Decreased expression of the type I isozyme of cAMP-dependent protein kinase in tumor cell lines of lung epithelial origin

A spontaneous transformant derived from a mouse lung epithelial cell line exhibited decreased cAMP-dependent protein kinase (PKA) activity. DEAE column chromatography demonstrated that this was caused by specific loss of the type I PKA isozyme (PKA I). Western immunoblot analysis indicated that indeed several mouse lung tumor-derived cell lines and spontaneous transformants of immortalized, nontumorigenic lung cell lines contained less PKA I regulatory subunit (RI) protein than normal cell lines. PKA II regulatory subunit protein differed only slightly among cell lines and showed no conspicuous trend between normal and neoplastic cells. The decrease in RI was apparently concomitant with decreased catalytic (C) subunit levels in neoplastic cells since no free catalytic subunit activity was detected by DEAE chromatography. Northern blot analysis using RI alpha and C alpha cDNA probes showed that the levels of RI alpha and C alpha mRNAs paralleled their intracellular protein concentrations; neoplastic cell lines contained significantly less RI alpha and C alpha mRNAs than the normal cell line. The decreased expression of both RI and C subunits therefore results in a net decrease of PKA I in neoplastic lung cells, an isozymic difference which may account for the differential effects of cAMP analogs on cell growth and differentiation in normal and neoplastic cells.     

Serotonin induces selective cleavage of the PKA RI subunit but not RII subunit in Aplysia neurons

PKA type I and type II are activated in Aplysia neurons by stimulation with serotonin (5-HT), which causes long-term facilitation (LTF). The proteolysis of the regulatory subunit (R) is thought important for the persistent activation of PKA, which is necessary to produce LTF. In this study, we report that the type I regulatory subunit (RI) and type II regulatory subunit (RII) are differentially regulated by proteolytic cleavage. RI, but not RII, was selectively cleaved after 5-HT treatment for 2h in Aplysia neurons. Interestingly, the proteasome inhibitor MG132 inhibited the cleavage of RI caused by 5-HT treatment in Aplysia neuron. Besides extracts from Aplysia ganglia treated with 5-HT cleaved (35)S-labeled RI synthesized in vitro, but not (35)S-labeled RII. This suggests that 5-HT induces the activation state of RI-specific proteolytic cleavage.     

Phosphodiesterases catalyze hydrolysis of cAMP-bound to regulatory subunit of protein kinase A and mediate signal termination

Although extensive structural and biochemical studies have provided molecular insights into the mechanism of cAMP-dependent activation of protein kinase A (PKA), little is known about signal termination and the role of phosphodiesterases (PDEs) in regulatory feedback. In this study we describe a novel mode of protein kinase A-anchoring protein (AKAP)-independent feedback regulation between a specific PDE, RegA and the PKA regulatory (RIα) subunit, where RIα functions as an activator of PDE catalysis. Our results indicate that RegA, in addition to its well-known role as a PDE for bulk cAMP in solution, is also capable of hydrolyzing cAMP-bound to RIα. Furthermore our results indicate that binding of RIα activates PDE catalysis several fold demonstrating a dual function of RIα, both as an inhibitor of the PKA catalytic (C) subunit and as an activator for PDEs. Deletion mutagenesis has localized the sites of interaction to one of the cAMP-binding domains of RIα and the catalytic PDE domain of RegA whereas amide hydrogen/deuterium exchange mass spectrometry has revealed that the cAMP-binding site (phosphate binding cassette) along with proximal regions important for relaying allosteric changes mediated by cAMP, are important for interactions with the PDE catalytic domain of RegA. These sites of interactions together with measurements of cAMP dissociation rates demonstrate that binding of RegA facilitates dissociation of cAMP followed by hydrolysis of the released cAMP to 5'AMP. cAMP-free RIα generated as an end product remains bound to RegA. The PKA C-subunit then displaces RegA and reassociates with cAMP-free RIα to regenerate the inactive PKA holoenzyme thereby completing the termination step of cAMP signaling. These results reveal a novel mode of regulatory feedback between PDEs and RIα that has important consequences for PKA regulation and cAMP signal termination.     

