Immunofluorescence localization of the regulatory subunit type II of cAMP-dependent protein kinase in PC12 and 3T3 cells in different proliferative states

Localization of the regulatory subunit of cAMP-dependent protein kinase type II was studied in proliferating and quiescent fibroblasts 3T3 and in a cell line of neural origin pheochromocytoma PC12. In actively proliferating PCl2 cells the regulatory subunit was found to be localized in the nucleus. Transition of these cells into a quiescent state was accompanied by a regulatory subunit translocation to the cytoplasm. In 3T3 cells the regulatory subunit was localized in the cytoplasm both in the quiescent and proliferating (though less actively than PC12 cells) states. Similar results were obtained both with monoclonal antibodies and with rabbit monospecific antiserum raised against the regulatory subunit type II from pig brain.     

Altered properties of cAMP-dependent protein kinase in H-ras-transformed NIH3T3 cells

cAMP-dependent protein kinase activity in the soluble fraction was decreased in both v-H-ras-transformed and activated-c-H-ras-transformed NIH3T3 cells as compared with that in NIH3T3 cells. Both of the elution profile of type II cAMP-dependent protein kinase from DEAE-cellulose and the electrophoretic behavior of its regulatory subunits in the particulate fraction of H-ras-transformed cells are different from those of control NIH3T3 cells. These results suggest that ras protein causes the alterations of some properties of cAMP-dependent protein kinases.     

Overexpression of the type II regulatory subunit of the cAMP-dependent protein kinase eliminates the type I holoenzyme in mouse cells

Mammalian tissues and cell lines express two major types of cAMP-dependent protein kinase, PKA-I and PKA-II, which can be distinguished at the molecular level by the presence of either type I or type II regulatory subunits in the holoenzyme. An expression vector for the mouse type II regulatory subunit (RII alpha) was transfected into ras-transformed NIH3T3 (R3T3) cells, which contain approximately equal amounts of both holoenzymes, PKA-I and PKA-II. In RII alpha-overexpressing R3T3 cells, PKA-II levels were increased, and the level of PKA-I declined. The decrease in PKA-I was dependent on the amount of RII alpha expressed, and at high levels of RII alpha expression, PKA-I was completely eliminated. In contrast, overexpression of the type I regulatory subunit (RI alpha) did not alter PKA isozyme levels. We propose that competition between RII alpha and RI alpha for a limited pool of catalytic subunit results in preferential assembly of PKA-II and that significant amounts of PKA-I are formed only if catalytic subunit is present in excess of the RII alpha subunit. The PKA-I isozyme, which is absent in untransformed 3T3 cells, is not essential for the transformed phenotype of R3T3 cells. RII alpha-overexpressing R3T3 cells that are devoid of PKA-I continued to exhibit a transformed phenotype including anchorage-independent growth. Overexpression of RII alpha provides a genetic approach that may prove useful in demonstrating specific functions for the two PKA isozymes in cAMP-dependent signal transduction pathways.     

Phosphorylation of type II regulatory subunit of cAMP-dependent protein kinase in intact smooth muscle

A monoclonal antibody was used to quantitate changes in the extent of phosphorylation of the type II regulatory subunit of cAMP-dependent protein kinase in intact bovine tracheal smooth muscle. The autophosphorylated and nonphosphorylated forms of the regulatory subunit (RII) were separated in sodium dodecyl sulfate-polyacrylamide gels and identified by immunoblot analysis. Addition of cAMP to tissue extracts resulted in rapid dephosphorylation of RII (t 1/2 = 20s at 4 degrees C) while addition of MgATP caused complete conversion to the phosphorylated form. Under basal conditions, 56% of RII in intact muscle was phosphorylated when the tissue was homogenized under conditions which fully inhibit protein kinase and phosphatase activities. Incubation with isoproterenol caused a dose-dependent decrease in the phosphorylation state of RII (EC50 = 5 X 10(-8) M). Incubation with high concentrations of isoproterenol, 1-methyl-3-isobutylxanthine, or forskolin caused maximal decreases in the phosphorylated form to 12-18% of the total RII. The effect of isoproterenol was rapid (t 1/2 = 15 s at 37 degrees C), reversible, and could be blocked with the antagonist propranolol. Contraction of the smooth muscle with K+ or low (less than 1 microM) concentrations of carbachol had no effect on the phosphorylation level. A decrease in the basal phosphorylation level to 41% was observed with 10 microM carbachol which was additive with the dephosphorylation produced by isoproterenol. The time course of isoproterenol-induced dephosphorylation of RII paralleled that of muscle relaxation, consistent with a role of cAMP-dependent protein kinase activation in relaxation of smooth muscle.     

