Characterization of a cyclic AMP-resistant Chinese hamster ovary cell mutant containing both wild-type and mutant species of type I regulatory subunit of cyclic AMP-dependent protein kinase

Protein kinase C and epidermal growth factor stimulation of Raf1 potentiates adenylyl cyclase type 6 activation in intact cells

Adenylyl cyclase type 6 (AC6) activity is inhibited by protein kinase C (PKC) in vitro; however, in intact cells, PKC activation does not inhibit the activity of transiently expressed AC6. To investigate the effects of PKC activation on AC6 activity in intact cells, we constructed human embryonic kidney (HEK) 293 cells that stably express wild-type AC6 (AC6-WT) or an AC6 mutant lacking a PKC and cyclic AMP-dependent protein kinase (PKA) phosphorylation site, Ser674 (AC6-S674A). In contrast to in vitro observations, we observed a PKC-mediated enhancement of forskolin- and isoproterenol-stimulated cyclic AMP accumulation in HEK-AC6 cells. Phorbol 12-myristate 13-acetate also potentiated cyclic AMP accumulation in cells expressing endogenous AC6, including Chinese hamster ovary cells and differentiated Cath.a differentiated cells. In HEK-AC6-S674A cells, the potentiation of AC6 stimulation was significantly greater than in cells expressing AC6-WT. The positive effect of PKC activation on AC6 activity seemed to involve Raf1 kinase because the Raf1 inhibitor 3-(3,5-dibromo-4-hydroxybenzylidene-5-iodo-1,3-dihydro-indol-2-one (GW5074) inhibited the PKC potentiation of AC6 activity. Furthermore, the forskolin-stimulated activity of a recombinant AC6 in which the putative Raf1 regulatory sites have been eliminated was not potentiated by activation of PKC. The ability of Raf1 to regulate AC6 may involve a direct interaction because AC6 and a constitutively active Raf1 construct were coimmunoprecipitated. In addition, we report that epidermal growth factor receptor activation also enhances AC6 signaling in a Raf1-dependent manner. These data suggest that Raf1 potentiates drug-stimulated cyclic AMP accumulation in cells expressing AC6 after activation of multiple signaling pathways.

Epac is a Rap1 guanine-nucleotide-exchange factor directly activated by cyclic AMP

Rap1 is a small, Ras-like GTPase that was first identified as a protein that could suppress the oncogenic transformation of cells by Ras. Rap1 is activated by several extracellular stimuli and may be involved in cellular processes such as cell proliferation, cell differentiation, T-cell anergy and platelet activation. At least three different second messengers, namely diacylglycerol, calcium and cyclic AMP, are able to activate Rap1 by promoting its release of the guanine nucleotide GDP and its binding to GTP. Here we report that activation of Rap1 by forskolin and cAMP occurs independently of protein kinase A (also known as cAMP-activated protein kinase). We have cloned the gene encoding a guanine-nucleotide-exchange factor (GEF) which we have named Epac (exchange protein directly activated by cAMP). This protein contains a cAMP-binding site and a domain that is homologous to domains of known GEFs for Ras and Rap1. Epac binds cAMP in vitro and exhibits in vivo and in vitro GEF activity towards Rap1. cAMP strongly induces the GEF activity of Epac towards Rap1 both in vivo and in vitro. We conclude that Epac is a GEF for Rap1 that is regulated directly by cAMP and that Epac is a new target protein for cAMP.

Cisplatin resistance in cyclic AMP-dependent protein kinase mutants

The emergence of cisplatin resistance poses a major problem to the successful treatment of a variety of human malignancies. Therefore, understanding the molecular mechanisms that underlie cisplatin resistance could significantly improve the clinical efficacy of this cytotoxic agent. Various studies have described that cellular sensitivity to cisplatin can be influenced by several signal transduction pathways. In this review, we examine the role of the cyclic AMP-dependent protein kinase (PKA) in the modulation of drug resistance in cancer. By a somatic mutant genetic approach, the role of PKA in the development of resistance to chemotherapeutic agents has been investigated. A series of mutants with decreased PKA activity was examined for their sensitivity to cisplatin. PKA mutants with defective regulatory (RIalpha) subunits, but not altered catalytic (C) subunits, exhibit increased resistance to cisplatin, as well as other DNA-damaging agents. Furthermore, since RIalpha subunit mutants show enhanced DNA repair we, therefore, hypothesize that functional inactivation of PKA may result in increased recognition and repair of cisplatin lesions. Alternatively, it seems likely that mutation of the RIalpha subunit may affect cellular sensitivity to various anticancer drugs, suggesting that the RIalpha subunit may have other physiological functions in addition to inhibiting the kinase activity of the C subunit. Therefore, exploitation of cyclic AMP levels or functional alteration of the R subunit may potentiate the cytotoxicity of chemotherapeutic agents and circumvent drug resistance in cancer. More importantly, the altered pattern and mechanism of drug resistance may offer the opportunity to investigate novel regulatory functions of the RIalpha subunit of PKA.

