The active form of the Saccharomyces cerevisiae ribonucleotide reductase small subunit is a heterodimer in vitro and in vivo

The class I ribonucleotide reductases (RNRs) are composed of two homodimeric subunits: R1 and R2. R2 houses a diferric-tyrosyl radical (Y*) cofactor. Saccharomyces cerevisiae has two R2s: Y2 (beta2) and Y4 (beta'2). Y4 is an unusual R2 because three residues required for iron binding have been mutated. While the heterodimer (betabeta') is thought to be the active form, several rnr4delta strains are viable. To resolve this paradox, N-terminally epitope-tagged beta and beta' were expressed in E. coli or integrated into the yeast genome. In vitro exchange studies reveal that when apo-(His6)-beta2 ((His)beta2) is mixed with beta'2, apo-(His)betabeta' forms quantitatively within 2 min. In contrast, holo-betabeta' fails to exchange with apo-(His)beta2 to form holo-(His)betabeta and beta'2. Isolation of genomically encoded tagged beta or beta' from yeast extracts gave a 1:1 complex of beta and beta', suggesting that betabeta' is the active form. The catalytic activity, protein concentrations, and Y* content of the rnr4delta and wild type (wt) strains were compared to clarify the role of beta' in vivo. The Y* content of rnr4delta is 15-fold less than that of wt, consistent with the observed low activity of rnr4delta extracts (<0.01 nmol min(-1) mg(-1)) versus wt (0.06 +/- 0.01 nmol min(-1) mg(-1)). (FLAG)beta2 isolated from the rnr4delta strain has a specific activity of 2 nmol min(-1) mg(-1), similar to that of reconstituted apo-(His)beta2 (10 nmol min(-1) mg(-1)), but significantly less than holo-(His)betabeta' (approximately 2000 nmol min(-1) mg(-1)). These studies together demonstrate that beta' plays a crucial role in cluster assembly in vitro and in vivo and that the active form of the yeast R2 is betabeta'.     

揭示蛋白激酶CK2生物学功能——亚基敲除/敲减

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,可催化细胞内多种蛋白质的磷酸化,由2个催化亚基CK2α或α′以及2个调节亚基CK2β组成的异源四聚体结构。为深入了解CK2的结构与功能,通过运用同源重组敲除、条件性敲除及RNAi引起的基因敲减技术分别对其3个亚基进行敲除与抑制,发现在CK2亚基敲除与抑制后,可对个体生殖、胚胎发育、肿瘤、代谢以及衰老造成重要的影响,说明CK2各亚基具有重要的生物学功能。本文就敲除与敲减蛋白激酶CK2任一亚基后其功能变化的进展作一综述。     

Purification and characterization of the CK2alpha'-based holoenzyme, an isozyme of CK2alpha: a comparative analysis

Protein kinase CK2 (former name: "casein kinase 2") is a pivotal and ubiquitously expressed member of the eukaryotic protein kinase superfamily. It predominantly exists as a heterotetrameric holoenzyme composed of two catalytic subunits (CK2alpha) and two regulatory subunits (CK2beta). In higher animals two paralog catalytic chains-abbreviated CK2alpha and CK2alpha'--exist which can combine with CK2beta to three isoforms of the holoenzyme: CK2alpha(2)beta(2), CK2alpha(2)(')beta(2), and CK2alphaalpha(')beta(2). While CK2alpha and the "normal" holoenzyme CK2alpha(2)beta(2) have been extensively characterized in vitro and in vivo, little is known about the enzymological properties of CK2alpha' and the "alternative" holoenzyme CK2alpha(2)(')beta(2) and about their specific physiological roles. A major reason for this lack of knowledge is the fact that so far CK2alpha' rather than CK2alpha has caused serious stability and solubility problems during standard heterologous expression procedures. To overcome them, we developed a preparation scheme for CK2alpha(2)(')beta(2) from Homo sapiens in catalytically active form based on two critical steps: first expression of human CK2alpha' as a well soluble fusion protein with the maltose binding protein (MBP) and second proteolytic cleavage of CK2alpha'-MBP in the presence of human CK2beta so that CK2alpha' subunits are incorporated into holoenzyme complexes directly after their release from MBP. This successful strategy which may be adopted in comparably difficult cases of protein/protein complex preparation is presented here together with evidence that the CK2alpha'-based and the CK2alpha-based holoenzymes are similar concerning their catalytic activities but are significantly different with respect to some well-known CK2 properties like autophosphorylation and supra-molecular aggregation.     

