Activators of phosphorylase kinase alter the cross-linking of its catalytic subunit to the C-terminal one-sixth of its regulatory alpha subunit

Phosphorylase kinase, a regulatory enzyme of glycogenolysis in skeletal muscle, is a hexadecameric oligomer consisting of four copies each of a catalytic subunit (gamma) and three regulatory subunits (alpha, beta, and delta, the last being endogenous calmodulin). The enzyme is activated by a variety of effectors acting through its regulatory subunits. To probe the quaternary structure of nonactivated and activated forms of the kinase, we used the heterobifunctional, photoreactive cross-linker N-5-azido-2-nitrobenzoyloxysuccinimide. Mono-derivatization of the holoenzyme with the succinimidyl group, followed by photoactivation of the covalently attached azido group, resulted in intramolecular cross-linking to form two distinct heterodimers: a major (alphagamma) and a minor (betadelta) conjugate. Formation of both conjugates was significantly altered in activated conformations of the enzyme induced by phosphorylation, alkaline pH, and several allosteric activators (ADP, exogenous calmodulin/Ca2+, and Ca2+ alone). Of these activating mechanisms, all increased formation of alphagamma, except Ca2+ alone, which inhibited its formation. When cross-linking was carried out at alkaline pH or in the presence of ADP or exogenous calmodulin/Ca2+, the cross-linked enzyme remained activated following removal of the activators; however, cross-linking in the presence of Ca2+ resulted in sustained inhibition. The results indicate that perturbations in the subunit cross-linking forming the alphagamma dimer reflect the subsequent extent of sustained activation of the holoenzyme that is measured. The region cross-linked to the catalytic gamma subunit was confined to the C-terminal 1/6th of the alpha subunit, which contains known regulatory regions. These results suggest that activators of the phosphorylase kinase holoenzyme perturb interactions between the C-terminal region of the inhibitory alpha subunit and the catalytic gamma subunit, ultimately leading to activation of the latter.     

The quaternary structure of phosphorylase kinase as influenced by low concentrations of urea. Evidence suggesting a structural role for calmodulin.

Skeletal-muscle phosphorylase kinase is a hexadecameric oligomer composed of equivalent amounts of four different subunits, (alpha beta gamma delta)4. The delta-subunit, which is calmodulin, functions as an integral subunit of the oligomer, and the gamma-subunit is catalytic. To learn more about intersubunit contacts within the hexadecamer and about the roles of individual subunits, we induced partial dissociation of the holoenzyme with low concentrations of urea. In the absence of Ca2+ the quaternary structure of phosphorylase kinase is very sensitive to urea over a narrow concentration range. Gel-filtration chromatography in the presence of progressively increasing concentrations of urea indicates that between 1.15 M- and 1.35 M-urea the delta-subunit dissociates, allowing extensive formation of complexes larger than the native enzyme that contain equivalent amounts of alpha-, beta- and gamma-subunits. As the urea concentration is increased to 2 M and 3 M, nearly all of the enzyme aggregates to the heavy species devoid of delta-subunit. Addition of Ca2+, which is known to block dissociation of the delta-subunit [Shenolikar, Cohen, Cohen, Nairn & Perry (1979) Eur. J. Biochem. 100, 329-337], also blocks aggregation of the enzyme induced by the low concentrations of urea. These results suggest that in native phosphorylase kinase the delta-subunit, in addition to activating the catalytic subunit and conferring upon it Ca2(+)-sensitivity, may also serve a structural role in preventing aggregation of the alpha-, beta- and gamma-subunits, thus limiting to four the number of alpha beta gamma delta protomers that associate under standard conditions. In gel-filtration chromatography with urea a protein peak containing equivalent amounts of alpha- and gamma-subunits is also observed, as is a peak containing only beta-subunits. Increasing concentrations of urea have a biphasic effect on the activity of the holoenzyme, being stimulatory up to 1 M and then inhibitory. The concentration-dependence of urea in the inhibitory phase parallels its ability to induce dissociation of the delta-subunit.     

