Mutations causing charge alterations in regulatory subunits of the cAMP-dependent protein kinase of cultured S49 lymphoma cells.

Two-dimensional polyacrylamide gel electrophoresis is used to visualize the regulatory subunit of cAMP-dependent protein kinase from cultured S49 mouse lymphoma cells and to demonstrate its in vivo phosphorylation. Regulatory subunits from mutant cells with altered kinases exhibit at least two patterns of charge shifts consistent with substitutions of single amino acids. The direct demonstration of structural alteration of this protein provides strong evidence for structural gene mutation in this cultured cell system. While mutant and wild-type gene products co-exist in the mutant cells, there is apparently preferential expression and phosphorylation of mutant subunit in these heterozygotes.     

Kinase-negative mutants of S49 mouse lymphoma cells carry a trans-dominant mutation affecting expression of cAMP-dependent protein kinase.

Kinase-negative mutants of S49 mouse lymphoma cells are pleiotropically negative for all known cAMP-mediated responses of S49 cells and yield cell extracts which are deficient in cAMP binding activity and devoid of cAMP-dependent protein kinase activity. In hybrids between kinase-negative and wild-type cells, the mutant phenotype is dominant: the tetraploid hybrids have reduced cAMP-binding activity and undetectable cAMP-dependent kinase activity. The mutant phenotype is attributable to neither a soluble inhibitor of kinase catalytic subunit, nor a defective kinase regulatory subunit acting as an inhibitor, nor a defective catalytic subunit which sequesters regulatory subunits in inactive complexes. We propose that these mutants carry trans-dominant lesions in a regulatory locus responsible for setting intracellular levels of kinase expression.     

Cell-free heterologous desensitization of adenylyl cyclase in S49 lymphoma cell membranes mediated by cAMP-dependent protein kinase

We have examined the cell-free heterologous desensitization of adenylyl cyclase in plasma membrane preparations from S49 wild-type (WT) and kin- cells (which lack cAMP-dependent protein kinase) incubated with purified catalytic subunit of cAMP-dependent protein kinase (cA.PKc). cA.PKc caused a rapid (t1/2 = 40 s) decrease in the hormone responsiveness of adenylyl cyclase in the WT membrane preparations that mimicked the intact cell heterologous desensitization; that is, there was an increase in the Kact for both epinephrine and prostaglandin E1 (PGE1) stimulations of adenylyl cyclase induced at the receptor level because neither forskolin- nor NaF-stimulated activity was affected. The desensitization was independent of agonist occupancy of the receptor, and the effects were blocked both by the active fragment (amino acids 5-22) of the specific inhibitor of cA.PK and by p[NH]ppA. cA.PKc treatment of kin- membranes resulted in a heterologous desensitization that resembled the effects of WT adenylyl cyclase, with the exception that forskolin-stimulated activity was also reproducibly decreased by 24%. cA.PKc had no effect on WT membranes isolated from cells that had previously undergone maximal heterologous desensitization during treatment with 10 microM forskolin. In contrast, cA.PKc-induced heterologous desensitization of kin- membranes was additive with the epinephrine-induced homologous desensitization of intact cells. Cell-free desensitizations were reversed by incubation of membranes with cA.PKc and ADP, conditions that drive the kinase reaction backward. The similarities of our cell-free cA.PKc-mediated heterologous desensitization of adenylyl cyclase with the intact cell desensitization support our hypothesis that heterologous desensitization of the WT lymphoma cells is mediated by cA.PK via a mechanism independent of homologous desensitization.     

