Ets1 is a common element in directing transcription of the alpha and beta genes of human protein kinase CK2.

Protein kinase CK2 is a conserved and vital Ser/Thr phosphotransferase with various links to malignant diseases, occurring as a tetramer composed of two catalytically active (CK2alpha and/or CK2alpha') and two regulatory subunits (CK2beta). There is balanced availability of CK2alpha and CK2beta transcripts in proliferating and differentiating cultured cells. Examination of the human CK2beta gene for transcriptionally active regions by systematic deletions and reporter gene assays indicates strong promoter activity at positions -42 to 14 and 12 to 72 containing transcription start sites 1 and 2 of the gene (positions +1 and 33), respectively, an upstream and a downstream enhancer activity at positions -241 to -168 and 123 to 677, respectively, and silencer activity at positions -241 to -261. Of the various transcription factor binding motifs present in those regions, Ets1 and CAAT-related motifs turned out to be of particular importance, Ets1 for promoter activation and CAAT-related motifs for enhancer activation. In addition, there are contributions by Sp1. Most strikingly, the Ets1 region representing two adjoining consensus motifs also occurs with complete identity in the recently characterized promoter of the CK2alpha gene [Krehan, A., Ansuini, H., Böcher, O., Grein, S., Wirkner, U. & Pyerin, W. (2001) J. Biol. Chem. 275, 18327-18336], and affects comparably, when assayed in parallel, the promoters of both CK2 genes, both by motif mutations and by Ets1 overexpression. The data strongly support the hypothesis that Ets1 acts as a common regulatory element of the CK2alpha and CK2beta genes involved in directing coordinate transcription and contributing to the balanced availability of transcripts.

Transcription factors ets1, NF-kappa B, and Sp1 are major determinants of the promoter activity of the human protein kinase CK2alpha gene.

CK2alpha is one of two isoforms of protein kinase CK2, a highly conserved, ubiquitous, and vital phosphotransferase whose expression is kept at constant cellular levels and whose dysregulated expression has been linked to malignant diseases. The upstream sequence of the gene coding for human CK2alpha (CSNK1A1, chromosomal location 20p13) has been examined for promoter location and transcription factor interactions using reporter gene assays (luciferase; HeLa cells), site-directed mutagenesis, electrophoretic mobility shift assays, super-shifts, UV cross-linking, Western blotting, and DNA affinity chromatography. Highest promoter activity has been found in a region comprising positions -9 to 46. Factors Sp1, Ets-1, and NF-kappaB have been identified as interaction partners and, by mutation of individual sites and simultaneous mutations of two or more sites, shown to cross-talk to each other. At least two of the factors (Sp1; NF-kappaB) were susceptible to phosphorylation by CK2 holoenzyme, a tetramer composed of two CK2alpha and two regulatory CK2beta proteins, but not by individual CK2alpha. Because the phosphorylation decreases promoter binding and repeated immunoprecipitation reveals presence of "free" CK2beta in cell extracts, it is tempting to speculate that the gene product CK2alpha might readily form CK2 holoenzyme and feed back onto gene transcription. The data represent the first promoter control analysis of a mammalian CK2alpha gene and provide a hypothesis of how the constant expression level of CK2alpha may be achieved.

Casein kinase 2 binds and phosphorylates the nucleosome assembly protein-1 (NAP1) in Drosophila melanogaster.

The nucleosome assembly protein-1 (NAP1) was originally identified in HeLa cells as a factor facilitating the in vitro assembly of nucleosomes. However, in yeast cells NAP1 is required in the control of mitotic events induced by the Clb2/p34(CDC28). Here, we show that Drosophila NAP1 is a phosphoprotein that is associated with a kinase able to phosphorylate NAP1. By using an in-gel kinase assay we found that this kinase displays a molecular mass of 38 kDa. Following purification and peptide microsequencing, we identified the kinase phosphorylating NAP1 as the alpha subunit of casein kinase 2 (CK2). With the help of a series of NAP1 segments and synthetic peptides, we assigned the CK2 phosphorylation sites to residues Ser118, Thr120, and Ser284. Interestingly, Ser118 and Thr120 are located within a PEST domain, while Ser284 is adjacent to the nuclear localization signal. Substitution of the identified phosphoresidues by alanine was found to reduce considerably the ability of CK2 to phosphorylate NAP1. The enhanced ability of CK2 to phosphorylate phosphatase-treated NAP1 extracted from Drosophila embryos and the similar tryptic phospho-peptide pattern of in vivo labelled NAP1 and in vitro labelled NAP1 with CK2 indicate that NAP1 is a natural substrate of CK2. Further analysis revealed that both CK2alpha and beta subunits are associated with NAP1 but we found that only the catalytic alpha subunit establishes direct contact with NAP1 on two distinct domains of this protein. The location of CK2 phosphorylation sites in NAP1 suggests that their phosphorylation can contribute to a PEST-mediated protein degradation of NAP1 and the translocation of NAP1 between cytoplasm and nucleus.