Baculovirus-mediated overexpression of the phosphorylase b kinase holoenzyme and alpha gamma delta and gamma delta subcomplexes

Recombinant baculoviruses were created and used to coexpress rat phosphorylase kinase (Phk) alpha, gamma, and delta subunits and rabbit beta subunit in insect cells. Coexpression allowed creation of the (alphabetagammadelta)4 hexadecamer, the alphagammadelta heterotrimer, and the gammadelta heterodimeric subcomplexes. Neither the individual alpha, beta, or gamma subunit nor any complex containing the beta subunit other than the hexadecameric holoenzyme was obtained in soluble form. The expressed complexes exhibited pH- and [Ca2+]-dependent specific activities that were similar to those of the Phk holoenzyme purified from rabbit skeletal muscle (SkM Phk). SkM Phk, expressed Phk, and the alphagammadelta subcomplex were activated by exogenous calmodulin and underwent Ca(2+)-dependent autophosphorylation. In some of these features there were subtle differences that could likely be attributed to differences in the covalent modification state of the baculovirus-driven expressed protein. Our results provide an important avenue to probe the detailed characterization of the structure of Phk and the function of the individual domains of the subunits using baculovirus-mediated expression of Phk and Phk subcomplexes.     

Inhibition of the catalytic subunit of phosphorylase kinase by its alpha/beta subunits

The subunits of phosphorylase kinase are separated and isolated in high yield by gel filtration chromatography in pH 3.3 phosphate buffer containing 8 M urea. Three protein peaks are obtained: the alpha and beta subunits coelute in the first, whereas the gamma and delta subunits are separate peaks. Upon dilution of the denaturant, catalytic activity reappears, associated only with the gamma subunit. As has been previously observed (Kee, S.M., and Graves, D.J. (1986) J. Biol. Chem. 261, 4732-4737), addition of calmodulin dramatically stimulates the reactivation of gamma. Inclusion of increasing amounts of the alpha/beta subunit mixture in the renaturation progressively decreases the activity of the renatured gamma or gamma-calmodulin. This inhibition by alpha/beta is likely due to specific interactions with the gamma subunit because the inhibition is less at pH 8.2 than at pH 6.8 and less when equivalent amounts of phosphorylated alpha/beta subunits are used (both alkaline pH and phosphorylation are known to stimulate the activity of the holoenzyme). These results suggest that the role of either the alpha or beta subunits, or perhaps both, in the nonactivated (alpha 2 beta 2 gamma 2 delta 2)2 complex of phosphorylase kinase is to suppress the activity of the gamma subunit and that activation of the enzyme, by phosphorylation for instance, is due to deinhibition caused by release of this quaternary constraint by alpha and/or beta upon gamma.     

Purification and characterization of a multisubunit phosphatase from turkey gizzard smooth muscle. The effect of calmodulin binding to myosin light chain kinase on dephosphorylation

A phosphatase that is active in dephosphorylating the isolated 20,000-Da light chain of myosin, as well as the enzyme myosin light chain kinase, has been purified to apparent homogeneity from turkey gizzards. The enzyme has a molecular weight of 165,000 by sedimentation-equilibrium centrifugation under nondenaturing conditions and is composed of three subunits (Mr = 60,000, 55,000, and 38,000) in a 1:1:1 molar ratio. The properties of the holoenzyme, as well as the purified catalytic subunit (Mr = 38,000) were compared using myosin light chains, intact myosin, and myosin light chain kinase as substrates. Although the holoenzyme is active in dephosphorylating the isolated myosin light chains and the enzyme myosin light chain kinase, the holoenzyme does not dephosphorylate myosin. On the other hand, the catalytic subunit of the holoenzyme dephosphorylates all three substrates. When myosin light chain kinase, which has been phosphorylated at two sites is used as substrate, both sites are rapidly dephosphorylated by the phosphatase in the absence of bound calmodulin. If calmodulin is bound to the diphosphorylated kinase, only one site is dephosphorylated. Interestingly, the single site dephosphorylated when calmodulin is bound to myosin light chain kinase is the site that is not phosphorylated when the calmodulin-myosin kinase complex is phosphorylated by cAMP-dependent protein kinase.     

