UNIPROT:P06889 - FACTA Search

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Query: UNIPROT:P06889 (Mol)
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Breast cancer is a major cause of cancer death in women, and the genetic abnormalities leading to the common sporadic forms of the disease are still under active investigation. CK2 has been reported to be upregulated in human breast cancer, which these studies confirm; CK2 is also upregulated in rat carcinogen-induced breast tumors. Transgenic mice overexpressing CK2alpha in the mammary gland develop mammary hyperplasia, dysplasia, and eventually adenocarcinomas, demonstrating that dysregulated expression of CK2 can contribute to transformation of the mammary epithelium. These mammary tumors have evidence of activation of the Wnt and NFkappaB pathways and upregulation of c-Myc. CK2 is capable of phosphorylating the key signaling molecule in the Wnt pathway, the transcriptional cofactor beta-catenin, and regulating its turnover. CK2 is known to phosphorylate IkappaB and thereby regulate basal NFkappaB levels; in the mammary cell lines and tumors, CK2 activity correlates with NFkappaB levels and inhibition of CK2 downregulates NFkappaB. Thus, CK2 may promote breast cancer through dysregulation of key pathways of transcriptional control in the mammary epithelium, and inhibition of CK2 has a potential role in the treatment of breast and other cancers.
Mol Cell Biochem 2001 Nov
PMID:Protein kinase CK2: signaling and tumorigenesis in the mammary gland. 1182 67

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 alpha and beta subunits of CK2. Our results demonstrate that antisense CK2-alpha and antisense CK2-beta ODNs markedly influence cell viability of these cancer cells in a dose and time-dependent manner. Antisense CK2-alpha was slightly more effective than antisense CK2-beta 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 downregulation of CK2 can evoke a much greater apoptotic response in cancer cells.
Mol Cell Biochem 2001 Nov
PMID:Response of cancer cells to molecular interruption of the CK2 signal. 1182 68

Protein kinase CK2 is an enzyme that is ubiquitous in eukaryotes. This enzyme, composed of catalytic (alpha and alpha') and regulatory (beta) subunits, is responsible for the phosphorylation of a large number of proteins and is implicated in cell division. Genomic clones coding for the CK2alpha subunit of Xenopus laevis have been isolated. Initial restriction enzyme profiles and subsequent PCR analysis and DNA sequencing indicated that these genomic clones correspond to two different genes. The two genes are highly homologous in the regions of the coding sequence (only 3 amino acid differences) but differ considerable in their intron sequences and lengths. Gene 1 corresponds to the cDNA of XlCK2alpha which had been previously isolated and described. The genomic clone for this gene was truncated. Gene 2 contains the entire coding region for CK2alpha subunit as well as a fragment of 6.4 kb of the 5' upstream region. The exon/intron boundaries of both genes obey the GT/AG rule with the exception of intron V where the less common GC/AG is seen. Comparison of the size of ten coding exons and sites where these are interrupted by introns shows strong conservation with respect to the human CK2alpha gene. RT-PCR analysis of mRNAs from X. laevis ovary, oocytes and early embryos using a specific primer for gene 2 demonstrated that this gene is expressed in these tissues and cells. Analysis of transcription start sites using 5'RACE and RNA from stage VI oocytes demonstrated that there are multiple start sites in the XlCK2alpha mRNA. It was also seen that a noncoding exon 1 is present 4 kb upstream of the translation start site and that alternate splicing occurs in gene 2 to give exon 1 of different lengths. Sequencing of the entire upstream genomic region of gene 2 revealed that there are regions of homology to the sequence of exon 1 of the human CK2alpha gene. Other sequences with consensus to transcription factor binding sites that are seen in the promoter region of human CK2alpha are also found in the X. laevis CK2alpha gene 2. These sites include Ets1, E2F, CCAAT and GC rich regions. No canonical TATA motif is observed.
Mol Cell Biochem 2001 Nov
PMID:The genomic structure of two protein kinase CK2alpha genes of Xenopus laevis and features of the putative promoter region. 1182 69

In mammals, protein kinase CK2 has two isozymic forms of its catalytic subunit, designated CK2alpha and CK2alpha'. CK2alpha and CK2alpha' 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. Examination of these cell lines provides evidence for functional specialization of CK2 isoforms at the cellular level in mammals with indications that CK2alpha' is involved in the control of proliferation and/or cell survival. To understand the molecular basis for functional differences between CK2alpha and CK2alpha', 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 CK2alpha but not CK2alpha'. 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 CK2alpha that regulates the cellular functions of CK2alpha by targeting or anchoring CK2alpha to specific cellular localization or by functioning as an adapter to integrate CK2alpha-mediated signaling events with components of other signal transduction pathways.
Mol Cell Biochem 2001 Nov
PMID:Functional specialization of CK2 isoforms and characterization of isoform-specific binding partners. 1182 70

