Phosphorylation of threonine 10 on CKBBP1/SAG/ROC2/Rbx2 by protein kinase CKII promotes the degradation of IkappaBalpha and p27Kip1

In eukaryotic cells, protein kinase CKII is required for progression through the cell division cycle. We recently reported that CKBBP1/SAG/ROC2/Rbx2 associates with the beta-subunit of CKII and is phosphorylated by purified CKII in the presence of ATP in vitro. In this report, we demonstrate that CKBBP1 is efficiently phosphorylated in vitro by purified CKII in the presence of GTP and by heparin-sensitive protein kinase in HeLa cell extract. Mutational analysis indicates that CKII phosphorylates threonine at residue 10 within CKBBP1. Furthermore, CKBBP1 is phosphorylated in vivo and threonine to alanine mutation at residue 10 abrogates the phosphorylation of CKBBP1 observed in vivo, indicating that CKII is a major kinase that is responsible for in vivo phosphorylation of CKBBP1. As compared with the wild-type CKBBP1 or CKBBP1T10E (in which threonine 10 is replaced by glutamate), overexpression of nonphosphorylatable CKBBP1 (CKBBP1T10A) results in accumulation of IkappaBalpha and p27Kip1. Experiments using proteasome inhibitor MG132 and CKII inhibitor 5,6-dichloro-1-beta-d-ribofuranosylbenzimidazole suggest that the accumulation of IkappaBalpha and p27Kip1 results primarily from the reduction of proteasomal degradation in cells expressing CKBBP1T10A, and that CKII-mediated CKBBP1 phosphorylation is required for efficient degradation of IkappaBalpha and p27Kip1. Overexpression of CKBBP1T10A in HeLa cells suppresses cell proliferation and causes accumulation of G1/G0 peak of the cell cycle. Taken together, our results indicate that CKII may control IkappaBalpha and p27Kip1 degradation and thereby G1/S phase transition through the phosphorylation of threonine 10 within CKBBP1.     

Phosphorylation of CKBBP2/CRIF1 by protein kinase CKII promotes cell proliferation

CKII plays a significant role in cell proliferation and cell cycle control. In this report, yeast two-hybrid assay and pull-down assay demonstrate that CKBBP2/CRIF1 associates with the beta subunit of CKII in vitro and in vivo. Recombinant CKBBP2/CRIF1 is phosphorylated in vitro by purified CKII and by CKII inhibitor apigenin-sensitive protein kinase in HEK293 cell extract. Phosphoamino acid analysis and mutational analysis indicate that CKII phosphorylates serine at residue 221 within CKBBP2/CRIF1. Furthermore, serine to alanine mutation at residue 221 abrogates the phosphorylation of CKBBP2/CRIF1 observed in HEK293 cell extract, indicating that CKII is a major kinase that is responsible for phosphorylation of CKBBP2/CRIF1. As compared with the wild-type CKBBP2/CRIF1 or nonphosphorylatable mutant CKBBP2(S221A) (in which the serine-221 is replaced by alanine), overexpression of CKBBP2(S221E) in COS7 cells promotes cell proliferation. Taken together, the present results suggest that CKII may be involved in cell proliferation, at least in part, through the phosphorylation of serine-221 within CKBBP2/CRIF1.     

Identification of mutations in protein kinase CKIIbeta subunit that affect its binding to ribosomal protein L41 and homodimerization

Protein kinase CKII is composed of two catalytic (alpha or alpha') subunits and two regulatory (beta) subunits. The CKIIbeta subunit is thought to mediate the tetramer formation and interact with other target proteins. However, its physiological function remains obscure. In this study, point mutants of CKIIbeta that are defective for the L41 binding were isolated by using the reverse two-hybrid system. A sequence analysis of the point mutants revealed that Asp-26, Met-52, and Met-78 of CKIIbeta are critical for L41 binding; Asn-67 (and/or Lys-139) and Met-52 are important for CKIIbeta homodimerization. Two point mutants, R75 and R83, of CKIIbeta interacted with L5, topoisomerase IIbeta, and CKBBP1/SAG, but not with the wild-type CKIIbeta. This indicates that CKIIbeta homodimerization is not a prerequisite for its binding to target proteins. These CKIIbeta point mutants may be useful in exploring the biochemical physiological functions of CKIIbeta.     

Casein kinase II phosphorylates p34cdc2 kinase in G1 phase of the HeLa cell division cycle.