Monoclonal antibodies to rabbit skeletal muscle phosphorylase kinase. Probes for studies of subunit function

Monoclonal antibodies to rabbit skeletal muscle phosphorylase kinase were produced by the conventional hybridoma cell technique. 90 out of 600 hybridomas were found to produce phosphorylase kinase binding antibodies from which only five secreted also phosphorylase kinase activity affecting antibodies. Three of them were cloned; two hybridomas resisted all cloning efforts. Employing immunoblot technique all monoclonal antibodies show cross-reactivity with the alpha, beta, and gamma subunits of phosphorylase kinase indicating that similar, if not identical, epitopes are present on these three subunits. No cross-reactivity with delta is observed. Monoclonal antibodies secreted by two clones which bind to the alpha subunit stimulate the Ca2+-independent A0 activity of phosphorylase kinase more than 30-fold, whereas all other monoclonal antibodies obtained are ineffective in this respect. Monoclonal antibodies binding to the beta subunit inhibit the Ca2+-dependent activities significantly. Antibody produced by one hybridoma binds to the alpha, beta, and gamma subunits with approximately the same affinity. Based on the dual function of calmodulin in phosphorylase kinase (Hessová, Z., Varsányi, M., and Heilmeyer, L.M.G., Jr. (1985) Eur. J. Biochem. 146, 107-115) we conclude that binding of anti-alpha monoclonal antibodies to a regulatory domain in the alpha subunit results in an uncoupling of the inhibitory function of the Ca2+-free delta from the holoenzyme which leads to a concomitant increase in A0 activity. Furthermore, binding of anti-beta monoclonal antibodies to the beta subunit prevents a signal transfer from the Ca2+-saturated delta to the catalytic site of the holoenzyme which inhibits the Ca2+-dependent activities.     

Analyses of phosphorylase kinase by transmission and scanning transmission electron microscopy

Under conventional electron microscopy negatively stained phosphorylase kinase exhibits a bilobal structure resembling two bridged opposing parentheses. In this predominant particle orientation, usually only one bridge is observed; however, in many particles two bridges can be seen. Scanning transmission electron microscopy of unstained phosphorylase kinase shows very similar structures, with a particle mass equivalent to that of the hexadecameric holoenzyme. Partial digestion of the enzyme with chymotrypsin, which preferentially hydrolyzes the alpha-subunits, causes no significant changes in the structure; however, when both the alpha and beta subunits are degraded by trypsin, single lobed particles appear, i.e. the connecting bridges are missing. Mass analysis of scanning transmission electron microscopy images of trypsinized enzyme indicates that the protease does, in fact, split the particle into halves. Transmission electron microscopy of an alpha gamma delta complex isolated after incubation of the holoenzyme with LiBr shows only small particles approximately one-fourth the size of the holoenzyme. Thus, integrity of the beta subunit may be necessary in order for the two lobes of phosphorylase kinase to be bridged. These data also indicate that the subunits are arranged as a bridged dimer of octamers 2 (alpha 2 beta 2 gamma 2 delta 2).     

A surface plasmon resonance study of the interactions between the component subunits of protein kinase CK2 and two protein substrates,casein and calmodulin

Surface plasmon resonance has been used to study the interaction between the subunits composing protein kinase CK2 (two catalytic, -subunits, and two regulatory, -subunits), as well as the interaction of each subunit with two types of protein substrates, casein, the phosphorylation of which is activated by the regulatory subunit, and calmodulin, which belongs to the kind of substrates on which the catalytic subunit is down regulated by the regulatory subunit. The interaction of casein with the catalytic subunit differs from the interaction with the holoenzyme. Similarly to the interaction with the regulatory subunit, the catalytic subunit interacts with the protein substrate forming a very stable, irreversible complex. The reconstituted holoenzyme, however, binds casein reversibly, displaying a binding mode similar to that displayed by the regulatory subunit. The interaction of calmodulin with the catalytic subunit gives place, like in the case of casein, to an irreversible complex. The interactions with the regulatory subunit, and with the holoenzyme were practically negligible, and the interaction with the regulatory subunit disappeared upon increasing the temperature value to close to 30°C. The presence of polylysine induced a high increase in the extent of calmodulin binding to the holoenzyme. The results obtained suggest that CK2 subunit and protein substrates share a common, or at least an overlapping site of interaction on the catalytic subunit. The interaction between both subunits would prevent substrates from binding irreversibly to subunit, and, at the same time, it would generate a new and milder site of interaction between the whole holoenzyme and the protein substrate. The main difference between casein and calmodulin would consist in the lower affinity display by the last for the new site generated upon the binding of the regulatory subunit, in the absence of polycations like polylysine.     