Heterogeneous nuclear ribonucleoprotein A2 interacts with protein kinase CK2.

The catalytic subunit of protein kinase CK2 (CK2alpha) was found associated with heterogeneous nuclear ribonucleoprotein particles (hnRNPs) that contain the core proteins A2 and C1-C2. High levels of CK2 activity were also detected in these complexes. Phosphopeptide patterns of hnRNP A2 phosphorylated in vivo and in vitro by protein kinase CK2 were similar, suggesting that this kinase can phosphorylate hnRNPA2 in vivo. Binding experiments using human recombinant hnRNP A2, free human recombinant CK2alpha or CK2beta subunits, reconstituted CK2 holoenzyme and purified native rat liver CK2 indicated that hnRNP A2 associated with both catalytic and regulatory CK2 subunits, and that the interaction was independent of the presence of RNA. However, the capability of hnRNP A2 to bind to CK2 holoenzyme was lower than its binding to the isolated subunits. These data indicate that the association of CK2alpha with CK2beta interferes with the subsequent binding of hnRNP A2. HnRNP A2 inhibited the autophosphorylation of CK2beta. This effect was stronger with reconstituted human recombinant CK2 than with purified native rat liver CK2.

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 beta (beta55-70) and 65-80 of subunit alpha (alpha65-80). This has been supported by crosslinking of subunits with peptides alpha65-80 and beta55-70, by binding of subunits to immobilized peptides, and by the hindrance of coprecipitation with peptide-raised antibodies (anti-alpha65-80; anti-beta55-70). Functionally, beta55-70 is a negative regulatory region for the kinase activity of subunit alpha. The opposite, stimulatory property of subunit beta has been assigned to its C-terminal part. Subdivision of peptide beta155-181, that has stimulatory effect, into overlapping peptides and assaying for alpha binding and binding competition revealed a tight physical contact at beta162-175. 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 alpha as indicated by crosslinking and peptide competition. The crosslinking data also confirm a beta-beta contact in CK2 holoenzyme. Effects by non-ionic detergents show hydrophobic interactions to play an important role in catalytic activity adjustment.

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, CK2alpha' was more resistant to these proteases than CK2alpha. When these proteases were assayed on the reconstituted (alpha2beta2 holoenzyme), a 37 kDa alpha-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 CK2alpha deletion mutants showed that m-calpain and the 20 S proteasome acted on the C-terminus end of CK2alpha. 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.

Identification of structural elements of subunit beta of human protein kinase CK2 participating in tight physical alpha-beta intersubunit contacts directly adjacent to a surface-oriented region.

Sites essential for tight physical intersubunit interaction in protein kinase CK2, a tetramer composed of two catalytic (alpha and/or alpha') and two regulatory subunits (beta), have been assigned to the C-terminal part of subunit beta. Mutational analysis suggests region 171-181 of beta to be one of these but this is not consistent with the observation of coprecipitation of catalytic subunits by antibodies directed specifically to this beta segment which indicates that this region is accessible to antibodies even if the beta subunit is associated with the alpha subunit. In an attempt to clarify the apparent contradiction, we have subdivided beta-(155-181)-peptide, which includes the fragment of beta and that both binds to catalytic subunits and stimulates kinase activity, into six more or less overlapping peptides with a length of 9-16 amino acid residues and performed peptide competition and a subunit binding assays. The kinase-stimulating effect of beta-(155-181)-peptide was counteracted significantly by beta-(162-175)-peptide while the others had less or no effect. In an ELISA assay with the peptides covalently bound to wells via a C10 spacer arm, binding of a occurred besides beta-(155-181)-peptide only with beta-(162-175)-peptide and beta-(165-175)-peptide. The data provide the first evidence that the contact and the stimulation competences of subunit beta represent separable functions and suggest further that a tight physical contact to catalytic subunits is located at position 162-175 consisting of a hydrophobic stretch (position 162-171) and a hydrophilic binding motif, PEY (position 172-174), with the adjoining downstream part allowing for surface exposure and antibody binding. The presence of several Pro residues within that region might relate to the structural basis for both the alpha-beta interaction and the surface orientation.

Infrared properties of chemical-vapor deposition polycrystalline diamond windows.

Low-resolution transmittance and reflectance spectra of high-quality chemical-vapor deposition (CVD) diamond windows were measured in the infrared in the 2.5-500-mum wavelength range (20-4000 cm(-1)). High-resolution measurements on a window with nearly parallel surfaces show well defined interference fringes at low frequencies. By standard procedures the optical constants n and k of CVD diamond were determined, for the first time to the author's knowledge, in the far-infrared region. It is shown that a window with a large wedge angle, close to 1 degrees , does not produce appreciable interference fringes. Modeling of these results confirms that interference fringes can be avoided by use of properly wedged CVD diamond windows. This result is of considerable relevance to the use of CVD diamond windows in spectroscopic applications for which fringe suppression is a major requirement.