Characterization of a cAMP-dependent protein kinase mutant resistant to cisplatin

The signal transduction pathway of cAMP, mediated by the cAMP-dependent protein kinase (PKA), is involved in the regulation of metabolisms, cell growth and differentiation and gene expression. Isolated PKA mutants from Chinese hamster ovary (CHO) cells were used in our laboratory to study the role of cAMP in the development of drug resistance in cancer. We have found that PKA mutants harboring a defective regulatory (RI alpha) subunit, but not the catalytic (C) subunit, are more resistant to the chemotherapeutic drug cisplatin. To clarify the role of PKA in cisplatin resistance, we have performed a step-wise selection with a CHO RI alpha subunit mutant cell line, 10248, for further resistance to cisplatin. A representative clone (10248/CDDP(R)-5) was used for further characterization. These cisplatin-resistant PKA mutant cells remained refractory to cAMP-induced growth inhibition and had decreased PKA activity comparable to the parental 10248 mutant cells. Furthermore, 10248/CDDP(R)-5 also exhibited cross-resistance to the nitrogen mustard melphalan but maintained the same sensitivity as wild-type cells to non-DNA-damaging agents such as methotrexate. The mechanism of resistance may be due to increased DNA repair as assessed by the host cell reactivation assay. We speculate that mutation and functional inactivation of PKA may result in deregulated growth response to cAMP, as well as the acquisition of resistance to cisplatin and other DNA-damaging agents in cancer.

Signal transduction pathways modulated by the D2 subfamily of dopamine receptors

The D2 subfamily of dopamine receptors includes D2A, D2B, D3, and D4 dopamine receptors. These receptors activate cellular effector systems, principally through pertussis toxin-sensitive G-proteins. Historically, D2-like receptors in brain tissues were recognized as the dopamine receptor subtypes that inhibit adenylyl cyclase. Recent studies, reviewed here, have shown that multiple effector systems can be activated by these receptors, and the potential involvement of these in dopaminergic neutrotransmission is discussed.

Ablation of stimulation of a cAMP-responsive promoter in CHO cell lines defective in their cAMP-dependent protein kinase system

We have studied the requirement for an intact cAMP-dependent protein kinase (PKA) system to regulate cAMP-mediated gene transcription in Chinese hamster ovary (CHO) cells. Wild-type CHO cells and mutant CHO cell lines selected for their resistance to the growth inhibitory effect of 8-Br-cAMP and defective in their PKA system were transiently transfected with reporter plasmids containing 2.5 and 3.0 kb of the 5'-flanking sequence of the rat tyrosine aminotransferase (TAT) gene promoter. This segment of DNA contains no CRE-like sequences, yet wild-type transfectants exhibited a specific increase in TAT promoter activity following growth in medium containing 8-Br-cAMP. In CHO cell lines defective in their PKA, the transfected TAT promoter failed to respond to cAMP treatment. We conclude that an intact PKA system is necessary for the cAMP-mediated increase in TAT promoter activity in CHO cells and that there is no requirement for a CRE to see this effect.

Analysis of the dominance of mutations in cAMP-binding sites of murine type I cAMP-dependent protein kinase in activation of kinase from heterozygous mutant lymphoma cells

Structural lesions in cAMP-binding sites of regulatory (R) subunit of cAMP-dependent protein kinase caused identical increases in apparent constants for cyclic nucleotide-dependent kinase activation in preparations from cells that were hemizygous or heterozygous for mutant R1 subunit expression. No wild-type kinase activation was observed in extracts from heterozygous mutant cells. This "dominance" was investigated by characterizing expression of wild-type and mutant R1 subunits and properties of protein kinase from S49 mouse lymphoma cell mutants heterozygous for expression of wild-type R1 subunits and R1 subunits with a lesion (Glu200) that inactivates cAMP-binding site A. By both studies of cAMP dissociation and two-dimensional gel analysis, wild-type R subunits comprised about 35% of total R1 subunits in heterozygous mutants. Synthesis of wild-type and mutant R1 subunits was equivalent, but wild-type subunits were degraded preferentially. Hydroxylapatite chromatography revealed a novel R1 subunit-containing species from heterozygous mutant preparations whose elution behavior suggested a trimeric kinase consisting of an R1 subunit dimer and one catalytic (C) subunit. Wild-type R1 subunit was found only in dimer and "trimer" peaks; the tetrameric kinase peak contained only mutant R1 subunit. It is concluded that C subunit binds preferentially to mutant R1 subunit in heterozygous cells forming either tetrameric kinase with mutant R1 subunit homodimers or trimeric kinase with R1 subunit heterodimers. This preferential binding results both in suppression of wild-type kinase activation and differential stabilization of mutant R1 subunits.

