CK2β results in increases in total cellular CK2 activity, but no changes in cell cycle profiles or proliferation. Furthermore, following exposure to ultraviolet radiation, p53 induction was identical regardless of the levels of CK2β in cells. Mouse 3T3‐L1 cells stably transfected with CK2β also showed no alterations in cell proliferation. The differences between these results and those previously reported emphasize the complex nature of CK2β and its cellular functions. Furthermore, these results indicate that increased expression of CK2β is not by itself sufficient to effect alterations in cell proliferation. J. Cell. Biochem. 84: 84–99, 2002.