cAMP-dependent protein kinase from Mucor rouxii: physical evidence of a ternary complex holoenzyme-cAMP

Gel electrophoresis and sucrose density gradient centrifugation techniques permitted the visualization for the first time of the ternary complex formed by the binding of cAMP to $\text{Mucor rouxii}$ cAMP-dependent protein kinase holoenzyme. The addition of 0.5 M NaCl or histone plus ATP-Mg⁺⁺, together with cAMP, dissociates the holoenzyme into free regulatory (R) and catalytic (C) subunits. At 4°C, cAMP bound to the holoenzyme is readily exchangeable with unlabeled cAMP (half life 2.5 min), while the nucleotide bound to the R subunit has a very slow exchange rate (half life 210 min). The amount of cAMP bound to R subunit is approximately twice the amount bound to holoenzyme at saturation.     

Single molecule analyses of the conformational substates of calmodulin bound to the phosphorylase kinase complex

The four integral delta subunits of the phosphorylase kinase (PhK) complex are identical to calmodulin (CaM) and confer Ca(2+) sensitivity to the enzyme, but bind independently of Ca(2+). In addition to binding Ca(2+), an obligatory activator of PhK's phosphoryltransferase activity, the delta subunits transmit allosteric signals to PhK's remaining alpha, beta, and gamma subunits in activating the enzyme. Under mild conditions about 10% of the delta subunits can be exchanged for exogenous CaM. In this study, a CaM double-mutant derivatized with a fluorescent donor-acceptor pair (CaM-DA) was exchanged for delta to assess the conformational substates of PhKdelta by single molecule fluorescence resonance energy transfer (FRET) +/-Ca(2+). The exchanged subunits were determined to occupy distinct conformations, depending on the absence or presence of Ca(2+), as observed by alterations of the compact, mid-length, and extended populations of their FRET distance distributions. Specifically, the combined predominant mid-length and less common compact conformations of PhKdelta became less abundant in the presence of Ca(2+), with the delta subunits assuming more extended conformations. This behavior is in contrast to the compact forms commonly observed for many of CaM's Ca(2+)-dependent interactions with other proteins. In addition, the conformational distributions of the exchanged PhKdelta subunits were distinct from those of CaM-DA free in solution, +/-Ca(2+), as well as from exogenous CaM bound to the PhK complex as delta'. The distinction between delta and delta' is that the latter binds only in the presence of Ca(2+), but stoichiometrically and at a different location in the complex than delta.     

Bovine brain calmodulin-dependent protein phosphatase. Regulation of subunit A activity by calmodulin and subunit B

Calmodulin-dependent protein phosphatase isolated from bovine brain consists of a catalytic subunit A (Mr = 60,000) and a regulatory subunit B (Mr = 19,000) present in equal molar ratios. The two subunits were dissociated by gel filtration in 6 M urea and reconstituted to investigate the role of calmodulin and subunit B in regulating the phosphatase activity of subunit A. The activity of subunit A was stimulated 2-fold by calmodulin, 13-fold by subunit B, and 21-fold by both, indicating that the effects of both were synergistic. Maximum stimulation by calmodulin was observed at a calmodulin to subunit A molar ratio of 2:1 in the presence or absence of subunit B, whereas that by subunit B was observed at a B to A molar ratio of 3:1 in the presence or absence of calmodulin. Calmodulin and subunit B increased the Vmax of subunit A 2- and 5-fold, respectively, but had little effect on the Km for casein. The specific activity of the phosphatase reconstituted from subunits A and B reached 86% that of the native enzyme, whereas that of the holoenzyme reached 90%. Subunit B, even though similar to calmodulin in many respects, did not stimulate the activity of native phosphatase, suggesting that it cannot substitute for calmodulin. Limited trypsinization of subunit A increased its catalytic activity to the level observed with calmodulin; and this activity was further stimulated by subunit B but not by calmodulin. These results indicate that subunit A of phosphatase contains one catalytic domain and two distinct regulatory domains, one for calmodulin, and another for subunit B, that these two proteins do not substitute for one another and that they stimulate subunit A synergistically.     

