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.     

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 CK2gr; and CK2. CK2 and CK2 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 CK2 is involved in the control of proliferation and/or cell survival. To understand the molecular basis for functional differences between CK2 and CK2, 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 CK2 but not CK2 [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 CK2 that regulates the cellular functions of CK2 by targeting or anchoring CK2 to specific cellular localization or by functioning as an adapter to integrate CK2-mediated signaling events with components of other signal transduction pathways.     

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.     

Distribution of CK2, its substrate MAP1B and phosphatases in neuronal cells

Neuronal morphogenesis depends on the organization of cytoskeletal elements among which microtubules play a very important role. The organization of microtubules is controlled by the presence of microtubule-associated proteins (MAPs), the activity of which is modulated by phosphorylation and dephosphorylation. One of these MAPs is MAP1B, which is very abundant within growing axons of developing neurons where it is found phosphorylated by several protein kinases including CK2. The expression of MAP1B is notably decreased after neuronal maturation in parallel with a change in the localization of the protein, which becomes largely concentrated in neuronal cell bodies and dendrites. Interestingly, MAP1B remains highly phosphorylated at sites targeted by protein kinase CK2 in mature neurons.We have analyzed the expression and localization of CK2 catalytic subunits along neuronal development. CK2 subunit appears early during development whereas CK2 subunit appears within mature neurons at the time of dendrite maturation and synaptogenesis, in parallel with the change in the localization of MAP1B. CK2 subunit is found associated with microtubule preparations obtained from either grey matter or white matter from adult bovine brain, whereas CK2 subunit is highly enriched in microtubules obtained from grey matter. These results lend support to the hypothesis that CK2 subunit is concentrated in neuronal cell bodies and dendrites, where it associates with microtubules, thus contributing to the increased phosphorylation of MAP1B in this localization in mature neurons.     

Multiple forms of protein kinase CK2 present in leukemic cells: In vitro study of its origin by proteolysis

Human recombinant CK2 subunits were incubated for different times with the two main cytosolic proteases m-calpain and 20 S proteasome. Both, m-calpain in a calcium dependent manner and the 20 S proteasome, were able to degrade CK2 subunits in vitro. In both cases, CK2 was more resistant to these proteases than CK2. When these proteases were assayed on the reconstituted (22 holoenzyme, a 37 kDa -band, analogous to that observed in AML extracts, was generated which was resistant to further degradation. No degradation was observed when the 26 S proteasome was assayed on free subunits. Studies with CK2 deletion mutants showed that m-calpain and the 20 S proteasome acted on the C-terminus end of CK2. These results pointed to cytosolic proteases as agents involved in the control of the amount of free CK2 subunits within the cell, which becomes evident when CK2 is overexpressed as in AML cells.     

The activity of CK2 in the extracts of COS-7 cells transfected with wild type and mutant subunits of protein kinase CK2