Molecular basis for regulatory subunit diversity in cAMP-dependent protein kinase: crystal structure of the type II beta regulatory subunit

BACKGROUND: Cyclic AMP binding domains possess common structural features yet are diversely coupled to different signaling modules. Each cAMP binding domain receives and transmits a cAMP signal; however, the signaling networks differ even within the same family of regulatory proteins as evidenced by the long-standing biochemical and physiological differences between type I and type II regulatory subunits of cAMP-dependent protein kinase. RESULTS: We report the first type II regulatory subunit crystal structure, which we determined to 2.45 A resolution and refined to an R factor of 0.176 with a free R factor of 0.198. This new structure of the type II beta regulatory subunit of cAMP-dependent protein kinase demonstrates that the relative orientations of the two tandem cAMP binding domains are very different in the type II beta as compared to the type I alpha regulatory subunit. Each structural unit for binding cAMP contains the highly conserved phosphate binding cassette that can be considered the "signature" motif of cAMP binding domains. This motif is coupled to nonconserved regions that link the cAMP signal to diverse structural and functional modules. CONCLUSIONS: Both the diversity and similarity of cAMP binding sites are demonstrated by this new type II regulatory subunit structure. The structure represents an intramolecular paradigm for the cooperative triad that links two cAMP binding sites through a domain interface to the catalytic subunit of cAMP-dependent protein kinase. The domain interface surface is created by the binding of only one cAMP molecule and is enabled by amino acid sequence variability within the peptide chain that tethers the two domains together.     

Conformational changes of type II regulatory subunit of cAMP-dependent protein kinase on cAMP binding

The effect of cAMP on the conformation of the regulatory subunit of type II cAMP-dependent protein kinase (RII) from bovine heart was investigated by UV-difference and circular dichroism (CD) spectroscopy. The UV-difference spectrum of RII with and without cAMP showed a positive band around 278 nm and a negative band at 256 nm. Similarly, cAMP enhanced the ellipticity of RII in the region between 280 and 300 nm and decreased that between 250 and 280 nm. In addition, cAMP transformed the far-UV CD spectrum of RII from that of a negative band minimally at 209 nm with a shoulder at 223 nm to one with two minima at 222 and 211 nm. These data show that cAMP induces conformational changes of RII upon binding. Such structural changes may be the basis of activation of cAMP-dependent protein kinases by cAMP.     

Expression cloning of a cDNA encoding the type II regulatory subunit of the cAMP-dependent protein kinase

We report here the isolation and sequence of a cDNA for the type II regulatory subunit of the cAMP-dependent protein kinase (cAMP-PK) from a lambda gt-11 cDNA library derived from a porcine epithelial cell line (LLC-PK1). The cDNA was detected by immunological screening using an affinity purified polyclonal antibody for bovine RII. DNA sequence analysis of the 467 bp EcoRI insert confirmed the identity of the clone, because the deduced amino acid sequence corresponded to the published sequence for the bovine RII protein. Northern analysis of total RNA from the LLC-PK1 cells indicated a single mRNA species of about 6.0 kb, probably derived from a single copy gene.     

Immunochemical properties of the regulatory subunit of cAMP-dependent protein kinase II]

Immunochemical analysis of the cAMP-dependent protein kinase regulatory subunit type II was performed with the use of two rabbit antisera elicited to a free R-subunit from pig brain and to a RcAMP complex. Quantitative precipitation of the homogeneous antigen revealed six determinants on the R-molecule. Of these at least one is localized in the R-fragment (37 kD), the others--in the N-terminal part of the R-molecule. The antigenic determinants seem to be remoted from the cAMP-binding centers, since the attachment of the affinity purified antibody Fab-fragments to the R-subunit did not influence the cAMP-binding activity of the latter. The antibodies to RcAMP caused dissociation of the holoenzyme. The antibody Fab-fragment binding to the R-subunit prevented its association with the catalytic subunit. The results of immunochemical analysis suggest that the R-subunit adopts different conformations when bound to cAMP or to the catalytic subunit.     