Revertants of a trans-dominant S49 mouse lymphoma mutant that affects expression of cAMP-dependent protein kinase

Phenotypic revertants were isolated from an S49 mouse lymphoma tissue culture cell mutant that lacks cAMP-dependent protein kinase (cA-PK) activity (kin-). The mutant phenotype is trans-dominant and results from a lesion that probably lies outside the cA-PK subunit structural genes. The nature of the event that produces the kin- phenotype is unknown. However, the mechanism that is responsible for its behavior is genetically encoded because: spontaneous revertants arise at low frequency; reversion frequency is increased by mutagen treatment; mutagen-specific classes of revertant phenotypes are induced; and some revertants are temperature-sensitive for expression of cA-PK subunit polypeptides. Additional evidence is provided that argues against structural lesions in cA-PK catalytic (C) subunits as explanatory of the kin- phenotype. Kin- cells do not express an immunologically detectable C polypeptide, whereas C expression is restored in revertant cells. Revertants in which phenotype and cA-PK activity levels are only partially restored to that of wild-type cells contain a commensurately reduced amount of C polypeptide. Finally, the structure of C polypeptide in partial revertants is unaltered from that of wild-type C. The evidence supports the hypothesis that the kin- lesion defines a regulatory gene responsible for setting intracellular levels of cA-PK C subunit expression.     

Determinants of ligand binding to cAMP-dependent protein kinase

Protein kinases are essential for the regulation of cellular growth and metabolism. Since their dysfunction leads to debilitating diseases, they represent key targets for pharmaceutical research. The rational design of kinase inhibitors requires an understanding of the determinants of ligand binding to these proteins. In the present study, a theoretical model based on continuum electrostatics and a surface-area-dependent nonpolar term is used to calculate binding affinities of balanol derivatives, H-series inhibitors, and ATP analogues toward the catalytic subunit of cAMP-dependent protein kinase (cAPK or protein kinase A). The calculations reproduce most of the experimental trends and provide insight into the driving forces responsible for binding. Nonpolar interactions are found to govern protein-ligand affinity. Hydrogen bonds represent a negligible contribution, because hydrogen bond formation in the complex requires the desolvation of the interacting partners. However, the binding affinity is decreased if hydrogen-bonding groups of the ligand remain unsatisfied in the complex. The disposition of hydrogen-bonding groups in the ligand is therefore crucial for binding specificity. These observations should be valuable guides in the design of potent and specific kinase inhibitors.     

A cAMP-dependent protein kinase is present in differentiating Dictyostelium discoideum cells

We demonstrate the occurrence of a cAMP-dependent protein kinase in Dictyostelium discoideum cells at the terminal stage of differentiation. A cAMP-binding component was purified to homogeneity by affinity chromatography. This subunit inhibits the activity of purified catalytic subunit from beef heart protein kinase; the inhibition is reversed upon addition of cAMP. The protein is highly specific for cAMP and has a dissociation constant of 4 nM. The isolated regulatory subunit is a monomer of 39 K, with a sedimentation coefficient of 3.5S and a frictional coefficient of 1.24. The differences between this regulatory subunit and regulatory subunits of protein kinases from other sources are discussed.     

The S49 Kin- cell line transcribes and translates a functional mRNA coding for the catalytic subunit of cAMP-dependent protein kinase

The S49 mouse lymphoma mutant cell line Kin- is resistant to the cytotoxic effects of elevated cAMP levels, has no detectable cAMP-dependent protein kinase activity, and has depressed levels of cAMP-binding regulatory subunits. We demonstrate that although the Kin- cell line lacks detectable catalytic subunit protein, these cells express wild-type levels of mRNA for both C alpha and C beta catalytic subunit isoforms. Translation of C alpha mRNA appears to be normal in the Kin- cell, based on the observation that C alpha mRNA associates with large polyribosomes in both wild-type and Kin- cells. We cloned the C alpha cDNA from Kin- cells and show that its transient expression in another cell type leads to activation of a cAMP-sensitive luciferase reporter gene, suggesting that functional C alpha protein is made. In addition to having catalytic activity, the C alpha subunit from Kin- cells is inhibited in the presence of mouse RI alpha regulatory subunit, indicating that formation of the holoenzyme complex is normal. We suggest that the mutation responsible for the Kin- phenotype is in a cellular component that directly or indirectly causes Kin- catalytic subunit protein to be degraded rapidly.     