Protein kinase CK2 is ubiquitous in eukaryotes and is known to phosphorylate many protein substrates. The enzyme is normally a heterotetramer composed of catalytic ( and ) and regulatory () subunits. The physiological regulation of the enzyme is still unknown but one of the factors that may play an important role in this regulation is the ratio of the catalytic and regulatory subunits present in cells. The possible existence of free CK2 subunits, not forming part of the holoenzyme, may be relevant to the physiological function of the enzyme in substrate selection or in the interaction of the subunits with other partners. The objective of this work was to study in COS-7 cells the effects of transient expression of CK2 subunits and mutants of the catalytic subunit on the CK2 phosphorylating activity of the extracts of these cells. Using pCEFL vectors that introduce hemaggutinin (HA) or a heptapeptide (AU5) tags in the expressed proteins, COS-7 cells were transfected with and subunits of Xenopus CK2, with the subunit of D. rerio, and with Xl CK2A¹⁵⁶, which although inactive can bind tightly to CK2, and with Xl CK2E⁷⁵E⁷⁶, which is resistant to heparin and polyanion inhibition. The efficiency of transient transfection was of 10–20% of treated cells.Expression of CK2 or CK2E⁷⁵E⁷⁶ in COS-7 cells caused an increase of 5–7-fold of the CK2 activity in the soluble cell extracts. If these catalytic subunits were cotransfected with CK2, the activity increased further to 15–20-fold of the controls. Transfection of CK2 alone also increase the activity of the extracts about 2-fold. Transfection with the inactive CK2A¹⁵⁶ yielded extracts with CK2 activities not significantly different from those transfected with the empty vectors. However, cotransfection of CK2 or CK2E⁷⁵E⁷⁶ with CK2A¹⁵⁶ caused a 60–70% decrease in the CK2 activity as compared to those of cells transfected with only the active CK2 subunits. These results can be interpreted as meaning that CK2A¹⁵⁶ is a dominant negative mutant that can compete with the other catalytic subunits for the CK2 subunit. Addition of recombinant CK2 to the assay system of extracts of cells transfected with catalytic subunits causes a very significant increase in their CK2 activity, demonstrating that CK2 subunit is limiting in the extracts and that an excess of free CK2 has been produced in the transfected cells. Transfection of cells with CK2E⁷⁵E⁷⁶ results in a CK2 activity of extracts that is 90% resistant to heparin demonstrating that a very large proportion of the CK2 activity is derived from the expression of the exogenous mutant. In both the in vivo and in vitro systems, the sensitivity of CK2E⁷⁵E⁷⁶ to heparin increases considerably when it forms part of the holoenzyme CK2₂₂.     

CK2α - protein phosphatase 2A molecular complex: Possible interaction with the MAP kinase pathway

Despite its wide range of known substrates, the signaling function of protein kinase CK2 is still enigmatic. Mounting evidence suggests that CK2, the catalytic subunit of holoenzymic CK2, may exist free of its usual regulatory partner CK2, raising the possibility that free CK2 has regulation and function distinct from those of the holoenzyme. We previously reported that CK2 could bind to the core dimer of protein phosphatase 2A, and indirectly cause down-regulation of the PP2A substrate MEK1, possibly via activation of PP2A and/or targeting of PP2A to some element of the Ras/Raf/MEK pathway. Here, these results are confirmed and extended. By using transfection experiments and immune kinase assays, we show that endogenous PP2Ac and CK2 are the only major substrates associating with epitope-tagged CK2, and that expression of activated Raf results in disruption of the CK2- PP2A association. Such disruption might be a necessary step for maximal activation of the MAP kinase pathway by Raf. In keeping with this idea, overexpression of CK2 dose-dependently inhibits the mitogen-induced activation of cotransfected, epitope-tagged MAP kinase. We suggest that the CK2 free form of CK2 is both a target and a regulator of Raf/MAPK signaling.     

The expression and biological activity of IL-2 receptor on a human pancreas cancer cell line

To ascertain whether the tumor cells can regulate the host immune systems through the production of the cytokines or their receptors, we examined the expressions of tumor necrosis factor (TNF), tumor necrosis factor (TNF), interleukin 2 (IL-2) and interleukin 2 receptor alpha chain (IL-2R) on the human cancer cell lines by Northern blot analysis. We used K562 (leukemia cell line), MCF-7 (breast cancer cell line), LS180, HT29 (colon cancer cell lines), SH101 (gastric cancer cell line) and PH101 (pancreas cancer cell line). Expressions of TNF, TNF and IL-2 mRNA were not detected in any of the tumor cell lines. However, 1.4 and 3.5 kilobases of the IL-2R mRNA were expressed in the PH101 cells, but not in the other five cell lines. Furthermore, IL-2R was detected on the cell surface of the PH101 cells by the flow-cytometric analysis with an anti-IL-2R monoclonal antibody. Interestingly, the soluble IL-2R (sIL-2R) was found in the conditioned media obtained from the PH101 cell culture with a sandwich enzyme immunoassay. Moreover, the sIL-2R secreted from the PH101 cells blocked the IL-2 dependent lymphocyte proliferation. These results indicate that the expression of IL-2R on PH101 might suppress the IL-2 induced lymphocyte proliferation.     