A search for strategies was conducted in order to obtain a human protein kinase CK2 preparation which would be suitable for crystallization, despite the fact that the recombinant enzyme is abundant and can be readily purified to homogeneity. This seemingly contradiction is based on the fact that the catalytic subunit moiety of the human CK2 holoenzyme is not stable neither as a free subunit nor in the tetrameric complex. All attempts to prevent degradation failed. Hence, alternative approaches were designed in order to avoid this degradation, which was expected to hamper any crystallization efforts severely. One of the approaches chosen was the production of a chimeric holoenzyme made up from a human regulatory subunit and a catalytic subunit from Z. mays. The plant catalytic subunit, in contrast to the human counterpart is very stable and does not undergo this kind of degradation. The second strategy to tackle the problem of instability was to produce the homologous recombinant human CK2 holoenzyme and then, instead of trying to avoid degradation, attempt to accelerate degradation until all catalytic subunit material was converted to the degraded form, i.e. a 40 kDa polypeptide.
Mol Cell Biochem 2001 Nov
PMID:Characterization of CK2 holoenzyme variants with regard to crystallization. 1182 71

Surface plasmon resonance has been used to study the interaction between the subunits composing protein kinase CK2 (two catalytic, alpha-subunits, and two regulatory, beta-subunits), as well as the interaction of each subunit with two types of protein substrates, casein, the phosphorylation of which is activated by the regulatory subunit, and calmodulin, which belongs to the kind of substrates on which the catalytic subunit is downregulated by the regulatory subunit. The interaction of casein with the catalytic subunit differs from the interaction with the holoenzyme. Similarly to the interaction with the regulatory subunit, the catalytic subunit interacts with the protein substrate forming a very stable, irreversible complex. The reconstituted holoenzyme, however, binds casein reversibly, displaying a binding mode similar to that displayed by the regulatory subunit. The interaction of calmodulin with the catalytic subunit gives place, like in the case of casein, to an irreversible complex. The interactions with the regulatory subunit and with the holoenzyme were practically negligible, and the interaction with the regulatory subunit disappeared upon increasing the temperature value to close to 30 degrees C. The presence of polylysine induced a high increase in the extent of calmodulin binding to the holoenzyme. The results obtained suggest that CK2beta subunit and protein substrates share a common, or at least an overlapping, site of interaction on the catalytic subunit. The interaction between both subunits would prevent substrates from binding irreversibly to alpha subunit, and, at the same time, it would generate a new and milder site of interaction between the whole holoenzyme and the protein substrate. The main difference between casein and calmodulin would consist in the lower affinity display by the last for the new site generated upon the binding of the regulatory subunit, in the absence of polycations like polylysine.
Mol Cell Biochem 2001 Nov
PMID:A surface plasmon resonance study of the interactions between the component subunits of protein kinase CK2 and two protein substrates, casein and calmodulin. 1182 72

Protein kinase CK2 is ubiquitous in eukaryotes and is known to phosphorylate many protein substrates. The enzyme is normally a heterotetramer composed of catalytic (alpha and alpha') and regulatory (beta) 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 hemagglutinin (HA) or a heptapeptide (AU5) tags in the expressed proteins, COS-7 cells were transfected with alpha and beta subunits of Xenopus CK2, with the alpha' subunit of D. rerio, and with Xl CK2alphaA156, which although inactive can bind tightly to CK2beta, and with Xl CK2alphaE75E76, which is resistant to heparin and polyanion inhibition. The efficiency of transient transfection was of 10-20% of treated cells. Expression of CK2alpha or CK2alphaE75E76 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 CK2beta, the activity increased further to 15-20-fold of the controls. Transfection of CK2beta alone also increase the activity of the extracts about 2-fold. Transfection with the inactive CK2alphaA156 yielded extracts with CK2 activities not significantly different from those transfected with the empty vectors. However, co-transfection of CK2alpha or CK2alphaE75E76 with CK2alphaA156 caused a 60-70% decrease in the CK2 activity as compared to those of cells transfected with only the active CK2alpha subunits. These results can be interpreted as meaning that CK2alphaA156 is a dominant negative mutant that can compete with the other catalytic subunits for the CK2beta subunit. Addition of recombinant CK2beta to the assay system of extracts of cells transfected with catalytic subunits causes a very significant increase in their CK2 activity, demonstrating that CK2beta subunit is limiting in the extracts and that an excess of free CK2alpha has been produced in the transfected cells. Transfection of cells with CK2alphaE75E76 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 CK2alphaE75E76 to heparin increases considerably when it forms part of the holoenzyme CK2alpha2beta2.
Mol Cell Biochem 2001 Nov
PMID:The activity of CK2 in the extracts of COS-7 cells transfected with wild type and mutant subunits of protein kinase CK2. 1182 73