Three different genes in S. cerevisiae encode the catalytic subunits of the cAMP-dependent protein kinase

We have isolated three genes (TPK1, TPK2, and TPK3) from the yeast S. cerevisiae that encode the catalytic subunits of the cAMP-dependent protein kinase. Gene disruption experiments demonstrated that no two of the three genes are essential by themselves but at least one TPK gene is required for a cell to grow normally. Comparison of the predicted amino acid sequences of the TPK genes indicates conserved and variable domains. The carboxy-terminal 320 amino acid residues have more than 75% homology to each other and more than 50% homology to the bovine catalytic subunit. The amino-terminal regions show no homology to each other and are heterogeneous in length. The TPK1 gene carried on a multicopy plasmid can suppress both a temperature-sensitive ras2 gene and adenylate cyclase gene.     

Nuclear translocation of cAMP-dependent protein kinase

A study was made of nuclear translocation of cAMP-dependent protein kinase and its subunits, as well as of the binding of these proteins to metaphase chromosomes. The CHO cell cultures were treated with ³H-labelled protein kinase and its subunits. The results indicate that cAMP-dependent protein kinase became translocated into the nucleus in a dissociated state and that the subunits have specific binding sites on chromatin. Transformation of normal mouse fibroblasts by virus SV40 interferes with the nuclear translocation of the regulatory subunit. The process is restored when the level of cAMP in the system is increased. Binding of the regulatory subunit to metaphase chromosomes of cells transformed by virus SV40 does not change. In the case of spontaneous cancer (KB cells) translocation of the regulatory subunit remains unaffected, whereas acceptance of the protein by the metaphase chromosomes is impeded. The results of this work suggest that compartmentalization of cAMP-dependent protein kinase—and particularly of its regulatory subunit—in the cell is highly significant for cellular processes. Disorders arising as a result of neoplastic transformation involve changes in nuclear translocation of the regulatory subunit and in its binding to the structural elements of the genome.     

Nuclear proteins--substrates for cAMP-dependent protein kinase

The phosphorylation of nuclear proteins of porcine brain cAMP-dependent protein kinase was studied. Some nuclear proteins after extraction from the nuclei served as substrates for protein kinase. Lysine-rich histones H1, H2a and H2b were found to accept phosphate during chromatin phosphorylation by cAMP-dependent protein kinase. Phosphorylation of intact nuclei revealed that in such a system only histone H1 is a substrate for cAMP-dependent protein kinase. In the presence of DNA the histones are phosphorylated by cAMP-dependent protein kinase in a different manner. It was concluded that DNA can determine the accessibility of protein substrates for the catalytic subunit of cAMP-dependent protein kinase.     

cAMP-dependent protein kinase from Dictyostelium discoideum

The cAMP-dependent protein kinase (cAK) from Dictyostelium discoideum is an enzyme composed of one catalytic and one regulatory subunit. Upon binding of cAMP, the holoenzyme dissociates to liberate free active catalytic subunits. The cAK is developmentally regulated, ranging from very little activity in vegetative cells to maximal expression in postaggregative cells. Although there is no immunological cross-reaction between the subunits of cAKs from Dictyostelium and from other organisms, they share several biochemical properties. A complete cDNA for the regulatory subunit has been cloned and sequenced. Only one copy of the gene for the regulatory subunit is present per haploid genome. On the basis of the comparison of the structure of the cAK from Dictyostelium with its counterparts in yeast and higher eukaryotes, we propose a model for the evolution of cyclic-nucleotide-binding proteins.     

cAMP-dependent protein kinase in sea urchin embryos

cAMP-dependent protein kinase in the supernatant fraction of the homogenate of sea urchin eggs and embryos obtained by centrifugation at 105,000g was investigated in the present study. In the previous report, the dissociation constant between cAMP-binding proteins and cAMP changed during the development. This suggests that the nature of cAMP-dependent protein kinase, which has been well established to be the major cAMP receptor, changes during the development. In the present study, four protein kinases were separated through DEAE-cellulose column from the supernatant of unfertilized egg homogenate. One of them was cAMP-dependent protein kinase. The others were cAMP-independent ones. One among them was phosvitin kinase, and the others were not identified at present. The activity of cAMP-dependent protein kinase gradually increased during a period from fertilization to the swimming blastula stage. During this period, cleavages occurred at a high rate, and the rate decreased after hatching out. Thus, it is supposed that cAMP-dependent protein kinase in the supernatant may take a part in the mechanism of cleavage. The activity, however, became very low at the mesenchyme blastula, the gastrula, and the pluteus stages. cAMP-binding capacity was observed in the sedimentable fraction and the supernatant fraction, respectively, obtained by 105,000g centrifugation at all stages examined. If the structure-bound cAMP-binding protein is also cAMP-dependent protein kinase, it may play different roles in the mechanism of development.     