Interaction of the regulatory subunit of a type II cAMP-dependent protein kinase with mammalian sperm flagellum

We have reported previously (Horowitz, J. A., Toeg, H., and Orr, G. A. (1984) J. Biol. Chem. 259, 832-838) that most of the type II cAMP-dependent protein kinases in rat sperm are associated with the flagellum. We have now identified flagellar polypeptides which are capable of forming tight complexes with the regulatory subunit of type II cAMP-dependent protein kinase (RII). Flagellar RII-binding polypeptides were identified using an RII overlay/immunoblot procedure and had apparent subunit Mr of 120,000, 80,000, and 57,000 in rat and 120,000 and 57,000 in bovine flagella. RII is released from the flagellum by disulfide reducing agents, e.g. 1 mM dithiothreitol (DTT). Sodium dodecyl sulfate-polyacrylamide gel electrophoresis and Coomassie Blue staining of the DTT-released material shows that a limited subpopulation of flagellar polypeptides are solubilized by disulfide-reducing agents. Neither tubulin, the dynein ATPase, or any of the RII-binding proteins are released by 1 mM DTT, and thin section electron microscopy revealed that the morphology of the flagellum is unaltered by reducing conditions. Our data established that RII is not linked to the flagellum via a direct disulfide bridge. We propose that RII is released from the flagellum, a highly disulfide cross-linked structure, due to structural changes in the flagellum which disrupts the interaction between RII and its binding proteins.     

Expression of the type I regulatory subunit of cAMP-dependent protein kinase in Escherichia coli

An expression vector has been constructed for the type I regulatory subunit of cAMP-dependent protein kinase. A cDNA clone for the bovine RI-subunit has been inserted into pUC7. When Escherichia coli JM105 was transformed with this plasmid, R-subunit was expressed in amounts that approached 4 mg/liter. The expressed protein was visualized in total cell extracts by photolabeling with 8-azidoadenosine 3':5'-mono[32P]phosphate following transfer from sodium dodecyl sulfate-polyacrylamide gels to nitrocellulose. Expression of R-subunit was independent of isopropyl-beta-D-thiogalactopyranoside. R-subunit accumulated in large amounts only in the stationary phase of growth, and the addition of isopropyl-beta-D-thiogalactopyranoside during the log phase of growth actually blocked the accumulation of R-subunit. Maximum expression (20 mg/liter) was achieved when E. coli 222 was transformed with the RI-containing plasmid. E. coli 222 is a strain that contains two mutations; it is cya- and also has a mutation in the catabolite gene activator protein (crp) that enables the protein to bind to DNA in the absence of cAMP. The expressed RI-subunit was a soluble, dimeric protein, and no significant proteolysis was apparent in the cell extract. The purified RI-subunit bound 2 mol of cAMP/mol of R monomer, reassociated with C-subunit to form holoenzyme, and migrated as a dimer on sodium dodecyl sulfate-polyacrylamide gels in the absence of reducing agents. The expressed protein was also susceptible to limited proteolysis, yielding a monomeric cAMP-binding fragment having a molecular weight of 35,000. In all of these properties, the expressed protein was indistinguishable from RI purified from bovine tissue even though the R-subunit expressed in E. coli represents a fusion protein that contains 10 additional amino acids at the amino terminus that are provided by the lac Z' gene of the vector. This NH2-terminal sequence was confirmed by amino acid sequencing.     

Retinoylation of the type II cAMP-binding regulatory subunit of cAMP-dependent protein kinase is increased in psoriatic human fibroblasts

Previously, we have reported a defect in the cAMP-dependent protein kinases (cAMP-PK) in psoriatic cells (i.e., a decrease in 8-azido-[³²P]cAMP binding to the regulatory subunits and a decrease in phosphotransferase activity) which is rapidly reversed with retinoic acid (RA) treatment of these cells. This led us to examine a possible direct interaction between retinoids and the RI and RII regulatory subunits through retinoylation. Retinoylation of RI and RII present in normal and psoriatic human fibroblasts was analysed by [³H]RA treatment of these cells, followed either by chromatographic separation of the regulatory subunits or by their specific immunoprecipitation. These studies indicated that RI and RII can be retinoylated. [³H]RA labeling of the RII subunit was significantly (P < 0.005) greater in psoriatic fibroblasts (nine subjects; mean 7.47 relative units ± 1.37 SEM) compared to normal fibroblasts (eight subjects; mean 2.46 relative units ± 0.49 SEM). [³H]RA labeling of and the increase in 8-azido-[³²P]-binding to the RI and RII subunit in psoriatic fibroblasts showed a similar time course. This suggests that the rapid effect of retinoic acid treatment to enhance 8-azido-[³²P]-cAMP binding to the RI and RII in psoriatic fibroblasts may be due, in part, to covalent modification of the regulatory subunits by retinoylation. © 1996 Wiley-Liss, Inc.     