Human heart failure is accompanied by altered protein kinase A subunit expression and post-translational state

β-Adrenergic receptor blockade reduces total mortality and all-cause hospitalizations in patients with heart failure (HF). Nonetheless, β-blockade does not halt disease progression, suggesting that cAMP-dependent protein kinase (PKA) signaling downstream of β-adrenergic receptor activation may persist through unique post-translational states. In this study, human myocardial tissue was used to examine the state of PKA subunits. As expected, total myosin binding protein-C phosphorylation and Ser23/24 troponin I phosphorylation significantly decreased in HF. Examination of PKA subunits demonstrated no change in type II regulatory (RIIα) or catalytic (Cα) subunit expression, although site specific RIIα (Ser96) and Cα (Thr197) phosphorylation were increased in HF. Further, the expression of type I regulatory subunit (RI) was increased in HF. Isoelectric focusing of RIα demonstrated up to three variants, consistent with reports that Ser77 and Ser83 are in vivo phosphorylation sites. Western blots with site-specific monoclonal antibodies showed increased Ser83 phosphorylation in HF. 8-fluo-cAMP binding by wild type and phosphomimic Ser77 and Ser83 mutant RIα proteins demonstrated reduced Kd for the double mutant as compared to WT RIα. Therefore, failing myocardium displays altered expression and post-translational modification of PKA subunits that may impact downstream signaling.     

Deletion of type IIalpha regulatory subunit delocalizes protein kinase A in mouse sperm without affecting motility or fertilization.

Cyclic AMP stimulates sperm motility in a variety of mammalian species, but the molecular details of the intracellular signaling pathway responsible for this effect are unclear. The type IIalpha isoform of protein kinase A (PKA) is induced late in spermatogenesis and is thought to localize PKA to the flagellar apparatus where it binds cAMP and stimulates motility. A targeted disruption of the type IIalpha regulatory subunit (RIIalpha) gene allowed us to examine the role of PKA localization in sperm motility and fertility. In wild type sperm, PKA is found primarily in the detergent-resistant particulate fraction and localizes to the mitochondrial-containing midpiece and the principal piece. In mutant sperm, there is a compensatory increase in RIalpha protein and a dramatic relocalization of PKA such that the majority of the holoenzyme now appears in the soluble fraction and colocalizes with the cytoplasmic droplet. Unexpectedly the RIIalpha mutant mice are fertile and have no significant changes in sperm motility. Our results demonstrate that the highly localized pattern of PKA seen in mature sperm is not essential for motility or fertilization.     

Subcellular localization and biological actions of activated RSK1 are determined by its interactions with subunits of cyclic AMP-dependent protein kinase

Cyclic AMP (cAMP)-dependent protein kinase (PKA) and ribosomal S6 kinase 1 (RSK1) share several cellular proteins as substrates. However, to date no other similarities between the two kinases or interactions between them have been reported. Here, we describe novel interactions between subunits of PKA and RSK1 that are dependent upon the activation state of RSK1 and determine its subcellular distribution and biological actions. Inactive RSK1 interacts with the type I regulatory subunit (RI) of PKA. Conversely, active RSK1 interacts with the catalytic subunit of PKA (PKAc). Binding of RSK1 to RI decreases the interactions between RI and PKAc, while the binding of active RSK1 to PKAc increases interactions between PKAc and RI and decreases the ability of cAMP to stimulate PKA. The RSK1/PKA subunit interactions ensure the colocalization of RSK1 with A-kinase PKA anchoring proteins (AKAPs). Disruption of the interactions between PKA and AKAPs decreases the nuclear accumulation of active RSK1 and, thus, increases its cytosolic content. This subcellular redistribution of active RSK1 is manifested by increased phosphorylation of its cytosolic substrates tuberous sclerosis complex 2 and BAD by epidermal growth factor along with decreased cellular apoptosis.     