Interaction sites between catalytic and regulatory subunits in human protein kinase CK2 holoenzymes as indicated by chemical cross-linking and immunological investigations.

Protein kinase CK2, a heterotetramer composed of two catalytic subunits (alpha and/or alpha') and two regulatory subunits (beta), has been examined for intermolecular contact sites by methods that allow investigation of the native, unaltered proteins. Antibodies were raised against a series of 11 subunit peptides, affinity purified, and ensured for site specific binding by peptide competition. Chemical cross-linking of CK2 subunits with a hydrophilic carbodiimide and analysis of fused subunits and of CNBr-digested fusion products by immunoblotting with the sequence specific antibodies identified a tight interaction between positions beta55-70 and alpha65-80 (alpha'66-81) of subunits beta and alpha (alpha'), respectively. This was corroborated by cross-linking of subunits with peptides alpha65-80 and beta55-70 by a peptide-based enzyme-linked immunosorbent assay in which peptides bound to wells via C-10 spacer arms are probed for complexing individual subunits and immunoprecipitation with antibodies anti-alpha65-80 and anti-beta55-70, resulting in precipitation but not coprecipitation of subunits. This alpha-beta (alpha'-beta) interaction site obviously is also of functional importance since subunits with attached antibodies cannot reconstitute to the fully active holoenzyme. Indeed, sites beta55-70 and alpha65-80 (alpha'66-81) correspond to an acidic (beta) and a basic (alpha or alpha') domain involved in activity and stability control and in substrate and cosubstrate binding (kinase domain II/III), respectively. By contrast, a number of suspected contact sites were found to be rather loose and not essential for enzyme control as concluded from precipitation behavior of respective antibodies and the toleration of attached antibodies when active holoenzymes were being constituted. At subunit beta, these include the terminal positions beta2-14 and beta204-213, the positions beta97-105 and beta140-156, and, surprisingly, also beta171-186 which have been shown by deletion mutation and peptide replacement studies to represent a positively affecting interaction site. At subunits alpha and alpha', these are the C-terminal positions alpha329 -343 and alpha'336-350. Binding of antibodies to the positions alpha15-27 (alpha'16-28) and position alpha151-166(alpha'152-167), on the other hand, inhibits activity.

Recombinant human casein kinase II. A study with the complete set of subunits (alpha, alpha' and beta), site-directed autophosphorylation mutants and a bicistronically expressed holoenzyme.

Human casein kinase II (CKII) is a ubiquitous and multipotential Ser/Thr kinase involved in the regulation of cell growth and differentiation. Biochemically, two characteristics are particularly notable; first, the tetrameric composition of two catalytic subunits (alpha and/or alpha') and two regulatory subunits (beta); second, the autophosphorylation of the holoenzyme at the N-terminus of CKII beta, suspected to be involved in tuning of the kinase activity. Whether CKII alpha and CKII alpha' reconstitute comparably with CKII beta to form holoenzyme is unclear. For a systematic investigation, the complete set of recombinant CKII subunits and of autophosphorylation mutants of CKII beta were expressed in Escherichia coli and comparative reconstitutions carried out. At 1:1 molar ratio, CKII beta stimulated both catalytic subunits roughly fivefold with phosvitin as a substrate. The level of activity reached with both of the reconstituted CKII isoforms was of the same order of magnitude as that of holoenzyme isolated from human placenta. It was also similar to a recombinant alpha 2 beta 2 holoenzyme whose expression had been attained in E. coli with a bicistronic construct containing the coding regions of CKII beta and CKII alpha in a tandem arrangement. Both Ser2 and Ser3 were identified as the autophosphorylation sites; replacement of one of these with Ala by oligonucleotide-mediated site-directed mutagenesis influenced only the extent of CKII beta autophosphorylation, replacement of both resulted in a loss of autophosphorylation. Despite these differences, the stimulatory effect of all the CKII beta mutants was comparable both to each other and to that of wild-type CKII beta. This was also obtained when substrates other than phosvitin were employed such as tubulin, or upstream-binding factor (UBF). However, the degree of stimulation was substrate specific and ranged from 2-5-fold with no major differences between CKII alpha and CKII alpha' stimulation. Calmodulin phosphorylation by both CKII alpha and CKII alpha' was decreased similarly by CKII beta and the CKII beta mutants. Proteins such as cAMP-responsive-element-binding protein (CREB), HPV16 E7 or Jun were not phosphorylated by either catalytic subunit but became substrates of both in the presence of CKII beta or CKII beta mutants. The data suggest that CKII alpha and CKII alpha' form similar CKII holoenzymes and that the tuning of holoenzyme activity is independent of the autophosphorylation status of CKII beta.