Comparison of protein phosphorylation patterns produced in adrenal cells by activation of cAMP-dependent protein kinase and Ca-dependent protein kinase

Bovine adrenal fasciculata cells, exposed to either ACTH or AII, synthesize glucocorticoids at an enhanced rate. It is generally accepted that the signaling pathways triggered by these two peptides are not identical. ACTH presumably acts via a cAMP-dependent protein kinase (PKA) and AII, via a calcium-dependent protein kinase. We have found that either peptide hormone stimulates synthesis of a mitochondrial phosphoprotein pp37, leading to accumulation of its proteolytically processed products pp30 and pp29. On the basis of a number of criteria, this 37 kDa protein is the bovine homolog of the 37 kDa protein that we have characterized in rodent steroidogenic tissue (Epstein L. F. and Orme-Johnson N. R.: J. Biol. Chem 266 (1991) 19,739–19,745). Further, bovine pp37 is phosphorylated when PKA or protein kinase C (PKC) is activated directly by (Bu)₂cAMP or PMA, respectively. These studies indicate that either pp37 is a common substrate for PKA and PKC in these cells or there is a common downstream kinase, which is activated by exposure to either ACTH or AII. Rat adrenal glomerulosa cells, exposed to either ACTH or AII, show an enhanced rate of mineralocorticoid synthesis. As for bovine fasciculata cells, it is thought that the signaling pathway triggered by ACTH differs from that triggered by AII. As we found for bovine fasciculata, pp37 is phosphorylated when the rat cells are exposed to either peptide hormone. However, in contrast to the finding for bovine fasciculata, while exposure of the rat glomerulosa cells to (Bu)₂cAMP does cause the synthesis of pp37, exposure of the cells to PMA does not. Taken together, these findings provide further evidence that the subcellular signaling events, triggered by the action of AII on bovine adrenal fasciculata and rat adrenal glomerulosa cells, differ. Further, the fact, that pp37 is phosphorylated only when the rate of steroidogenesis is enhanced, reaffirms its potential involvement in the signaling pathway that causes stimulation of steroid hormone biosynthesis.     

Effect of acidosis on heart cAMP-dependent protein kinase.

The effect of acidosis on cAMP-dependent protein kinase activity in perfused hearts from normal and reserpinized rats has been investigated. The results were compared to the effect of acidosis on myocardial contractility under the same conditions. The results showed that acidosis increases the cAMP-dependent protein kinase activity in normal hearts. This increase was abolished when the hearts were depleted of norepinephrine by previous treatment with reserpine. As regards myocardial contractility, there was a similar decrease by acidosis either in normal hearts with increased cAMP-dependent protein kinase activity or in reserpinized hearts in which the increase in protein kinase activity was prevented. Two alternative hypotheses are suggested: (1) a dissociation between contractility and cAMP levels, or (2) a "blockade" by acidosis of the mechanical effect of increasing cAMP-dependent protein kinase activity.     

Cooperative interactions of protein kinase C and cAMP-dependent protein kinase systems in human promyelocytic leukemia HL60 cells

Interactions of protein kinase C (PKC) and cAMP-dependent protein kinase (PKA) systems were investigated in HL60 cells. It was found that the differentiating effects of 12-O-tetradecanoylphorbol-13-acetate (TPA) were potentiated by dibutyryl cAMP (dbcAMP) or prostaglandin E2 (PGE2). In addition, dbcAMP or PGE2 inhibited TPA-induced binding of PKC to plasma membrane, leading to decreased protein phosphorylation, and promoted subsequent redistribution of enzyme to the nuclear membrane region. The findings are consistent with the hypothesis that PKC and PKA systems regulate cooperatively the phenotypical differentiation of leukemic cells.