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.     

First Inactive Conformation of CK2α, the Catalytic Subunit of Protein Kinase CK2

The Ser/Thr kinase casein kinase 2 (CK2) is a heterotetrameric enzyme composed of two catalytic chains (CK2α, catalytic subunit of CK2) attached to a dimer of two noncatalytic subunits (CK2β, noncatalytic subunit of CK2). CK2α belongs to the superfamily of eukaryotic protein kinases (EPKs). To function as regulatory key components, EPKs normally exist in inactive ground states and are activated only upon specific signals. Typically, this activation is accompanied by large conformational changes in helix αC and in the activation segment, leading to a characteristic arrangement of catalytic key elements. For CK2α, however, no strict physiological control of activity is known. Accordingly, CK2α was found so far exclusively in the characteristic conformation of active EPKs, which is, in this case, additionally stabilized by a unique intramolecular contact between the N-terminal segment on one side, and helix αC and the activation segment on the other side. We report here the structure of a C-terminally truncated variant of human CK2α in which the enzyme adopts a decidedly inactive conformation for the first time. In this CK2α structure, those regulatory key regions still are in their active positions. Yet the glycine-rich ATP-binding loop, which is normally part of the canonical anti-parallel β-sheet, has collapsed into the ATP-binding site so that ATP is excluded from binding; specifically, the side chain of Arg47 occupies the ribose region of the ATP site and Tyr50, the space required by the triphospho moiety. We discuss some factors that may support or disfavor this inactive conformation, among them coordination of small molecules at a remote cavity at the CK2α/CK2β interaction region and binding of a CK2β dimer. The latter stabilizes the glycine-rich loop in the extended active conformation known from the majority of CK2α structures. Thus, the novel inactive conformation for the first time provides a structural basis for the stimulatory impact of CK2β on CK2α.     

Binding domain for p21(WAF1) on the polypeptide chain of the protein kinase CK2 beta-subunit

Protein kinase CK2 is a ubiquitous serine/threonine kinase which is involved in many proliferation-related processes in the cell. It is composed of two regulatory beta-subunits and two catalytic alpha-subunits. Its regulation still remains mysterious in spite of many years of intense research. One of its regulators is the cdk inhibitory molecule p21(WAF1)-a protein which is expressed in situations of genotoxic stress. p21(WAF1) binds to the beta-subunit of CK2 and inhibits the activity of CK2. Using deletion mutants of CK2 beta as well as a peptide library consisting of 15-amino-acid-long peptides derived from the polypeptide chain of CK2 beta we mapped the binding region for p21(WAF1) on the polypeptide chain of CK2 beta. We localized an amino-terminal and a carboxy-terminal binding domain. Binding of p21(WAF1) to both regions of the CK2 beta-subunit interferes with the phosphotransferase activity of the CK2 holoenzyme.     

The Protein Kinase CK2 Holoenzyme Structure Supports Proposed Models of Autoregulation and Trans-Autophosphorylation

Eukaryotic protein kinases are typically strictly controlled by second messenger binding, protein/protein interactions, dephosphorylations or similar processes. None of these regulatory mechanisms is known to work for protein kinase CK2 (former name “casein kinase 2”), an acidophilic and constitutively active eukaryotic protein kinase. CK2 predominantly exists as a heterotetrameric holoenzyme composed of two catalytic subunits (CK2α) complexed to a dimer of non-catalytic subunits (CK2β). One model of CK2 regulation was proposed several times independently by theoretical docking of the first CK2 holoenzyme structure. According to this model, the CK2 holoenzyme forms autoinhibitory aggregates correlated with trans-autophosphorylation and driven by the down-regulatory affinity between an acidic loop of CK2β and the positively charged substrate binding region of CK2α from a neighboring CK2 heterotetramer. Circular trimeric aggregates in which one-half of the CK2α chains show the predicted inhibitory proximity between those regions were detected within the crystal packing of the human CK2 holoenzyme. Here, we present further in vitro support of the “regulation-by-aggregation” model by an alternative crystal form in which CK2 tetramers are arranged as approximately linear aggregates coinciding essentially with the early predictions. In this assembly, the substrate binding region of every CK2α chain is blocked by a CK2β acidic loop from a neighboring tetramer. We found these crystals with CK2^Andante that contains a CK2β variant mutated in a CK2α-contact helix and described to be responsible for a prolonged circadian rhythm in Drosophila. The increased propensity of CK2^Andante to form aggregates with completely blocked active sites may contribute to this phenotype.     