Molecular cloning and characterization of Ct-PKAR, a gene encoding the regulatory subunit of cAMP-dependent protein kinase in Colletotrichum trifolii

Colletotrichum trifolii is a plant pathogenic fungus causing alfalfa anthracnose. Prepenetration development, including conidial germination and appressorial formation, are requisite for successful infection. Pharmacological data from our laboratory indicated a role for a cAMP-dependent protein kinase (PKA) pathway during these early morphogenic transitions. Thus, the cloning and characterization of the genes for PKA catalytic and regulatory subunits were undertaken to more precisely determine the function of PKA during C. trifolii pathogenic growth and development. In this report, the cloning, sequencing, and partial characterization of the gene encoding the regulatory subunit of cAMP-dependent protein kinase (Ct-PKAR) is described. An open reading frame of 1,212 bp containing 404 predicted amino acid residues was identified. Database analysis revealed that the deduced amino acid sequence of Ct-PKAR shares considerable similarity with that of PKA regulatory subunits in other organisms, particularly in the conserved regions. Furthermore, the Ct-PKAR protein is classified as a type II regulatory subunit based on the presence of the hallmark autophosphorylation site. Southern blot analysis indicated that Ct-PKAR is a single-copy gene. Northern blot analysis showed that the expression of Ct-PKAR is developmentally regulated. Ct-PKAR was shown to be a functional regulatory subunit of PKA by complementating the Neurospora crassa mcb mutant, which has a temperature-sensitive mutation in the regulatory subunit of PKA. Received: 26 August 1998 / Accepted: 30 December 1998     

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.     

R-subunit isoform specificity in protein kinase A: distinct features of protein interfaces in PKA types I and II by amide H/2H exchange mass spectrometry

The two isoforms (RI and RII) of the regulatory (R) subunit of cAMP-dependent protein kinase or protein kinase A (PKA) are similar in sequence yet have different biochemical properties and physiological functions. To further understand the molecular basis for R-isoform-specificity, the interactions of the RIIβ isoform with the PKA catalytic (C) subunit were analyzed by amide H/²H exchange mass spectrometry to compare solvent accessibility of RIIβ and the C subunit in their free and complexed states. Direct mapping of the RIIβ-C interface revealed important differences between the intersubunit interfaces in the type I and type II holoenzyme complexes. These differences are seen in both the R-subunits as well as the C-subunit. Unlike the type I isoform, the type II isoform complexes require both cAMP-binding domains, and ATP is not obligatory for high affinity interactions with the C-subunit. Surprisingly, the C-subunit mediates distinct, overlapping surfaces of interaction with the two R-isoforms despite a strong homology in sequence and similarity in domain organization. Identification of a remote allosteric site on the C-subunit that is essential for interactions with RII, but not RI subunits, further highlights the considerable diversity in interfaces found in higher order protein complexes mediated by the C-subunit of PKA.     

Splicing Factor Arginine/Serine-rich 17A (SFRS17A) Is an A-kinase Anchoring Protein That Targets Protein Kinase A to Splicing Factor Compartments

Protein kinase A (PKA) is targeted to distinct subcellular localizations by specific protein kinase A anchoring proteins (AKAPs). AKAPs are divided into subclasses based on their ability to bind type I or type II PKA or both. Dual-specificity AKAPs were recently reported to have an additional PKA binding determinant called the RI specifier region. A bioinformatic search with the consensus RI specifier region identified a novel AKAP, the splicing factor arginine/serine-rich 17A (SFRS17A). Here, we show by a variety of protein interaction assays that SFRS17A binds both type I and type II PKA in vitro and inside cells, demonstrating that SFRS17A is a dual-specific AKAP. Moreover, immunofluorescence experiments show that SFRS17A colocalizes with the catalytic subunit of PKA as well as the splicing factor SC35 in splicing factor compartments. Using the E1A minigene splicing assay, we found that expression of wild type SFRS17A conferred regulation of E1A alternative splicing, whereas the mutant SFRS17A, which is unable to bind PKA, did not. Our data suggest that SFRS17A is an AKAP involved in regulation of pre-mRNA splicing possibly by docking a pool of PKA in splicing factor compartments.     