Study of the structural characteristics of the regulatory subunit of cAMP-dependent protein kinase type II using monoclonal antibodies

Monoclonal antibodies to the regulatory subunit of cAMP-dependent protein kinase type II from porcine brain were used to study the antigenic properties of the enzyme regulatory subunit (RII). The monoclonal antibodies were bound to linear antigenic determinants on the protein molecule surface. The cAMP binding to RII interfered with the interaction between monoclonal antibodies and the protein. The use of different proteolytic fragments of RII allowed for the localization of antigenic determinants in the N-terminal moiety of RII.     

Type II regulatory subunit dimerization determines the subcellular localization of the cAMP-dependent protein kinase

The type II cAMP-dependent protein kinase (PKA) is localized to specific subcellular environments through binding of dimeric regulatory subunits (RII) to anchoring proteins. Cytoskeletal localization occurs through RII dimer interaction with the PKA substrate molecule microtubule-associated protein 2 (MAP2). RII alpha deletion mutants and RII alpha/endonexin chimeras retained MAP2 binding activity if they contained the first 79 residues of the molecule. Disruption of RII alpha dimerization always prevented MAP2 interaction because 1) RII delta 1-14 (an amino-terminal deletion mutant lacking residues 1-14) was unable to bind MAP2 or form dimers, and 2) a modified RII alpha monomer including residues 1-14 did not bind MAP2. Chimeric proteins containing the first 30 residues of RII alpha fused to endonexin II formed dimers but did not bind MAP2. This suggested other side-chains between residues 30-79 also participate in MAP2 interaction. Peptide studies indicate additional contact with MAP2 may occur through an acidic region (residues 68-82) close to the RII autoinhibitor domain. Therefore, anchored PKA holoenzyme topology may position the catalytic subunit and MAP2 as to allow its preferential phosphorylation upon kinase activation.     

The regulatory subunit of the type II cAMP-dependent protein kinase in rabbit ovaries is the RII beta isoform.

Based on RII autophosphorylation, photoaffinity labeling with 8-N3[32P]cAMP, and Western blot analysis we have identified the RII isoform found in rabbit corpora lutea as RII beta. The RII beta subunit found in rabbit corpora lutea differs from the RII beta found in rat follicles and corpora lutea in that it migrates at Mr 52,500 on SDS-PAGE and shifts to Mr 53,000 when phosphorylated.     

Coelution of the type II holoenzyme form of cAMP-dependent protein kinase with regulatory subunits of the type I form of cAMP-dependent protein kinase

The types and subunit composition of cAMP-dependent protein kinases in soluble rat ovarian extracts were investigated. Results demonstrated that three peaks of cAMP-dependent kinase activity could be resolved using DEAE-cellulose chromatography. Based on the sedimentation of cAMP-dependent protein kinase and regulatory subunits using sucrose density gradient centrifugation, identification of 8-N3[32P]cAMP labeled RI and RII in DEAE-cellulose column and sucrose gradient fractions by sodium dodecyl sulfate-polyacrylamide gel electrophoresis, and Scatchard analysis of the cAMP-stimulated activation of the eluted peaks of kinase activity, the following conclusions were drawn regarding the composition of the three peaks of cAMP-dependent protein kinase activity: peak 1, eluting with less than or equal to 0.05 M potassium phosphate, consisted of the type I form of cAMP-dependent protein kinase; peak 2, eluting with 0.065-0.11 M potassium phosphate, consisted of free RI and a type II tetrameric holoenzyme; peak 3, eluting with 0.125 M potassium phosphate, consisted of an apparent RIIC trimer, followed by the elution with 0.15 M potassium phosphate of free RII. The regulatory subunits were confirmed as authentic RI and RII based upon their molecular weights and autophosphorylation characteristics. The more basic elution of the type II holoenzyme with free RI was not attributable to the ionic properties of the regulatory subunits, based upon the isoelectric points of photolabeled RI and RII and upon the elution location from DEAE-cellulose of RI and RII on dissociation from their respective holoenzymes by cAMP. This is the first report of a type II holoenzyme eluting in low salt fractions with free RI, and of the presence of an apparent RIIC trimer in a soluble tissue extract.     