Specific in vitro phosphorylation of plant eIF2α by eukaryotic eIF2α kinases

Phosphorylation of the subunit of eukaryotic initiation factor 2 (eIF2) is known to be an important translational control mechanism in all eukaryotes with the major exception of plants. Regulation of mammalian and yeast eIF2 activity is directly governed by specific phosphorylation on Ser-51. We now demonstrate that recombinant wheat wild-type (51S) but not mutant 51-Ala (51A) protein is phosphorylated by human PKR and yeast GCN2, which are defined eIF2 kinases. Further, only wheat wild-type eIF2 is a substrate for plant-encoded, double-stranded RNA-dependent kinase (pPKR) activity. Plant PKR and GCN2 phosphorylate recombinant yeast eIF2 51S but not the 51A mutant demonstrating that pPKR has recognition site capability similar to established eIF2 kinases. A truncated version of wild-type wheat eIF2 containing 51S but not the KGYID motif is not phosphorylated by either hPKR or pPKR suggesting that this putative eIF2 kinase docking domain is essential for phosphorylation. Taken together, these results demonstrate the homology among eukaryotic eIF2 species and eIF2 kinases and support the presence of a plant eIF2 phosphorylation pathway.     

High D-glucose does not affect binding of α-tocopherol to human erythrocytes

The role of -tocopherol uptake system in human erythrocyte in the uptake of plasma -tocopherol has been suggested. However no information is available on -tocopherol uptake activity of human erythrocytes in the presence of high levels of D-glucose which is known to lead to pathological alterations in different cells including human erythrocytes. Therefore, in order to examine the effect of D-glucose on the binding of -tocopherol to human erythrocytes, the binding characteristics of -tocopherol to these cells were established first. Binding of [3H]-tocopherol to human erythrocytes was both saturable and specific. Scatchard analysis of -tocopherol binding to these cells showed the presence of two independent classes of binding sites with widely different affinities. The high affinity binding sites had a dissociation constant (Kd1) of 90 nM with a binding capacity (n1) of 900 sites per cell, whereas the low affinity binding sites had a dissociation constant (Kd2) of 5.2 M and a binding capacity (n2) of 105,400 sites per cell. Trypsin treatment abolished all the -tocopherol binding activity. Competition for the binding of -tocopherol to human erythrocytes was effective with other homologues of -tocopherol (-tocopherol, -tocopherol and -tocopherol) and their potency was almost equal to -tocopherol itself. The order of preference was -tocopherol > -tocopherol -tocopherol -tocopherol. Incubation of human erythrocytes with various concentrations of D-glucose did not affect -tocopherol uptake activity. Our data demonstrate the presence of an -tocopherol uptake system in human erythrocytes and that the -tocopherol uptake activity is not modulated by the presence of D-glucose.     

Characterization,subcellular localization and nuclear targeting of casein kinase 2 from Zea mays

We have isolated and characterized the genomic clone of maize casein kinase 2 (CK2) subunit using the previously described CK2-1 cDNA clone as a probe. The genomic clone is 7.5 kb long and contains 10 exons, separated by 9 introns of different size, two larger than 1.5 kb and the others around 100–150 bp. The sequence of the exons is 100% homologous to the sequence of the CK2-1 cDNA. Southern hybridization of total genomic DNA from maize embryos with CK2 cDNA indicated that the CK2-1 gene is part of a multigenic family. We also isolated a new embryo cDNA clone coding for an CK2-2 subunit. We studied the regulation of the enzyme in embryos at the mRNA level, at the protein level and by activity testing. By using immunocytochemistry the CK2 protein was localized in several types of cells of mature embryos. Particularly strong signals were visible in the cytoplasm of epidermis and meristematic cells. Decoration of nuclei of root cortex and scutellum cells was also observed suggesting that CK2 can shift from the cytoplasm into nuclei in specific cell types. We examined whether CK2 contained specific protein domains which actively target the protein to the nucleus by using in-frame fusions of the maize CK2 subunit to the reporter gene encoding -glucuronidase (GUS) which were assayed in transiently transformed onion epidermal cells. Analysis of chimeric constructs identified one region containing a nuclear localization signal (NLS) that is highly conserved in other CK2 proteins.     