Chemical cross-linking of cyclic AMP-dependent protein kinase and its dissimilar subunits

Previous kinetic studies have demonstrated that the activation of cyclic AMP-dependent protein kinase by cyclic AMP involves the formation of a ternary complex of cyclic AMP, the regulatory subunit (R) and the catalytic subunit (C). It is suggested that only this ternary complex breaks down to liberate the enzymically active catalytic subunit. We have performed cross-linking experiments with the holoenzyme and its dissimilar subunits in the presence of MgATP and various concentrations of cyclic AMP. Results from these cross-linking studies indicate that regulatory subunits exist as dimers in the native form. Moreover, dissociation of the holoenzyme or the reconstituted enzyme is promoted by cyclic AMP, and the effect of MgATP is to stabilize the enzyme in the tetrameric form. The success in cross-linking the regulatory and the catalytic subunits of protein kinase with the lysine-specific bifunctional cross-linking reagent dimethyl suberimidate may be attributed to the presence of a large number of lysine residues in the enzyme.     

Rabbit skeletal muscle protein kinase. Conversion from cAMP dependent to independent form by chemical perturbations.

Protein kinase isolated from rabbit skeletal muscle can be reversibly converted from the cAMP dependent form to the indepent form by chaotropic salts and urea. A similar but irreversible conversion can also be induced by trypsin digestion of the holoenzyme. The dissociation of cAMP dependent protein kinase by low concentrations of thiocyanate raises the possibility of isolating both native regulatory and catalytic subunits. From various changes in enzymatic activity caused by urea and trypsin perturbation, it is proposed that the conversion of protein kinase from the cAMP dependent to the independent form is due primarily to preferential modification of the regulatory subunit of the holoenzyme.     

The calmodulin-binding domain of the catalytic gamma subunit of phosphorylase kinase interacts with its inhibitory alpha subunit: evidence for a Ca2+ sensitive network of quaternary interactions

Chemical cross-linking as a probe of conformation has consistently shown that activators, including Ca(2+) ions, of the (alphabetagammadelta)(4) phosphorylase kinase holoenzyme (PhK) alter the interactions between its regulatory alpha and catalytic gamma subunits. The gamma subunit is also known to interact with the delta subunit, an endogenous molecule of calmodulin that mediates the activation of PhK by Ca(2+) ions. In this study, we have used two-hybrid screening and chemical cross-linking to dissect the regulatory quaternary interactions involving these subunits. The yeast two-hybrid system indicated that regions near the C termini of the gamma (residues 343-386) and alpha (residues 1060-1237) subunits interact. The association of this region of alpha with gamma was corroborated by the isolation of a cross-linked fragment of alpha containing residues 1015-1237 from an alpha-gamma dimer that had been formed within the PhK holoenzyme by formaldehyde, a nearly zero-length cross-linker. Because the region of gamma that we found to interact with alpha has previously been shown to contain a high affinity binding site for calmodulin (Dasgupta, M., Honeycutt, T., and Blumenthal, D. K. (1989) J. Biol. Chem. 264, 17156-17163), we tested the influence of Ca(2+) on the conformation of the alpha subunit and found that the region of alpha that interacts with gamma was, in fact, perturbed by Ca(2+). The results herein support the existence of a Ca(2+)-sensitive communication network among the delta, gamma, and alpha subunits, with the regulatory domain of gamma being the primary mediator. The similarity of such a Ca(2+)-dependent network to the interactions among troponin C, troponin I, and actin is discussed in light of the known structural and functional similarities between troponin I and the gamma subunit of PhK.     

