1,720,972 research outputs found
Phosphorylation and activation of protein kinase CK2 by p34cdc2 are independent events.
No full textRecombinant isolated beta-subunit of protein kinase CK2 is readily phosphorylated by p34cdc2/cyclin B kinase at Ser209 with favourable kinetic constants (Km = 1.7 microM, Vmax = 20 nmol.min-1.mg-1). Two synthetic peptides reproducing the 170-215 and the 206-215 C-terminal fragments of the beta-subunit are also phosphorylated though with tenfold higher Km values (19.5 and 28.0 microM, respectively). In contrast, both the beta-subunit associated with the alpha-subunit to give the heterotetrameric holoenzyme and the native CK2 are not appreciably phosphorylated by p34cdc2. These data suggest that the Ser209 beta-subunit phosphorylation observed in intact cells occurs prior to beta-subunit incorporation into the holoenzyme. The isolated CK2 alpha-subunit is not phosphorylated to any appreciable extent by p34cdc2 kinase. Its catalytic activity is nevertheless increased up to fivefold upon incubation with p34cdc2/cyclin B kinase complex. Such a stimulation of activity is comparable to that induced by the beta-subunit and it is paralleled by a 40% decrease of p34cdc2/cyclin B catalytic activity. Similar to beta-subunit, p34cdc2/cyclin B also protects the alpha-subunit against thermal inactivation. CK2 holoenzyme is also stimulated by p34cdc2/cyclin B, albeit less dramatically than the isolated alpha-subunit. Such an effect is also evident with CK2 holoenzyme reconstituted with a mutated beta-subunit lacking the p34cdc2 phosphorylation site and it is not accompanied by any appreciable phosphorylation of either the beta or the alpha-subunit. These data indicate that in vitro CK2 alpha-subunit interacts with and is activated by p34cdc2/cyclin B kinase by a mechanism that does not imply the phosphorylation of CK2
Protein kinase CK2 mutants defective in substrate recognition - Purification and kinetic analysis
No full textFive mutants of protein kinase CK2 alpha subunit in which altogether 14 basic residues were singly to quadruply replaced by alanines (K74A,K75A,K76A,K77A; K79A, R80A,K83A; R191A,R195A,K198A; R228A; and R278A, K279A,R280A) have been purified to near homogeneity either as such or after addition of the recombinant beta subunit. By this latter procedure five mutated tetrameric holoenzymes were obtained as judged from their subunit composition, sedimentation coefficient on sucrose gradient ultracentrifugation, and increased activity toward a specific peptide substrate as compared with the isolated alpha subunits. The kinetic constants and the phosphorylation efficiencies (V(max)/Km) of all the mutants with the parent peptide RRRADDSDDDDD and a series of derivatives, in which individual aspartic acids were replaced by alanines, have been determined. Three mutants, namely K74A,K75A,K76A,K77A; K79A, R80A,K83A; and R191A,R195A, K198A, display dramatically lower phosphorylation efficiency and 8-50-fold higher Km values with the parent peptide, symptomatic of reduced attitude to bind the peptide substrate as compared with CK2 wild type. Such differences either disappear or are attentuated if the mutants R191A,R195A, K198A; K79A,R80A,K83A; and K74A,K75A, K76A,K77A are assayed with the peptides RRRADDSADDDD, RRRADDSDDADD, and RRRADDSDDDAA, respectively. In contrast, the phosphorylation efficiencies of the other substituted peptides decrease more markedly with these mutants than with CK2 wild type. These data show that one or more of the basic residues clustered in the 191-198, 79-83, and 74-77 sequences are implicated in the recognition of the acidic determinants at positions +1, +3, and +4/+5, respectively, and that if these residues are mutated, the relevance of the other acidic residues surrounding serine is increased. In contrast the other two mutants, namely R228A and R278A,K279A, R280A, display with all the peptides V(max) values higher than CK2 wild type, counterbalanced however by somewhat higher Km values. It can be concluded from these data that all five mutations performed are compatible with the reconstitution of tetrameric holoenzyme, but all of them influence the enzymatic efficiency of CK2 to different extents. Although the basic residues mutated in the 74-77, 79-83, and 191-198 sequences are clearly implicated in substrate recognition by interacting with acidic determinants at variable positions downstream from serine, the other basic residues seem to play a more elusive and/or indirect role in catalysis
Casein kinase-2 structure-function relationship: creation of a set of mutants of the beta subunit that variably surrogate the wildtype beta subunit function.
No full textRole of the beta subunit of casein kinase-2 on the stability and specificity of the recombinant reconstituted holoenzyme.
No full textThe effect of polylysine on casein-kinase-2 activity is influenced by both the structure of the protein/peptide substrates and the subunit composition of the enzyme.