Specific characteristics of CK2β regulatory subunits in plants

In all eukaryotes, the typical CK2 holoenzyme is an heterotetramer composed of two catalytic (CK2α and CK2α') and two regulatory (CK2β) subunits. One of the distinctive traits of plant CK2 is that they present a greater number of genes encoding for CK2α/β subunits than animals or yeasts, for instance, in Arabidopsis and maize both CK2α/β subunits belong to multigenic families composed by up to four genes. Here, we conducted a genome-wide survey examining 34 different plant genomes in order to investigate if the multigenic property of CK2β genes is a common feature through the entire plant kingdom. Also, at the level of structure, the plant CK2β regulatory subunits present distinctive features as (i) they lack about 20 aminoacids in the C-terminal domain, (ii) they present a specific N-terminal extension of about 90 aminoacids that shares no homology with any previously characterized functional domain, and (iii) the acidic loop region is poorly conserved at the aminoacid level. Since there is no data about CK2β or holoenzyme structure in plants, in this study, we use human CK2β as a template to predict a structure for Zea mays CK2β1 by homology modeling and we discuss about possible structural changes in the acidic loop region that could affect the enzyme regulation.     

Crystal structure of a C-terminal deletion mutant of human protein kinase CK2 catalytic subunit

Protein kinase CK2 (formerly called: casein kinase 2) is a heterotetrameric enzyme composed of two separate catalytic chains (CK2alpha) and a stable dimer of two non-catalytic subunits (CK2beta). CK2alpha is a highly conserved member of the superfamily of eukaryotic protein kinases. The crystal structure of a C-terminal deletion mutant of human CK2alpha was solved and refined to 2.5A resolution. In the crystal the CK2alpha mutant exists as a monomer in agreement with the organization of the subunits in the CK2 holoenzyme. The refined structure shows the helix alphaC and the activation segment, two main regions of conformational plasticity and regulatory importance in eukaryotic protein kinases, in active conformations stabilized by extensive contacts to the N-terminal segment. This arrangement is in accordance with the constitutive activity of the enzyme. By structural superimposition of human CK2alpha in isolated form and embedded in the human CK2 holoenzyme the loop connecting the strands beta4 and beta5 and the ATP-binding loop were identified as elements of structural variability. This structural comparison suggests that the ATP-binding loop may be the key region by which the non-catalytic CK2beta dimer modulates the activity of CK2alpha. The beta4/beta5 loop was found in a closed conformation in contrast to the open conformation observed for the CK2alpha subunits of the CK2 holoenzyme. CK2alpha monomers with this closed beta4/beta5 loop conformation are unable to bind CK2beta dimers in the common way for sterical reasons, suggesting a mechanism to protect CK2alpha from integration into CK2 holoenzyme complexes. This observation is consistent with the growing evidence that CK2alpha monomers and CK2beta dimers can exist in vivo independently from the CK2 holoenzyme and may possess physiological roles of their own.     

Yeast holoenzyme of protein kinase CK2 requires both β and β′ regulatory subunits for its activity

Protein kinase CK2 is a highly conserved Ser/Thr protein kinase that is ubiquitous among eucaryotic organisms and appears to play an important role in many cellular functions. This enzyme in yeast has a tetrameric structure composed of two catalytic (α and/or α′) subunits and two regulatory β and β′ subunits. Previously, we have reported isolation from yeast cells four active forms of CK2, composed of αα′ββ′, α₂ββ′, α′₂ββ′ and a free α′-catalytic subunit. Now, we report that in Saccharomyces cerevisiae CK2 holoenzyme regulatory β subunit cannot substitute other β′ subunit and only both of them can form fully active enzymatic unit. We have examined the subunit composition of tetrameric complexes of yeast CK2 by transformation of yeast strains containing single deletion of the β or β′ regulatory subunits with vectors carrying lacking CKB1 or CKB2 genes. CK2 holoenzyme activity was restored only in cases when both of them were present in the cell. Additional, co-immunoprecypitation experiments show that polyadenylation factor Fip1 interacts with catalytic α subunits of CK2 and interaction with beta subunits in the holoenzyme decreases CK2 activity towards this protein substrate. These data may help to elucidate the role of yeast protein kinase CK2β/β′ subunits in the regulation of holoenzyme assembly and phosphotransferase activity.     