The activity of p34cdc2 kinase is regulated in the phases of vertebrate cell cycle by mechanisms of phosphorylation and dephosphorylation. In this paper, we demonstrate that casein kinase II (CKII) phosphorylates p34cdc2 in vivo and in vitro at Ser39 during the G1 phase of HeLa cell division cycle. Human p34cdc2 shows a typical phosphorylation sequence motif site for CKII at Ser39 (ES39EEE). In our experiments, either p34cdc2 expressed and purified from bacteria or p34cdc2 immunoprecipitated from HeLa cells enriched in G1 by elutriation were substrates for in vitro phosphorylation by CKII. Phosphoamino acid analysis, N-chlorosuccinimide mapping, and two-dimensional tryptic mapping of p34cdc2 phosphorylated in vitro were performed to determine the phosphorylation site. A synthetic peptide spanning residues 33-50 of human p34cdc2, including the CKII site, was used to map the site. In addition, phosphorylation at Ser39 also occurs in vivo, since p34cdc2 is phosphorylated during G1 on serine, and its two-dimensional tryptic map shows two phosphopeptides that comigrate exactly with the synthetic peptides used as standard.     

Protein kinase CKII interacts with and phosphorylates the SAG protein containing ring-H2 finger motif.

To investigate the biological function of CKII, we have identified proteins that interact with the subunits of CKII using the yeast two-hybrid system. Here we report that SAG, an antioxidant protein containing Ring-H2 finger motif, is a cellular partner associating with the beta subunit of CKII. SAG does not interact with the alpha subunit of CKII. Analysis of SAG deletion mutants indicates that the Ring-H2 motif of SAG is necessary and sufficient for its binding to the beta subunit of CKII. Recombinant SAG can be phosphorylated by CKII in vitro, providing evidence that the beta subunit mediates the interaction of CKII enzyme with substrate proteins. Overlay experiment shows that SAG and the beta subunit of CKII associate directly in vitro and that CKII-mediated phosphorylation of SAG does not affect the interaction between SAG and the beta subunit of CKII. Northern blot analysis indicates that both SAG and the beta subunit of CKII were relatively rich in human heart, liver, skeletal muscle, and pancreas, but were detected in only trace amounts in brain, placenta, and lung. Our present results suggest that CKII may play a role in the regulation of SAG function.     

NAP-2: histone chaperone function and phosphorylation state through the cell cycle

We have recently cloned the human nucleosome assembly protein 2 (NAP-2). Here, we demonstrate that casein kinase 2 (CKII) from HeLa cell nuclear extracts interacts with immobilized NAP-II, and phosphorylates both NAP-2 and nucleosome assembly protein 1 (NAP-1) in vitro. Furthermore, NAP-1 and NAP-2 phosphorylation in crude HeLa cell extracts is abolished by heparin, a specific inhibitor of CKII. Addition of core histones can stimulate phosphorylation of NAP-1 and NAP-2 by CKII. NAP-2 is also a phosphoprotein in vivo. The protein is phosphorylated at the G0/G1 boundary but it is not phosphorylated in S-phase. Here, we show that NAP-2 is a histone chaperone throughout the cell cycle and that its cell-cycle distribution might be governed by its phosphorylation status. Phosphorylated NAP-2 remains in the cytoplasm in a complex with histones during the G0/G1 transition, whereas its dephosphorylation triggers its transport into the nucleus, at the G1/S-boundary, with the histone cargo, suggesting that binding to histones does not depend on phosphorylation status. Finally, indirect immunofluorescence shows that NAP-2 is present during metaphase of HeLa and COS cells, and its localization is distinct from metaphase chromosomes.     

Stimulation of human DNA topoisomerase II activity by its direct association with the beta subunit of protein kinase CKII

DNA topoisomerase II copurifies with and is phosphorylated by protein kinase CKII. In this study, a yeast two-hybrid system was used to investigate the interaction between human topoisomerase II isozymes and CKII subunits. The two-hybrid test clearly showed that both topoisomerase IIalpha and IIbeta interact with the CKIIbeta, but not the CKIIalpha subunit. The two-hybrid test also demonstrated that topoisomerase IIbeta residues 1099-1263 and topoisomerase IIalpha residues 1078-1182 mediate the interaction with the CKIIbeta subunit, providing evidence that the leucine zipper motif and the major CKII-dependent phosphorylation sites of topoisomerase II are unnecessary for its physical binding to CKIIbeta. Furthermore, a DNA relaxation assay demonstrated that the CKII subunit enhances topoisomerase II activity by physical interaction with topoisomerase II.     