No full textBasic residues in the 74-83 and 191-198 segments of protein kinase CK2 catalytic subunit are implicated in negative but not in positive regulation by the beta-subunit
No full textProtein kinase CK2 is a ubiquitous pleiotropic serine/threonine protein kinase whose holoenzyme is comprised of two catalytic (alpha and/or alpha') and two non-catalytic, beta-subunits. The beta-subunit possesses antagonist functions that can be physically dissected by generating synthetic fragments encompassing its N-terminal and C-terminal domains. Here we show that by mutating basic residues in the 74-77 and in the 191-198 regions of the alpha-subunit, the negative regulation by the beta-subunit and by its N-terminal synthetic fragment CK2beta-(1-77), which is observable using calmodulin as a substrate for phosphorylation, is drastically reduced. In contrast, the positive regulation by a C-terminal, CK2beta-(155-215)-peptide is unaffected or even increased. Moreover, the basal activity of alpha mutants K74-77A, K79R80K83A, and R191R195K198A toward specific peptide substrates is stimulated by the beta-subunit many fold more than that of alpha wild type, while extrastimulation by beta mutant D55L56E57A, observable with alpha wild type, is abolished with these mutants. These data support the conclusion that down regulation by the acidic residues clustered in the N-terminal moiety of beta is mediated by basic residues in the 74-83 and in the 191-198 sequences of the alpha-subunit. These are also implicated in substrate recognition consistent with the concept that the N-terminal acidic region of the beta subunit operates as a pseudosubstrate. In contrast, another CK2alpha mutant, V66A, is more sensitive to inhibition by either beta-subunit or its N-terminal, CK2beta-(1-77)-peptide, while its stimulation by the C-terminal peptide, CK2beta-(155-215), is comparable to that of alpha wild type. These observations suggest an indirect role of Val66 in conferring to the alpha-subunit a conformation less sensitive to down regulation by beta-subunit
Mapping the residues of protein kinase CK2 alpha subunit responsible for responsiveness to polyanionic inhibitors
No full textSix mutants of protein kinase CK2 alpha subunit in which basic residues have been mutated into alanines were assayed for their capability to phosphorylate the peptide RRRADDSDDDDD. Two mutants (R228A and R278K279R280A) behaved more or less as alpha wild type and one (H160,166A) was nearly inactive, hampering the calculation of kinetic parameters. In contrast 3 mutants (K74-77A, K79R80K83A and R191,195K198A) phosphorylated the peptide with reduced efficiency accounted for by increased Km and decreased Vmax values. By using derivatives of the RRRADDSDDDDD peptide in which individual aspartyl residues were variably replaced by alanine(s) and two peptide substrates derived from I-2 (KYRIREQESSGEEDSDL and RRKDLHDDEEDEEMSETADGE) it was shown that mutations in the 191-198, 74-77 and 79-83 regions were the least detrimental whenever the acidic determinants were lacking at positions +1, +4/+5 and +3, respectively. These data support the conclusion that the basic residues present in the p+1 loop of CK2 alpha specifically recognize the acidic determinant adjacent to the C-terminal side of serine, while the specificity determinants located more down-stream are variably recognized by different residues of the unique basic cluster spanning between Lys74 and Lys83
MAPPING THE RESIDUES OF PROTEIN-KINASE CK2 IMPLICATED IN SUBSTRATE RECOGNITION - MUTAGENESIS OF CONSERVED BASIC RESIDUES IN THE ALPHA-SUBUNIT
No full textSix mutants of protein kinase CK2 alpha subunit in which basic residues have been mutated into alanines were assayed for their capability to phosphorylate the peptide RRRADDSDDDDD. Two mutants (R228A and R278K279R280A) behaved more or less as alpha wild type and one (H160,166A) was nearly inactive, hampering the calculation of kinetic parameters. In contrast 3 mutants (K74-77A, K79R80K83A and R191,195K198A) phosphorylated the peptide with reduced efficiency accounted for by increased Km and decreased Vmax values. By using derivatives of the RRRADDSDDDDD peptide in which individual aspartyl residues were variably replaced by alanine(s) and two peptide substrates derived from I-2 (KYRIREQESSGEEDSDL and RRKDLHDDEEDEEMSETADGE) it was shown that mutations in the 191-198, 74-77 and 79-83 regions were the least detrimental whenever the acidic determinants were lacking at positions +1, +4/+5 and +3, respectively. These data support the conclusion that the basic residues present in the p+1 loop of CK2 alpha specifically recognize the acidic determinant adjacent to the C-terminal side of serine, while the specificity determinants located more down-stream are variably recognized by different residues of the unique basic cluster spanning between Lys74 and Lys83
Going Beyond Counting First Authors in Author Co-citation Analysis
Full text linkThe present study examines one of the fundamental aspects of author co-citation analysis (ACA) - the way co-citation
counts are defined. Co-citation counting provides the data on which all subsequent statistical analyses and mappings
are based, and we compare ACA results based on two different types of co-citation counting - the traditional type that
only counts the first one among a cited work's authors on the one hand and a non-traditional type that takes into
account the first 5 authors of a cited work on the other hand. Results indicate that the picture produced through this non-traditional author co-citation counting contains more coherent author groups and is therefore considerably clearer. However, this picture represents fewer specialties in the research field being studied than that produced through the traditional first-author co-citation counting when the same number of top-ranked authors is selected and analyzed. Reasons for these effects are discussed
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