CK2β interacts with and regulates p21-activated kinases in Drosophila

The role of CK2β has been defined as the regulatory subunit of protein kinase CK2, which is a heterotetrameric complex composed of two CK2β and two catalytic active CK2α subunits. The identification of other serine/threonine kinases such as A-Raf, Chk1, and c-Mos that interact with and are regulated by CK2β has challenged this view and provided evidence for functions of CK2β outside the CK2 holoenzyme. In this report we describe the first interaction of Drosophila CK2β outside the CK2 holoenzyme with p21-activated kinase (PAK) proteins. This interaction is seen for distinct PAK and CK2β isoforms. In contrast to the CK2α–CK2β interaction, dimer formation of the CK2β subunits is not a prerequisite for binding of PAK proteins. Our results support the idea that CK2β can bind to PAK proteins in a CK2α independent manner and negatively regulates PAK kinase activity.     

Enzymatic activity with an incomplete catalytic spine: insights from a comparative structural analysis of human CK2?? and its paralogous isoform CK2????

Eukaryotic protein kinases are fundamental factors for cellular regulation and therefore subject of strict control mechanisms. For full activity a kinase molecule must be penetrated by two stacks of hydrophobic residues, the regulatory and the catalytic spine that are normally well conserved among active protein kinases. We apply this novel spine concept here on CK2α, the catalytic subunit of protein kinase CK2. Homo sapiens disposes of two paralog isoforms of CK2α (hsCK2α and hsCK2α'). We describe two new structures of hsCK2α constructs one of which in complex with the ATP-analog adenylyl imidodiphosphate and the other with the ATP-competitive inhibitor 3-(4,5,6,7-tetrabromo-1H-benzotriazol-1-yl)propan-1-ol. The former is the first hsCK2α structure with a well defined cosubstrate/magnesium complex and the second with an open β4/β5-loop. Comparisons of these structures with existing CK2α/CK2α' and cAMP-dependent protein kinase (PKA) structures reveal: in hsCK2α' an open conformation of the interdomain hinge/helix αD region that is critical for ATP-binding is found corresponding to an incomplete catalytic spine. In contrast hsCK2α often adopts the canonical, PKA-like version of the catalytic spine which correlates with a closed conformation of the hinge region. HsCK2α can switch to the incomplete, non-canonical, hsCK2α'-like state of the catalytic spine, but this transition apparently depends on binding of either ATP or of the regulatory subunit CK2β. Thus, ATP looks like an activator of hsCK2α rather than a pure cosubstrate.     

The expression of casein kinase 2alpha' and phosphatase 2A activity

Protein phosphatase 2A (PP2A) activity may be differentially regulated by the expression of proteins containing a related amino acid sequence motif such as the casein kinase 2alpha (CK2alpha) subunit or SV40 small t antigen (SVt). Expression of CK2alpha increases PP2A activity whereas SVt decreases its activity. In this work we have tested for the effect of the expression of a third protein containing a similar motif that could be involved in PP2A regulation, the catalytic casein kinase 2alpha' subunit. Our results show that despite the structural similarity of this protein with the other CK2 catalytic (alpha) subunit, the function of the two subunits with respect to the modulation of PP2A activity is quite different: CK2alpha increases whereas CK2alpha' slightly decreases PP2A activity.     

The regulatory beta subunit of protein kinase CK2 mediates formation of tetrameric CK2 complexes

Protein kinase CK2 is a tetrameric enzyme composed of two catalytic (alpha and/or alpha') subunits and two regulatory (beta) subunits. Because CK2beta is synthesized in excess of CK2alpha, we hypothesized that formation of CK2beta homodimers precedes the incorporation of the catalytic subunits of CK2 into complexes. To test this hypothesis, we cotransfected cells with two epitope-tagged variants of CK2beta. The results of these cotransfection studies demonstrate that interactions between two CK2beta subunits take place in the absence of CK2alpha. Together with results from previous biosynthetic labeling studies, these results suggest that formation of CK2beta homodimers occurs before incorporation of catalytic subunits of CK2 into CK2 complexes. We also cotransfected Cos-7 cells with a deletion fragment of CK2beta (i.e. Myc-beta1-166) together with full-length hemagglutinin (HA)-tagged CK2beta and/or CK2alpha'. Although complexes between Myc-beta1-166 and HA-beta were readily detected, we obtained no evidence of direct interactions between Myc-beta1-166 and HA-CK2alpha'. These results suggest that residues within the N-terminal 166 amino acids of CK2beta are sufficient for interactions between CK2beta subunits, whereas the C-terminal domain of CK2beta is required for complex formation with the catalytic subunits of CK2. Finally, we observed that expression of full-length HA-beta promotes phosphorylation of Myc-beta1-166 by HA-CK2alpha'.     