Purification and characterization of hormone-regulated isoforms of the regulatory subunit of type II cAMP-dependent protein kinase from rat ovaries

The regulatory subunit (R-II) of cAMP-dependent protein kinase type II is induced in rat ovarian granulosa cells by the synergistic actions of estradiol and follicle-stimulating hormone. The R-II from rat ovaries was compared with R-II from rat heart, rat brain, bovine heart, and bovine brain using immunological methods, 8-N3[32P]cAMP photoaffinity labeling and sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Three isoforms of R-II were identified in rat ovarian cell extract (R-II54 Mr = 54,000, R-II52 Mr = 52,000, R-II51 Mr = 51,000), two isoforms of R-II in rat brain cell extract (Mr = 54,000, Mr = 52,000), and one isoform of R-II in rat heart cell extract (Mr = 54,000). Rat ovarian R-II54, heart R-II, and brain R-II (Mr = 54,000) were recognized by antiserum against rat heart R-II, whereas rat ovarian R-II52/R-II51 and rat brain R-II (Mr = 52,000) were not. In contrast, an antiserum raised against bovine heart R-II recognized all three isoforms of ovarian R-II as well as the lower molecular weight form of rat brain R-II. Ovarian types R-II52 and R-II51 but not R-II54 were increased selectively in granulosa cells by estradiol and follicle-stimulating hormone. In addition: 1) ovarian R-II52/51 subunits were purified to homogeneity and shown to recombine with C subunit from bovine heart to form a cAMP-dependent protein kinase; 2) pure R-II52/51 were not interconvertible to a higher molecular weight form by C subunit-dependent phosphorylation; 3) pure rat heart R-II (Mr = 54,000) and ovarian R-II52/51 exhibited distinct differences based on one- and two-dimensional peptide mapping; and 4) by two-dimensional sodium dodecyl sulfate-polyacrylamide gel electrophoresis pure R-II52/51 were resolved as three (rather than two) isoelectric variants which were clearly different from pure rat heart R-II54. Thus, the hormone-regulated form of R-II in rat ovarian granulosa cells appears to represent a gene product distinct from R-II54 in rat heart.     

A cAMP-binding phosphoprotein in Drosophila heads is similar to the regulatory subunit of the mammalian type II cAMP-dependent protein kinase

Cyclic AMP (cAMP)-dependent regulation of in vitro phosphorylation of several proteins including a cAMP-binding protein was studied with crude membrane and cytosol fractions from Drosophila heads. Phosphorylation of at least seven distinct proteins was enhanced in the presence of cAMP. Interestingly, however, the phosphorylation of a 56 kDa protein was apparently reduced by cAMP in the membrane but not in the cytosol fraction. The following data strongly indicate that the 56 kDa phosphoprotein in both membrane and cytosol fractions is a cAMP-binding protein, very similar to the regulatory subunit (RII) of a mammalian cAMP-dependent protein kinase, and that its binding to cAMP makes this protein very susceptible to the action of phosphatases: (i) cAMP highly stimulated the dephosphorylation of the 56 kDa phosphoprotein by the endogenous phosphatase in the membrane fraction. (ii) The dephosphorylation of a similar 56 kDa phosphoprotein in the cytosol fraction by an exogenous, cAMP-independent, alkaline phosphatase was also highly stimulated by cAMP. (iii) The 56 kDa phosphoprotein was covalently bound to cAMP by u.v. irradiation. (iv) The alkaline-phosphatase treatment reversibly converted this phosphoprotein to a 53 kDa non-phosphorylated protein. (v) The 53 kDa protein was selectively bound to cAMP-agarose and subsequently eluted by cAMP and high salt. (vi) This protein served as a substrate for the catalytic subunit of a mammalian cAMP-dependent protein kinase.     

Inhibitory effect of the regulatory subunit of type I cAMP-dependent protein kinase on phosphoprotein phosphatase

The regulatory subunit of type I cAMP-dependent protein kinase (RI) from rabbit skeletal muscle inhibited the activity of a low molecular weight phosphoprotein phosphatase. The inhibition was concentration and time dependent. A maximum inhibition, about 70%, was observed at 2 microM of RI with an apparent Ki of 0.8 microM. Inhibition was associated with a decrease in Vmax with no change in Km for substrate, phosphorylase a. On the other hand, cAMP-dependent protein kinase holoenzyme or its catalytic subunit was without any effect. The inhibition of phosphoprotein phosphatase by RI may be of physiological significance since the dissociation of cAMP-dependent protein kinase by cAMP would result in a simultaneous increase in the phosphorylation and decrease in the dephosphorylation rates of target proteins.