Protein kinase CK2, a tetramer composed of two catalytically active (CK2alpha isoforms) and two regulatory (CK2beta isoforms) subunits, is suspected to have, among others, a role in gene transcription. To identify the genes targeted by CK2, the transcriptional effect of silencing the CK2 subunit genes in Saccharomyces cerevisiae (CK2alpha isoform genes: CKA1 and CKA2; CK2beta isoform genes: CKB1 and CKB2) was examined using genome-wide expression array analysis (oligonucleotide array chips). Silencing did not influence the overwhelming majority (5801) of the over six thousand open reading frames composing the yeast genome. Cells knocked-out for both CKA1 and CKA2 and plasmid-rescued by Cka1 affected specifically at 2-fold discrimination level the transcription of 57 genes, and when rescued by Cka2, the transcription of 118 genes. In CKB1/CKB2 double knock-outs, transcription of 54 genes was specifically altered. Interestingly, aside overlaps between the gene spectra affected by CKA1 and CKA2 silencing, there were overlaps also between those influenced by CK2alpha and CK2beta isoform silencing. The data indicate a distinct role of CK2 in gene transcription control, identify specific functional differences between the two catalytic subunits in gene targeting, and reveal independent effects by the regulatory subunits.
Mol Cell Biochem 2001 Nov
PMID:Genes targeted by protein kinase CK2: a genome-wide expression array analysis in yeast. 1182 75

Little is known of how protein kinase CK2 genes are regulated, and it is unclear whether there are mechanisms of transcriptional coordination. Response elements present in the promoter sequences of the human catalytic (CK2alpha) and regulatory (CK2beta) subunit genes have been examined for the significance in transcriptional control using reporter gene assays, electrophoretic mobility shift assays, site-directed mutagenesis, ectopic protein expressions, and transcript assessments. Most strikingly, in both promoters the regions of highest transcriptional activity contain two adjoining, completely identical and conserved Ets1 response elements, and both the mutation of motifs and the overexpression of Ets1 affect significantly transcriptional activity. Also in common are Sp1 response elements that cooperate with Ets1, and Sp1 is phosphorylatable by CK2 holoenzyme but not by individual CK2alpha, the phosphorylation negatively affecting DNA binding. CK2alpha and CK2beta transcript levels and stoichiometries of mRNA species turned out quite constant in cultured cells despite progressing through various stages of proliferation and differentiation. The data seem to indicate transcriptional coordination of the human genes encoding CK2alpha and CK2beta based on an Ets1 double motif common to both genes cooperating with Sp1 motifs and amenable to negative feedback control by the gene products which, following complexation into CK2 holoenzyme, could phosphorylate Sp1 (and Ets1?) and thus downregulate transcription and contribute to the observed constant cellular CK2alpha and CK2beta transcripts situation.
Mol Cell Biochem 2001 Nov
PMID:Transcriptional coordination of the genes encoding catalytic (CK2alpha) and regulatory (CK2beta) subunits of human protein kinase CK2. 1182 74

Protein kinase CK2 is recognized as one of the key cellular signals for cell growth and proliferation. Its nuclear targeting appears to be critical to its role in these functions. In the nucleus, nuclear matrix (NM) which plays a major role in growth-related activities is a primary locus for CK2 signaling. A variety of growth stimuli evoke a rapid translocation of the CK2 to the NM whereas removal of these factors has the opposite effect. These studies, employing various experimental models of cell growth (involving different growth-stimulatory factors), have suggested that rapid shuttling of CK2 to the NM is a key feature of early growth control. By contrast, removal of growth-stimulatory factors leading to the loss of cell viability is associated with early loss of CK2 from the NM (and chromatin). This indicates that absence of CK2 from the nuclear compartment is contributory to induction of cell death via apoptosis, implying a protective role for CK2 against cell death. Here, we review the evidence that suggests that CK2 signaling in the NM is not only involved in cell growth but also in cell survival.
Mol Cell Biochem 2001 Nov
PMID:Consequences of CK2 signaling to the nuclear matrix. 1182 76

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