Association of protein kinase CK2 with eukaryotic translation initiation factor eIF-2 and with grp94/endoplasmin

Protein kinase CK2 forms complexes with some protein substrates what may be relevant for the physiological control of this protein kinase. In previous studies in rat liver cytosol we had detected that the trimeric form of eukaryotic translation initiation factor 2 (eIF-2) co-eluted with protein kinase CK2. We have now observed that the ratio between eIF-2 and cytosolic CK2 contents in testis, liver and brain is quite similar, being eIF-2 levels about 5-fold higher than those of CK2. Furthermore eIF-2 was present in liver samples immunoprecipitated with anti-CK2/ antibodies, confirming the existence of complexes containing both proteins. Nonetheless, these complexes would represent only a fraction of total cytosolic CK2 and eIF-2.We had also observed that rat liver membrane glycoproteins obtained through chromatography on wheat-germ lectin-Sepharose contain CK2 activity which copurifies with grp94/endoplasmin. We have now confirmed that this activity was due to the presence of protein kinase CK2 as evidenced by immunodetection with antibodies against CK2/. The fractions enriched in grp94/endoplasmin and CK2 also contained another 55-kDa polypeptide (p55) phosphorylated by CK2 which has been identified as calreticulin by N-terminal sequencing. Calreticulin and grp94/endoplasmin could be partially resolved from CK2 by chromatography on heparin-agarose and almost completely on ConA-Sepharose. However, phosphorylation of immunoprecipitated grp94/endoplasmin was enhanced by its preincubation with purified CK2 prior to immunoprecipitation, what confirms the easy reassociation between these proteins.The association of protein kinase CK2 with eIF-2 and with grp94/endoplasmin may serve to locate the enzyme in the cellular machinery involved in protein synthesis and folding, and reinforces the possible involvement of CK2 in these processes.     

Novel Type of Signaling Molecules: Protein Kinases Covalently Linked with Ion Channels

Recently we identified a new class of protein kinases with a novel type of catalytic domain structurally and evolutionarily unrelated to the conventional eukaryotic protein kinases. This new class, which we named alpha-kinases, is represented by eukaryotic elongation factor-2 kinase and the Dictyosteliummyosin heavy chain kinases. Here we cloned, sequenced, and analyzed the tissue distribution of five new putative mammalian -kinases: melanoma -kinase, kidney -kinase, heart -kinase, skeletal muscle -kinase, and lymphocyte -kinase. All five are large proteins of more than 1000 amino acids with an -kinase catalytic domain located in the carboxyterminal part. We expressed the catalytic domain of melanoma -kinase in Escherichia coli, and found that it autophosphorylates at threonine residues, demonstrating that it is a genuine protein kinase. Unexpectedly, we found that long aminoterminal portions of melanoma and kidney -kinases represent new members of the TRP ion channel family, which are thought to mediate the capacitative Ca²⁺entry in nonexcitable mammalian cells. This suggests that melanoma and kidney -kinases, which represent a novel type of signaling molecule, are involved in the regulation of Ca²⁺influx in mammalian cells.     

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.     

Generation of mutants of CK2α which are dependent on the β-subunit for catalytic activity

To shed light on the structural features underlying high constitutive activity of protein kinase CK2 a number of mutants of the human CK2 subunit altered in the interactions between the N-terminal segment and the activation loop have been generated and shown to be defective in catalytic activity. In particular the truncated mutant 2-12 displays under standard conditions an almost complete loss of catalytic activity accounted for by a dramatic rise in its Km for ATP (from 10 to 206 M) and a reduced Kcat. Such a drop in efficiency is paralleled by conformational disorganization, as judged from Superdex 75 gel filtration profile. Both catalytic properties and gel filtration behaviour similar to those of wild type CK2 were restored upon association with the regulatory -subunit, suggesting that constitutive activity is conferred to CK2 and to CK2 holoenzyme through different molecular mechanisms. In the holoenzyme an assumable release of tension at the backbone of Ala-193 (as seems to be indicated by a comparison of the crystal structures of maize CK2 alone vs. a CK2– peptide complex) may result in the ability of the activation loop to adopt its proper conformation independently of interactions with the N-terminal segment.     

