Distinctive features of plant protein kinase CK2

In plants, protein kinase CK2 is involved in different processes that control many aspects of metabolism and development. In mammals and yeast the enzyme is a heterotretamer composed of two types of subunits. During years the subunit composition of the maize protein kinase CK2 enzyme has been a source of controversy. We have recently characterized the maize holoenzyme subunits. Our results show that multiple catalytic and regulatory subunits are expressed in maize and are able to specifically interact with other and subunits suggesting a high level of heterogeneity in the typical heterotetrameric structure. Here, we summarize data available on plant CK2 enzymes, in order to clarify the distinctive features and functions of plant protein kinase CK2.     

In situ study of c-myc protein expression during avian development

The distribution of the c-myc protein was studied in the developing embryo from the two-somite stage to embryonic day 17 (E17). A triple labelling method was used, with a polyclonal serum recognizing the human and avian c-myc proteins as the first marker followed by Hoechst 33258 for nuclear staining and the monoclonal antibody 13F4 which reveals the avian myogenic lineage. In situ hybridization was carried out at three selected stages (E3, E6 and E8), in order to compare the distribution of myc mRNA and myc protein. The c-myc protein signal was barely detectable in blastodisc nuclei during the period of somite formation, after which it became ubiquitous in the embryonic body until E4. Myotomal cell nuclei displayed a strong signal until their organization into premuscular masses. On day 4, the level of c-myc protein decreased in all embryonic tissues. By doubling the antibody titre and amplifying the signal by means of the streptavidin-biotin method, c-myc could still be detected in nuclei of defined groups of cells. Such was the case in some mesenchyme-derived tissues at critical periods of organogenesis, for instance in prechondrogenic condensations or hemopoietic cell foci at E6, the latter becoming negative at E9. The heart ventricle displayed a patch-work of positive and negative nuclei from E6 to E10. A myc signal restricted to the quail species was found in the wall of the carotid arteries. Cell nuclei in the nervous system displayed a detectable signal which became restricted to postmitotic neurones. In the ectoderm, the c-myc protein was generally not present after E4, except in presumptive feather buds at the time of epitheliomesenchymal interactions. Endodermal cells (such as hepatocytes, oesophageal and tracheal epithelia) did not express detectable levels of c-myc at any time. Our results reveal a time- and tissue-specific expression of c-myc during avian development. It is noteworthy that the expression of the c-myc protein often appears dissociated from cell proliferation as shown by the absence of the signal in endodermal cells at E3-E13 as well as its presence in postmitotic neurones. Finally, although RNA and protein are simultaneously detected in some structures such as presumptive feather buds, their expression is dissociated in endodermal tissues, notably hepatocytes, where in situ hybridization detects a large number of RNA copies with no detectable protein signal.     

Transient increase of a protein kinase activity identified to CK2 during sea urchin development

Using GST-EF-1 delta as an exogenous substrate, and EF-1 delta kinase activity was shown to increase transiently during early development of sea urchin embryos. The basal activity of EF-1 delta kinase in unfertilized eggs was 150 fmoles/min/mg protein. The activity began to increase 10 h after fertilization and reached its maximum level (8.4 x basal) at 24 h. The activity then declined to twice the basal value at 72 h post-fertilization. The EF-1 delta kinase activity was identified to a CK2-type enzyme on the basis of its substrate specificity for EF-1 delta, crude casein and beta casein, its inhibition by heparin, DRB, 2,3-bisphosphoglycerate, and its stimulation by spermine, spermidine, and polylysin. Furthermore, the activity was inhibited by the synthetic peptide RRREEETEEE specific for CK2. DRB (200 microM) and 2,3-bisphosphoglycerate (2.5 mM) blocked or delayed the transition from blastula to gastrula of the embryos, suggesting a role for the kinase in early development.     

蛋白激酶CK2的研究进展

蛋白激酶CK2是一种真核细胞中普遍存在的信使非依赖性丝／苏氨酸蛋白激酶。近年来,对蛋白激酶CK2的研究也取得了一些重要进展,尤其是蛋白激酶CK2的结构及其作用底物,蛋白激酶CK2与肿瘤及细胞凋亡的关系,越来越引起人们的关注。     

Alpha 2-macroglobulin gene expression during rat development studied by in situ hybridization.