Transfection of a mutant regulatory subunit gene of cAMP-dependent protein kinase causes increased drug sensitivity and decreased expression of P-glycoprotein

Wild-type Chinese hamster ovary (CHO) cells were transfected with a DNA clone (MT-REV, site A) carrying a mouse gene for a dominant mutant regulatory subunit (RI) gene of cAMP-dependent protein kinase (PKA) from S49 cells along with a marker for G418 resistance. G418-resistant transfectant clone R-2D1 was resistant to 8-Br-cAMP-induced growth inhibition and morphological changes. The cells also did not phosphorylate a 50-kDa protein after cAMP stimulation and had decreased PKA activity, both characteristics of PKA mutants. Northern blot analysis indicated that clone R-2D1 was actively transcribing the MT-REV (site A)-specific RNA. We also tested clone R-2D1 for sensitivity to certain natural product hydrophobic drugs and found increased sensitivity to several drugs including adriamycin. Hypersensitivity to these drugs has previously been shown by us to be a characteristic of a CHO PKA mutant cell line. Expression of the mutant RI gene is also associated with a decrease in expression of the multidrug resistance associated P-glycoprotein (gp170) mRNA and protein. These results show that the PKA mutant RI gene from S49 cells acts as a dominant mutation to reduce the total PKA activity in the CHO transfectants as it does in mouse S49 cells. This study also confirms that reduced PKA activity modulates the basal multidrug resistance of these cells, apparently by causing decreased expression of the mdr gene at the protein and mRNA level.

M2 subunit of ribonucleotide reductase is a target of cyclic AMP-dependent protein kinase

Cyclic AMP arrests T lymphocytes in the G1 phase of the cell cycle, and prolonged exposure results in cytolysis. Both of these effects require cyclic AMP-dependent protein kinase. We recently observed that some S49 mouse T lymphoma cell lines selected for hydroxyurea resistance were not arrested in G1 by cyclic AMP. Further analysis revealed that these cell lines were cyclic AMP-dependent protein kinase deficient, and conversely, other cyclic AMP-dependent protein kinase deficient cell lines not selected for hydroxyurea resistance were two- to threefold more hydroxyurea resistant. However, hydroxyurea is a specific inhibitor of ribonucleotide reductase and does not inhibit this kinase. We subsequently showed that cyclic AMP-dependent protein kinase will phosphorylate the M2 but not the M1 subunit of ribonucleotide reductase in vitro, and this phosphorylation will diminish CDP reductase activity. In vivo phosphorylation of M2 occurred under conditions similar to those that generate cell cycle arrest. We conclude that the M2 subunit of ribonucleotide reductase can be a target of cyclic AMP-dependent protein kinase. The phosphorylated enzyme has diminished activity, and this may play a role in cyclic AMP-induced lymphocyte cell cycle arrest.

Cyclic AMP-induced expression of the mouse lactate dehydrogenase-A promoter-cat fusion gene in Chinese hamster ovary wild-type cells, but not in cAMP-dependent protein kinase mutant cells

The promoter region of mouse lactate dehydrogenase-A gene was fused with the chloramphenicol acetyltransferase gene of Escherichia coli, and the expression of this fusion gene was induced by cyclic AMP in Chinese hamster ovary wild-type cells, but not in mutants affecting the regulatory or catalytic subunit of cAMP-dependent protein kinase.

Characterization of two mutants of the LLC-PK1 porcine kidney cell line affected in the catalytic subunit of the cAMP-dependent protein kinase

The catalytic (C) subunit activity of the cAMP-dependent protein kinase (cAMP-PK) from the mutant cell lines, FIB4 and FIB6, is only 10% compared with the parent cell line, LLC-PK1 [Jans and Hemmings (1986) FEBS Lett. 205, 127-131]. In order to understand the nature of the mutant phenotypes the cAMP-PK from parent and mutant cell lines was studied in more detail. Analysis of mutant cAMP-PK activity by ion-exchange chromatography revealed that kinase activity associated with type I holoenzyme of both FIB4 and FIB6 was only 5% parental, and the activity of the type II holoenzyme was about 20% parental. The type I regulatory (RI) subunits associated with the type I were also found to be reduced by 70-80% in both mutants, whereas the type II R subunit levels were similar to that of the parent. The residual kinase activity associated with the type I holoenzyme from FIB4 and FIB6 could not be activated by cAMP whereas the type II holoenzyme was activated by cAMP (Ka of 5.5 X 10(-8) M), and showed normal affinities for Kemptamide and ATP. A polyclonal antibody to the catalytic subunit was used to quantify the level of this protein in wild-type and mutant cells. This analysis showed that FIB4 and FIB6 had nearly normal levels of C subunit, suggesting that the C subunit synthesized by the mutants was mostly inactive. As both type I and type II cAMP-PK holoenzymes were abnormal, the most likely explanation of the mutant phenotype is a defect either in the structural gene for the C subunit or in an enzyme involved in its posttranslational processing. However, a second lesion affecting the RI subunit cannot be ruled out at this moment.

Molecular genetic analysis of cAMP-dependent protein kinase

Genetic evidence has been obtained indicating that the responsiveness of CHO cells to cAMP requires an intact cADepPK system. DNA carrying mutant RI and C subunit genes has been transferred to wild-type cells. Recipient cells carrying the DNA have been detected by selecting for expression of the phenotype for cAMP resistance. We are in the process of cloning a functional mutant RI subunit to use as a moveable genetic element that can confer cAMP resistance on recipient cells. This cloned gene should allow us to test hypotheses concerning the mechanism of cAMP regulation of transcription in mammalian cells.