Response of cancer cells to molecular interruption of the CK2 signal

Protein kinase CK2 is one of the key cellular signals for cell survival, growth, and proliferation. It is has been observed to be elevated in various cancers that have been examined. Various observations suggest that moderate dysregulation of CK2 may profoundly influence the cell response. We have examined the effects of interfering with the CK2 signal in various cancer cell lines by employing antisense oligodeoxynucleotides (ODN) against the and subunits of CK2. Our results demonstrate that antisense CK2- and antisense CK2- ODNs markedly influence cell viability of these cancer cells in a dose and time-dependent manner. Antisense CK2- was slightly more effective than antisense CK2- in most of the cells tested. The efficacy of the antisense ODN seemed to vary with the cell type; however, in all cases potent induction of apoptosis was observed. Significantly, the effects of the antisense ODN on the CK2 activity in the nuclear matrix were relatively small compared to the much stronger induction of apoptosis in cells. This suggests that modest down-regulation of CK2 can evoke a much greater apoptotic response in cancer cells.     

Evaluation of hydrophobicity versus chaperonelike activity of bovine alphaA- and alphaB-crystallin

Calf lens A-crystallin isolated by reversed-phase HPLC demonstrates a slightly more hydrophobic profile than B-crystallin. Fluorescent probes in addition to bis-ANS, like cis-parinaric acid (PA) and pyrene, show higher quantum yields or Ham ratios when bound to A-crystallin than to B-crystallin at room temperature. Bis-ANS binding to both A- and B-crystallin decreases with increase in temperature. At room temperature, the chaperone-like activity of A-crystallin is lower than that of B-crystallin whereas at higher temperatures, A-crystallin shows significantly higher protection against aggregation of substrate proteins compared to B-crystallin. Therefore, calf lens A-crystallin is more hydrophobic than B-crystallin and chaperone-like activity of -crystallin subunits is not quantitatively related to their hydrophobicity.     

Long-range physical mapping of the alpha-amylase-1 (alpha-Amy-1) loci on homoeologous group 6 chromosomes of wheat

Summary Long-range physical maps of the small multigene family of the malt -amylase genes (-Amy-1) located on the long arms of wheat chromosomes 6A (the -Amy-A1 locus) and 6B (-Amy-B1) were generated by pulsed-field gel electrophoresis analysis. By using three methylation-sensitive rare-cutter restriction endonucleases, NotI, NruI and MluI, and an -Amy-1 cDNA probe and four gene-specific genomic probes from the -Amy-B1 locus, the size of the -Amy-B1 locus was estimated to be about 700 kb and of the -Amy-B1 locus to be about approximately 4300 kb. These two maps indicate clustering of GC-rich and C-methylation-sensitive restriction enzyme recognition sites. At least five regions reminiscent of CpG islands are apparent in -Amy-B1, and three in -Amy-A1. Correlation between recombination frequency and physical distance within the -Amy-B1 locus suggests that 1 cM approximates to 1 Mb in physical distance.     

ααααanti-3.7 type II: a new α-globin gene rearrangement suggesting that the α-globin gene duplication could be caused by intrachromosomal recombination

Summary We report here a new human -globin gene rearrangement carrying the two normal, 2 and 1, and two hybrid, 1/2, globin genes in the order 5-2-1/2-1/2-1-3. Both the hybrid genes, subtyped with ApaI and RsaI restriction enzymes, were found to be of the uncommon anti 3.7 type II. The hybrid genes were expressed at the biosynthetic level and their interaction with the -thalassaemia IVS 1 nt 1 GA mutation caused thalassaemia intermedia. We also report a case of an -globin gene rearrangement in the twin of one of the -globin gene carriers; the duplicated gene was of the anti 4.2 type and was associated with the absence of RsaI polymorphism. The singular finding of an -anti 3.7 cluster with two identical rare hybrid genes suggests that the reciprocal unequal recombination causing the -globin gene rearrangements could be of the intra-chromosomal rather than the interchromosomal type.     

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.