Regulation of protein kinase CKII by direct interaction with the C-terminal region of p47(phox)

Protein kinase CKII is a Ser/Thr kinase which is involved in many proliferation-related processes in the cell. p47(phox) is a component of the leukocyte NADPH oxidase, which is an important element of host defense against microbial infection. In this study, we demonstrate that a truncated form of the p47(phox) lacking its N-terminal region (p47(phox)/SH3-C), but not a truncated form of the p47(phox) lacking its C-terminal region (p47(phox)/N-SH3), undergoes better phosphorylation by CKII in the presence of arachidonic acid. The yeast two-hybrid test and the glutathione S-transferase (GST) pull-down assay showed that p47(phox) interacts specifically with the regulatory beta subunit (CKIIbeta), but not with the catalytic alpha subunit (CKIIalpha) of the tetrameric CKII holoenzyme. The binding of p47(phox) to CKIIbeta requires the C-terminal region of p47(phox) and is completely abolished by addition of spermine, indicating that a highly basic region in the C-terminal region of p47(phox) contributes to binding to CKIIbeta. In addition, p47(phox) stimulates the catalytic activity of CKII holoenzyme; this stimulation also requires the C-terminal region of p47(phox). Coimmunoprecipitation experiments showed that CKII holoenzyme interacts with p47(phox) in human neutrophils. Taken together, the present data indicate that the C-terminal region of p47(phox) plays a significant role in the arachidonic acid-dependent phosphorylation of p47(phox) by CKII and that the same region of p47(phox) associates directly with CKIIbeta and can modulate the catalytic activity of CKII holoenzyme.     

Protein kinase CK2 phosphorylates the cell cycle regulatory protein Geminin

Geminin contributes to cell cycle regulation by a timely inhibition of Cdt1p, the loading factor required for the assembly of pre-replication complexes. Geminin is expressed during S and G2 phase of the HeLa cell cycle and phosphorylated soon after its synthesis. We show here that Geminin is an excellent substrate for protein kinase CK2 in vitro; and that the highly specific CK2 inhibitor tetrabromobenzotriazole (TBB) blocks the phosphorylation of Geminin in HeLa protein extracts and HeLa cells in vivo. The sites of CK2 phosphorylation are located in the carboxyterminal region of Geminin, which carries several consensus sequence motifs for CK2. We also show that a minor phosphorylating activity in protein extracts can be attributed to glycogen synthase kinase 3 (GSK3), which most likely targets a central peptide in Geminin. Treatment of HeLa cells with TBB does not interfere with the ability of Geminin to interact with the loading factor Cdt1.     

A positive feedback loop between protein kinase CKII and Cdc37 promotes the activity of multiple protein kinases

We report here the identification of CDC37, which encodes a putative Hsp90 co-chaperone, as a multicopy suppressor of a temperature-sensitive allele (cka2-13(ts)) of the CKA2 gene encoding the alpha' catalytic subunit of protein kinase CKII. Unlike wild-type cells, cka2-13 cells were sensitive to the Hsp90-specific inhibitor geldanamycin, and this sensitivity was suppressed by overexpression of either Hsp90 or Cdc37. However, only CDC37 was capable of suppressing the temperature sensitivity of a cka2-13 strain, implying that Cdc37 is the limiting component. Immunoprecipitation of metabolically labeled Cdc37 from wild-type versus cka2-13 strains revealed that Cdc37 is a physiological substrate of CKII, and Ser-14 and/or Ser-17 were identified as the most likely sites of CKII phosphorylation in vivo. A cdc37-S14,17A strain lacking these phosphorylation sites exhibited severe growth and morphological defects that were partially reversed in a cdc37-S14,17E strain. Reduced CKII activity was observed in both cdc37-S14A and cdc37-S17A mutants at 37 degrees C, and cdc37-S14A or cdc37-S14,17A overexpression was incapable of protecting cka2-13 mutants on media containing geldanamycin. Additionally, CKII activity was elevated in cells arrested at the G(1) and G(2)/M phases of the cell cycle, the same phases during which Cdc37 function is essential. Collectively, these data define a positive feedback loop between CKII and Cdc37. Additional genetic assays demonstrate that this CKII/Cdc37 interaction positively regulates the activity of multiple protein kinases in addition to CKII.     