Visualization of Subunit Interactions and Ternary Complexes of Protein Phosphatase 2A in Mammalian Cells

Protein phosphatase 2A (PP2A) is a ubiquitous phospho-serine/threonine phosphatase that controls many diverse cellular functions. The predominant form of PP2A is a heterotrimeric holoenzyme consisting of a scaffolding A subunit, a variable regulatory B subunit, and a catalytic C subunit. The C subunit also associates with other interacting partners, such as α4, to form non-canonical PP2A complexes. We report visualization of PP2A complexes in mammalian cells. Bimolecular fluorescence complementation (BiFC) analysis of PP2A subunit interactions demonstrates that the B subunit plays a key role in directing the subcellular localization of PP2A, and confirms that the A subunit functions as a scaffold in recruiting the B and C subunits to form a heterotrimeric holoenzyme. BiFC analysis also reveals that α4 promotes formation of the AC core dimer. Furthermore, we demonstrate visualization of specific ABC holoenzymes in cells by combining BiFC and fluorescence resonance energy transfer (BiFC-FRET). Our studies not only provide direct imaging data to support previous biochemical observations on PP2A complexes, but also offer a promising approach for studying the spatiotemporal distribution of individual PP2A complexes in cells.     

Characterization of a soluble Mr-30,000 catalytic fragment of the neuronal calmodulin-dependent protein kinase II

Chymotryptic digestion of postsynaptic densities releases a soluble, catalytically active fragment of the alpha (Mr 50,000) subunit of the neuronal cytoskeletal calmodulin-dependent protein kinase II. The purified soluble form of the kinase likewise yields the fragment. Denaturation of the enzyme results in more extensive proteolytic degradation. 125I-Iodopeptide maps of the isolated catalytic portions of both forms of the enzyme are similar and are contained within the map of the isolated alpha subunit. Catalytic fragments of both forms of the enzyme comigrate on two-dimensional SDS-PAGE/isoelectric focusing with pI 6.7-7.2. The fragment phosphorylates microtubule-associated protein (MAP-2) but is not activated by Ca+2/calmodulin nor is it inhibited by trifluoperazine. Km values for MAP-2 and ATP are indistinguishable from those of the holoenzyme, while the Vmax is similar to that of the holoenzyme activated with Ca+2/calmodulin. Overlays of Western blots of fragment with 125I-calmodulin shows a loss of calmodulin binding. Both the number of phosphorylation sites and the ability to autophosphorylate are markedly reduced in the catalytic fragment. Evaluation of the hydrodynamic parameters of the purified fragment yielded Mr value of 25,600 with a frictional ratio (f/f0) of 1.12; the Mr value determined by SDS-PAGE was 30,000. Thus, the catalytic fragment appears to represent an activated form of the kinase with a monomeric, globular structure unlike the native enzyme which exhibits oligomerization and cytoskeletal association. These results are consistent with a tertiary structure for the calmodulin-dependent protein kinase that contains distinct domains responsible for catalytic activity, regulation by calmodulin, cytoskeletal association and the multimeric organization of enzyme subunits.     

Kinetic characterization of the calmodulin-activated catalytic subunit of phosphorylase kinase

The phosphorylase kinase holoenzyme from skeletal muscle is composed of a catalytic and three different regulatory subunits. Analysis of the kinetic mechanism of the holoenzyme is complicated because both the natural substrate phosphorylase b and also phosphorylase kinase itself have allosteric binding sites for adenine nucleotides. In the case of the kinase, these allosteric sites are not on the catalytic subunit. We have investigated the kinetic mechanism of phosphorylase kinase by using its isolated catalytic gamma-subunit (activated by calmodulin) and an alternative peptide substrate (SDQEKRKQISVRGL) corresponding to the convertible region of phosphorylase b, thus eliminating from our system all known allosteric binding sites for nucleotides. This peptide has been previously employed to study the kinetic mechanism of the kinase holoenzyme before the existence of the allosteric sites on the regulatory subunits was suspected [Tabatabai, L. B., & Graves, D. J. (1978) J. Biol. Chem. 253, 2196-2202]. This peptide was determined to be as good an alternative substrate for the isolated catalytic subunit as it was for the holoenzyme. Initial velocity data indicated a sequential kinetic mechanism with apparent Km's for MgATP and peptide of 0.07 and 0.47 mM, respectively. MgADP used as product inhibitor showed competitive inhibition against MgATP and noncompetitive inhibition against peptide, whereas with phosphopeptide as product inhibitor, the inhibition was competitive against both MgATP and peptide. The initial velocity and product inhibition studies were consistent with a rapid equilibrium random mechanism with one abortive complex, enzyme-MgADP-peptide. The substrate-directed, dead-end inhibitors 5'-adenylyl imidodiphosphate and Asp-peptide, in which the convertible Ser of the alternative peptide substrate was replaced with Asp, were competitive inhibitors toward their like substrates and noncompetitive inhibitors toward their unlike substrates, further supporting a random mechanism, which was also the conclusion from the report cited above that used the holoenzyme.     