Molecular cloning and mapping of casein kinase 2 alpha and beta subunit genes in barley.

Casein kinase 2 (CK2) is a ubiquitous, highly pleiotropic, constitutively active, and messenger-independent Ser/Thr protein kinase. It is found in two different forms: the heterotetrameric CK2, composed of two alpha catalytic subunits and two beta regulatory subunits, and the monomeric CK2 alpha, consisting of the alpha catalytic subunit. In the present study, we isolated barley cDNA clones of the CK2 alpha and beta subunit genes, designated HvCK2A and HvCK2B, respectively. Chromosome assignment, using a set of wheat-barley disomic chromosome addition lines, and RFLP mapping, using two doubled haploid populations, showed that HvCK2A was duplicated on the short arm of chromosome 2H and the long arm of chromosome 5H (designated HvCK2a-2H and HvCK2a-5H, respectively), and a single copy of HvCK2B was located on the long arm of chromosome 1H (designated HvCK2b). A PCR-Southern hybridization experiment demonstrated that the HvCK2A sequence originated from the HvCK2a-5H locus, showing that at least HvCK2a-5H was expressed. The present cDNA sequences and genomic organization of the two subunits will facilitate further functional analysis of CK2 in barley.     

Unique activation mechanism of protein kinase CK2. The N-terminal segment is essential for constitutive activity of the catalytic subunit but not of the holoenzyme

CK2 is an essential, ubiquitous, and highly pleiotropic protein kinase whose catalytic subunits (alpha and alpha') and holoenzyme (composed by two catalytic and two regulatory beta-subunits) are both constitutively active, a property that is suspected to contribute to its pathogenic potential. Extensive interactions between the N-terminal segment and the activation loop are suspected to underlie the high constitutive activity of the isolated catalytic subunit. Here we show that a number of point mutations (Tyr(26) --> Phe, Glu(180) --> Ala, Tyr(182) --> Phe) and deletions (Delta 2-6, Delta 2-12, Delta 2-18, Delta 2-24, Delta 2-30) expected to affect these interactions are more or less detrimental to catalytic activity of the alpha-subunit of human CK2, the deleted mutants Delta 2-24 and Delta 2-30 being nearly inactive under normal assay conditions. Kinetic analyses showed that impaired catalytic activity of mutants Delta 2-12, Delta 2-18, Delta 2-24, and Y182F is mainly accounted for by dramatic increases in the K(m) values for ATP, whereas a drop in K(cat) with K(m) values almost unchanged was found with mutants Y26F and E180A. Holoenzyme reconstitution restored the activity of mutants Delta 2-12, Delta 2-18, Y26F, E180A, and Y182F to wild type level and also conferred catalytic activity to the intrinsically inactive mutants, Delta 2-24 and Delta 2-30. These data demonstrate that specific interactions between the N-terminal segment and the activation loop are essential to provide a fully active conformation to the catalytic subunits of CK2; they also show that these interactions become dispensable upon formation of the holoenzyme, whose constitutive activity is conferred by the beta-subunit through a different mechanism.     

The crystal structure of the complex of Zea mays alpha subunit with a fragment of human beta subunit provides the clue to the architecture of protein kinase CK2 holoenzyme.

The crystal structure of a complex between the catalytic alpha subunit of Zea mays CK2 and a 23-mer peptide corresponding the C-terminal sequence 181-203 of the human CK2 regulatory beta subunit has been determined at 3.16-A resolution. The complex, composed of two alpha chains and two peptides, presents a molecular twofold axis, with each peptide interacting with both alpha chains. In the derived model of the holoenzyme, the regulatory subunits are positioned on the opposite side with respect to the opening of the catalytic sites, that remain accessible to substrates and cosubstrates. The beta subunit can influence the catalytic activity both directly and by promoting the formation of the alpha2 dimer, in which each alpha chain interacts with the active site of the other. Furthermore, the two active sites are so close in space that they can simultaneously bind and phosphorylate two phosphoacceptor residues of the same substrate.