Immunocytochemical localization of casein kinase II during interphase and mitosis

We have developed specific antibodies to synthetic peptide antigens that react with the individual subunits of casein kinase II (CKII). Using these antibodies, we studied the localization of CKII in asynchronous HeLa cells by immunofluorescence and immunoelectron microscopy. Further studies were done on HeLa cells arrested at the G1/S transition by hydroxyurea treatment. Our results indicate that the CKII alpha and beta subunits are localized in the cytoplasm during interphase and are distributed throughout the cell during mitosis. Further electron microscopic investigation revealed that CKII alpha subunit is associated with spindle fibers during metaphase and anaphase. In contrast, the CKII alpha' subunit is localized in the nucleus during G1 and in the cytoplasm during S. Taken together, our results suggest that CKII may play significant roles in cell division control by shifting its localization between the cytoplasm and nucleus.     

Identification of a G(2) arrest domain in the E1 wedge E4 protein of human papillomavirus type 16

Human papillomavirus type 16 (HPV16) is the most common cause of cervical carcinoma. Cervical cancer develops from low-grade lesions that support the productive stages of the virus life cycle. The 16E1 wedge E4 protein is abundantly expressed in such lesions and can be detected in cells supporting vegetative viral genome amplification. Using an inducible mammalian expression system, we have shown that 16E1 wedge E4 arrests HeLa cervical epithelial cells in G(2). 16E1 wedge E4 also caused a G(2) arrest in SiHa, Saos-2 and Saccharomyces pombe cells and, as with HeLa cells, was found in the cytoplasm. However, whereas 16E1 wedge E4 is found on the keratin networks in HeLa and SiHa cells, in Saos-2 and S. pombe cells that lack keratins, 16E1 wedge E4 had a punctate distribution. Mutagenesis studies revealed a proline-rich region between amino acids 17 and 45 of 16E1 wedge E4 to be important for arrest. This region, which we have termed the "arrest domain," contains a putative nuclear localization signal, a cyclin-binding motif, and a single cyclin-dependent kinase (Cdk) phosphorylation site. A single point mutation in the putative Cdk phosphorylation site (T23A) abolished 16E1 wedge E4-mediated G(2) arrest. Arrest did not involve proteins regulating the phosphorylation state of Cdc2 and does not appear to involve the activation of the DNA damage or incomplete replication checkpoint. G(2) arrest was also mediated by the E1 wedge E4 protein of HPV11, a low-risk mucosal HPV type that also causes cervical lesions. The E1 wedge E4 protein of HPV1, which is more distantly related to that of HPV16, did not cause G(2) arrest. We conclude that, like other papillomavirus proteins, 16E1 wedge E4 affects cell cycle progression and that it targets a conserved component of the cell cycle machinery.     

E1A induces phosphorylation of the retinoblastoma protein independently of direct physical association between the E1A and retinoblastoma products.

We have studied the initial effects of adenovirus E1A expression on the retinoblastoma (RB) gene product in normal quiescent cells. Although binding of the E1A products to pRB could, in theory, make pRB phosphorylation unnecessary for cell cycle progression, we have found that the 12S wild-type E1A product is capable of inducing phosphorylation of pRB in normal quiescent cells. The induction of pRB phosphorylation correlates with E1A-mediated induction of p34cdc2 expression and kinase activity, consistent with the possibility that p34cdc2 is a pRB kinase. Expression of simian virus 40 T antigen induces similar effects. Induction of pRB phosphorylation is independent of the pRB binding activity of the E1A products; E1A domain 2 mutants do not bind detectable levels of pRB but remain competent to induce pRB phosphorylation and to activate cdc2 protein kinase expression and activity. Although the kinetics of induction are slower, domain 2 mutants induce wild-type levels of pRB phosphorylation and host cell DNA synthesis and yet fail to induce cell proliferation. These results imply that direct physical interaction between the RB and E1A products does not play a required role in the early stages of E1A-mediated cell cycle induction and that pRB phosphorylation is not, of itself, sufficient to allow quiescent cells to divide. These results suggest that the E1A products do not need to bind pRB in order to stimulate resting cells to enter the cell cycle. Indeed, a more important role of the RB binding activity of the E1A products may be to prevent dividing cells from returning to G0.     