Polymeric structure of the cyclic AMP-dependent protein kinase from the dimorphic fungus Mucor rouxii and purification of its catalytic subunit

Summary The polymeric structure of the cyclic AMP-dependent protein kinase (E.C.2.7.1.37) from the dimorphic fungus Mucor rouxii was analyzed through studies of gel filtration and sucrose gradient centrifugation of the holoenzyme and its subunits and by photoaffinity labeling of the regulatory subunit. It was demonstrated that it is a tetramer composed by two regulatory subunits (R) of mol. wt. 75 000 and two catalytic subunits (C) of mol. wt. 41 000 forming a holoenzyme R₂C₂ of mol. wt. 242 000. Frictional coefficients of 1.55 and 1.62 for the holoenzyme and for the regulatory dimer, respectively, indicate a significant degree of dimensional asymmetry in both molecules. A procedure for the purification of the catalytic subunit of the kinase is presented. The holoenzyme could be bound to a cyclic AMP-agarose column and the catalytic subunit could be eluted by 0.5 M NaCl, well resolved from the bulk of protein. This particular behaviour of the holoenzyme in cyclic AMP-agarose chromatography allowed the inclusion of this step in the purification of the catalytic subunit and corroborated that the holoenzyme was not dissociated by cyclic AMP alone. The isolated catalytic subunit displays Michaelis-Menten behaviour towards kemptide, protamine and histone and is inhibited by sulfhydryl reagents, indicating that the molecule has at least one cysteine residue essential for enzyme activity. The catalytic activity of the isolated C subunit is inactivated by the mammalian protein kinase inhibitor, and is inhibited by the regulatory subunit from homologous and heterologous sources. In general, the properties of the catalytic subunit suggest a structural similarity between Mucor and mammalian C subunits.Abbreviations C catalytic subunit monomer of protein kinase - R regulatory subunit monomer of protein kinase - 8-N₃-cyclic AMP 8-azido-cylic AMP - SDS sodium dodecyl sulfate - Pipes piperazine-N,N-bis(2-ethanesulfonic acid) See AcknowledgementsCareer Investigators from the CONICET     

Purification and characterization of recombinant protein kinase CK2 from Zea mays expressed in Escherichia coli

Recombinant protein kinase subunits rmCK2alpha-1 and rmCK2beta-1 from Zea mays were expressed separately in Escherichia coli and assembled to a fully active tetrameric holoenzyme complex in vitro. The obtained maize holoenzyme was purified to homogeneity, biochemically characterized, and compared to CK2 from human. Kinetic measurements of the recombinant maize holoenzyme (rmCK2) revealed k(cat) values for ATP and GTP of 4 and 2s(-1), respectively; whereas the recombinant maize catalytic subunit showed almost equal values for ATP and GTP, i.e., ca. 0.8s(-1). A comparison of the k(cat)/K(m) ratio between the maize holoenzyme and the catalytic subunit from CK2 maize shows that the incorporation of the catalytic subunit into the holoenzyme leads to a 14-fold activation in the case of ATP and 8-fold activation in the case of GTP. The maize holoenzyme is about 10 times more sensitive towards CK2 inhibitor heparin, on the other hand, it is stimulated only 0% by polylysine as compared to the human counterpart. The maize holoenzyme activity is more sensitive towards NaCl concentrations higher than those of rhCK2 and treatment with urea showed that rmCK2 holoenzyme was denatured more readily than the human holoenzyme.