The sites of alpha 2-macroglobulin mRNA synthesis during rat development have been localized by in situ hybridization using a rat alpha 2-macroglobulin cDNA probe. Fetal liver was found to be the major site of alpha 2-macroglobulin mRNA synthesis. In addition, alpha 2-macroglobulin mRNA was detected in brain, spinal cord and eye. Alpha 2-Macroglobulin mRNA was quantitated by use of a sensitive RNAse protection assay. Maximal levels of alpha 2-macroglobulin mRNA were found in fetal livers shortly before birth. A rapid decline of alpha 2-macroglobulin mRNA occurred within 1 day after parturition. A similar time course, although at an approximately 20-fold lower level, was observed for alpha 2-macroglobulin mRNA in livers of pregnant rats. Alpha 2-Macroglobulin mRNA could also be detected in placenta. The levels were comparable to those found in maternal livers.     

A role for protein kinase CK2 in plant development: evidence obtained using a dominant-negative mutant

Protein kinase CK2 is an evolutionary conserved Ser/Thr phosphotransferase composed of two distinct subunits, α (catalytic) and β (regulatory), that combine to form a tetrameric complex. Plant genomes contain multiple genes for each subunit, the expression of which gives rise to different active holoenzymes. In order to study the effects of loss of function of CK2 on plant development, we have undertaken a dominant-negative mutant approach. We generated an inactive catalytic subunit by site-directed mutagenesis of an essential lysine residue. The mutated open reading frame was cloned downstream of an inducible promoter, and stably transformed Arabidopsis thaliana plants and tobacco BY2 cells were isolated. Continuous expression of the CK2 kinase-inactive subunit did not prevent seed germination, but seedlings exhibited a strong phenotype, affecting chloroplast development, cotyledon expansion, and root and shoot growth. Prolonged induction of the transgene was lethal. Moreover, dark-germinated seedlings exhibited an apparent de-etiolated phenotype that was not caused by disruption of the light-signalling pathways. Short-term induction of the CK2 kinase-inactive subunit allowed plant survival, but root growth and lateral root formation were significantly affected. The expression pattern of CYCB1;1::GFP in the root meristems of mutant plants demonstrated an important decrease of mitotic activity, and expression of the CK2 kinase-inactive subunit in stably transformed BY2 cells provoked perturbation of the G1/S and G2 phases of the cell cycle. Our results are consistent with a model in which CK2 plays a key role in cell division and cell expansion, with compelling effects on Arabidopsis development.     

原位杂交检测microRNA-205在乳腺癌中的表达

目的探讨microRNA-205表达与乳腺恶性病变的关系。方法乳腺疾病及癌组织芯片原位杂交分析microRNA-205的表达;实时定量RT-PCR方法检测正常乳腺细胞株、恶性程度不同的乳腺癌细胞株中microRNA-205的表达。结果原位杂交分析显示,36例正常与良性乳腺病变中,33例(91.67%)表达阳性;36例乳腺癌中,23例(63.89%)表达阳性。microRNA-205的表达在乳腺正常与良性病变中的表达较恶性病变中高且有统计学差异(P=0.011),但与乳腺癌TNM分期、临床分期无关(P0.05)。实时定量RT-PCR结果显示,四个高度恶性乳腺癌细胞株(MDA-MB-231、HS578T、BT549和SUM159PT)中microRNA-205的表达较永生化正常乳腺上皮细胞株MCF10A和四个低度恶性细胞株(MDA-MB-468、T-47D、ZR-75-1和SKBR3)中为低(P0.05)。结论原位杂交适用于microRNA-205的表达分析;组织芯片标本原位杂交与乳腺细胞株实时定量RT-PCR分析结果提示,microRNA-205可能参与了乳腺癌的发生、发展,并随着乳腺癌的演进呈下调趋势。     

Prealbumin gene expression during mouse development studied by in situ hybridization

Localization of prealbumin mRNA in tissues from mice at various stages of gestation was investigated using in situ hybridization procedures. Prealbumin mRNA was detected as early as the 10th day of gestation. It was specifically localized in endodermal cells of the visceral yolk sac, tela choroidea, and hepatocytes. In the adult mice, prealbumin mRNA was localized in the hepatocytes and choroid plexus epithelial cells. These observations indicate that synthesis of prealbumin mRNA is initiated in several different types of cells at early stages of fetal development.     

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.     

Cellular regulators of protein kinase CK2

Protein phosphorylation is a key regulatory post-translational modification and is involved in the control of many cellular processes. Protein kinase CK2, formerly known as casein kinase II, which is a ubiquitous and highly conserved protein serine/threonine kinase, plays a central role in the control of a variety of pathways in cell proliferation, transformation, apoptosis and senescence. An understanding of the regulation of such a central protein kinase would greatly help our comprehension of the regulation of many pathways in cellular regulation. A number of reviews have addressed the detection, the development, and the characterization of inhibitors of CK2. The present review focuses on possible natural regulators of CK2, i.e. proteins and other cellular factors that bind to CK2 and thereby regulate its activity.     