Sequencing of full-length cDNA encoding the alpha and beta subunits of human casein kinase II from human platelets and megakaryocytic cells. Expression of the casein kinase IIalpha intronless gene in a megakaryocytic cell line

Casein kinase II (CKII) is a ubiquitous protein kinase composed of two subunits, alpha and beta, that can use both ATP and GTP as phosphoryl donors. Two genes located on two separate chromosomes were identified for CKIIalpha: one on chromosome 20 band 13 with an approximate size of 20 kb and a second on chromosome 11 band 15.5-p15.4 that is the same size as the cDNA of locus 20 kb (1.2 kb) and does not contain any introns. The two genes differ in four amino acids. Recently, it has been demonstrated that a membrane-associated platelet-derived CKII phosphorylates coagulation factor Va. The mRNA encoding the platelet CKII was isolated from fresh human platelets, and the corresponding cDNAs encoding the alpha and beta subunits of human platelet CKII were produced and sequenced. The cDNA for platelet CKIIalpha was found to be 99.7% homologous to the CKIIalpha intronless gene, having the same characteristic amino acid residues at positions 128, 256, 287, and 351. However, the cDNA of platelet CKIIalpha has a different amino acid at position 236 (Arg --> His), which is not found in the intronless gene. The cDNA of the CKIIbeta subunit was completely identical with the sequence of the CKIIbeta subunit isolated from other tissues. Since platelets arise from megakaryocytes, mRNA was isolated from the megakaryocytic cell line MEG-01 and the cDNA for CKIIalpha was cloned and sequenced. The cDNA was found to be identical to the intronless gene found in platelets. We have also investigated the expression of the intronless gene in several other cell lines. Expression of the intronless gene was only found in cell line MEG-01. Our data demonstrate expression of the CKIIalpha intronless gene in megakaryocytes and platelets.     

Phosphorylation and cell cycle-dependent regulation of Na+/H+ exchanger regulatory factor-1 by Cdc2 kinase

Na(+)/H(+) exchanger regulatory factor (NHERF)-1 is a PDZ domain-containing adaptor protein known to bind to various receptors, channels, cytoskeletal elements, and cytoplasmic signaling proteins. We report here that the phosphorylation state of NHERF-1 is profoundly regulated by the cell cycle: NHERF-1 in HeLa cells is hyperphosphorylated in mitosis phase and much less phosphorylated at other points of the cell cycle. This mitosis phase-dependent phosphorylation of NHERF-1 could be blocked by roscovitine, consistent with phosphorylation by cyclin-dependent kinases. In vitro studies with purified NHERF-1 fusion proteins and purified kinases revealed that NHERF-1 was robustly phosphorylated by the cyclin-dependent kinase Cdc2. In contrast, the NHERF-1 relative NHERF-2 was not phosphorylated at all by Cdc2. NHERF-1 possesses two serines (Ser(279) and Ser(301)) that conform to the SPX(K/R) motif preferred for phosphorylation by Cdc2. Mutation of either of these serines reduced Cdc2-mediated phosphorylation of NHERF-1 in vitro, and mutation of both residues together completely abolished Cdc2-mediated phosphorylation. When the S279A/S301A NHERF-1 mutant was expressed in cells, it failed to exhibit the mitosis phase-dependent phosphorylation observed with wild-type NHERF-1. Mutation of both Ser(279) and Ser(301) to aspartate, to mimic Cdc2 phosphorylation of NHERF-1, resulted in a NHERF-1 mutant with a markedly impaired ability to oligomerize in vitro. Similarly, endogenous NHERF-1 from lysates of mitosis phase HeLa cells exhibited a markedly reduced ability to oligomerize relative to endogenous NHERF-1 from lysates of interphase HeLa cells. Mitosis phase NHERF-1 furthermore exhibited the ability to associate with Pin1, a WW domain-containing peptidylprolyl isomerase that does not detectably bind to NHERF-1 in interphase lysates. The association of NHERF-1 with Pin1 facilitated dephosphorylation of NHERF-1, as shown in experiments in which cellular Pin1 activity was blocked by the selective inhibitor juglone. These data reveal that cellular NHERF-1 is phosphorylated during mitosis phase by Cdc2 at Ser(279) and Ser(301) and that this phosphorylation regulates NHERF-1 oligomerization and association with Pin1.