Candida albicans protein kinase CK2 governs virulence during oropharyngeal candidiasis

To identify Candida albicans genes whose proteins are necessary for host cell interactions and virulence, a collection of C. albicans insertion mutants was screened for strains with reduced capacity to damage endothelial cells in vitro. This screen identified CKA2. CKA2 and its homologue CKA1 encode the catalytic subunits of the protein kinase CK2. cka2delta/cka2delta strains of C. albicans were constructed and found to have significantly reduced capacity to damage both endothelial cells and an oral epithelial cell line in vitro. Although these strains invaded endothelial cells similarly to the wild-type strain, they were defective in oral epithelial cell invasion. They were also hypersusceptible to hydrogen peroxide, but not to high salt or to cell wall damaging agents. A cka1delta/cka1delta mutant caused normal damage to both endothelial cells and oral epithelial cells, and it was not hypersusceptible to hydrogen peroxide. However, overexpression of CKA1 in a cka2delta/cka2delta strain restored wild-type phenotype. Although the cka2delta/cka2delta mutant had normal virulence in the mouse model of haematogenously disseminated candidiasis, it had significantly attenuated virulence in the mouse model of oropharyngeal candidiasis. Therefore, Cka2p governs the interactions of C. albicans with endothelial and oral epithelial cells in vitro and virulence during oropharyngeal candidiasis.     

Subcellular localization of protein kinase CK2

More than 46 years ago, Burnett and Kennedy first described protein kinase CK2 (formerly known as casein kinase 2) in liver extracts. Since then, protein kinase CK2 has been investigated in many organisms from yeast to man. It is now well established that protein kinase CK2 is a pleiotropic and ubiquitous serine or threonine kinase, which is highly conserved during evolution. A great number of studies deal with substrates of CK2, but the fact that over 160 substrates exist is more confusing than elucidatory. The holoenzyme is composed of two regulatory beta-subunits and two catalytic alpha- or alpha'-subunits. There is now increasing evidence for individual functions of the subunits that are different from their functions in the holoenzyme. Furthermore, more and more studies describe interacting partners of the kinase that may be decisive in the regulation of this enzyme. A big step forward has been the determination of the crystal structure of the two subunits of protein kinase CK2. Now the interactions of the catalytic subunit of CK2 with ATP as well as GTP and the interaction between the regulatory subunits can be explained. However, cellular functions of protein kinase CK2 still remain unclear. In the present review we will focus our interest on the subcellular localization of protein kinase CK2. Protein kinase CK2 is found in many organisms and tissues and nearly every subcellular compartment. There is ample evidence that protein kinase CK2 has different functions in these compartments and that the subcellular localization of protein kinase CK2 is tightly regulated. Therefore studying the subcellular localization of protein kinase CK2 may be a key to its function.     

Expression and regulation of protein kinase CK2 during the cell cycle

There are indications from genetic, biochemical and cell biological studies that protein kinase CK2 (formerly casein kinase II) has a variety of functions at different stages in the cell cycle. To further characterize CK2 and its potential roles during cell cycle progression, one of the objectives of this study was to systematically examine the expression of all three subunits of CK2 at different stages in the cell cycle. To achieve this objective, we examined levels of CK2, CK2 and CK2 on immunoblots as well as CK2 activity in samples prepared from: (i) elutriated populations of MANCA (Burkitt lymphoma) cells, (ii) serum-stimulated GL30-92/R (primary human fibroblasts) cells and (iii) drug-arrested chicken bursal lymphoma BK3A cells. On immunoblots, we observed a significant and co-ordinate increase in the expression of CK2 and CK2 following serum stimulation of quiescent human fibroblasts. By comparison, no major fluctuations in CK2 activity were detected during any other stages during the cell cycle. Furthermore, we did not observe any dramatic differences between the relative levels of CK2 to CK2 during different stages in the cell cycle. However, we observed a significant increase in the amount of CK2 relative to CK2 in cells arrested with nocodazole. We also examined the activity of CK2 in extracts or in immunoprecipitates prepared from drug-arrested cells. Of particular interest is the observation that the activity of CK2 is not changed in nocodazole-arrested cells. Since CK2 is maximally phosphorylated in these cells, this result suggests that the phosphorylation of CK2 by p34cdc2 does not affect the catalytic activity of CK2. However, the activity of CK2 was increased by incubation with p34cdc2 in vitro. Since this activation was independent of ATP we speculate that p34cdc2 may have an associated factor that stimulates CK2 activity. Collectively, the observations that relative levels of CK2 increase in mitotic cells, that CK2 and CK2 are phosphorylated in mitotic cells and that p34cdc2 affects CK2 activity in vitro suggest that CK2 does have regulatory functions associated with cell division.