Isozymes of cyclic AMP-dependent protein kinases (PKA) in human lymphoid cell lines: Levels of endogenous cAMP influence levels of PKA subunits and growth in lymphoid cell lines

Activation of the cAMP signaling pathway in lymphoid cells is known to inhibit cell proliferation of T and B cells as well as cytotoxicity of natural killer (NK) cells. In order to find suitable model systems to study cAMP-mediated processes, we have examined the expression of cAMP-dependent protein kinase (PKA), endogenous levels of cAMP, and cell proliferation in eight cell lines of B lineage origin, four cell lines of T lineage origin, and normal human B and T cells. We demonstrated that the expression of mRNA and protein for one of the regulatory (R) subunits of PKA (RIα) was present in all the cells investigated, in contrast to the other R subunits (RIβ, RIIα, and RIIβ). Furthermore, three T cell lines and one B cell line expressed only RIα and C, implying these cells to contain solely PKA type I. Moreover, for the RI subunit, we observed an apparent reciprocal relationship between levels of mRNA and protein. Generally, RIα protein was low in cell lines where mRNA was elevated and vice versa. This was not the case for the RII subunits, where high levels of mRNA were associated with elevated levels of protein. Interestingly, we demonstrated an inverse correlation between levels of endogenous cAMP and cell growth as determined by [³H]-thymidine incorporation and cell-doubling rate (P < 0.05). Taken together, our results demonstrate great differences in PKA isozyme composition, which should be taken into consideration when using lymphoid cell lines as model system for cAMP/PKA effects in normal lymphocytes. J. Cell. Physiol. 177:85–93, 1998. © 1998 Wiley-Liss, Inc.     

Major 56,000-dalton, soluble phosphoprotein present in bovine sperm is the regulatory subunit of a type II cAMP-dependent protein kinase

It has been shown that cAMP-dependent phosphorylation of a soluble sperm protein is important for the initiation of flagellar motion. The suggestion has been made that this motility initiation protein, named axokinin, is the major 56,000-dalton phosphoprotein present in both dog sperm and in other cells containing axokinin-like activity. Since the regulatory subunit of a type II cAMP-dependent protein kinase is a ubiquitous cAMP-dependent phosphoprotein of similar subunit molecular weight as reported for axokinin, we have addressed the question of how many soluble 56,000-dalton cAMP-dependent phosphoproteins are present in mammalian sperm. We report that in bovine sperm cytosol, the ratio of the type I to type II cAMP-dependent protein kinase is approximately 1:1. The type II regulatory subunit is related to the non-neural form of the enzyme and undergoes a phosphorylation-dependent electrophoretic mobility shift. The apparent subunit molecular weights of the phospho and dephospho forms are 56,000 and 54,000 daltons, respectively. When bovine sperm cytosol or detergent extracts are phosphorylated in the presence of catalytic subunits, two major proteins are phosphorylated and have subunit molecular weights of 56,000 and 40,000 daltons. If, however, the type II regulatory subunit (RII) is quantitatively removed from these extracts using either immobilized cAMP or an anti-RII monoclonal affinity column, the ability to phosphorylate the 56,000- but not 40,000-dalton polypeptide is lost. These data suggest that the major 56,000 dalton cAMP-dependent phosphoprotein present in bovine sperm is the regulatory subunit of a type II cAMP-dependent protein kinase and not the motility initiator protein, axokinin.     

Haploinsufficiency at the protein kinase A RI alpha gene locus leads to fertility defects in male mice and men

Carney complex (CNC) is a familial multiple neoplasia syndrome characterized by spotty skin pigmentation, cardiac and cutaneous myxomas, and endocrine tumors. CNC is inherited as an autosomal dominant trait and is transmitted with greater frequency by women vs. men. Nearly two thirds of CNC patients are heterozygous for inactivating mutations in the gene encoding the protein kinase A (PKA) type I alpha regulatory subunit (RI alpha), PRKAR1. We report here that male mice heterozygous for the Prkar1a gene have severely reduced fertility. Sperm from Prkar1a heterozygous mice are morphologically abnormal and reduced in number. Genetic rescue experiments reveal that this phenotype results from elevated PKA catalytic activity in germ cells as early as the pachytene stage of spermatogenesis. Consistent with this defect in the male mutant mice, sperm from CNC patients heterozygous for PRKAR1A mutations were also found to be morphologically aberrant and decreased in number. We conclude that unregulated PKA activity in male meiotic or postmeiotic germ cells leads to structural defects in mature sperm and results in reduced fertility in mice and humans, contributing to the strikingly reduced transmission of PRKAR1A inactivating mutations by male patients with CNC.     

Signaling the signal, cyclic AMP-dependent protein kinase inhibition by insulin-formed H2O2 and reactivation by thioredoxin

Catecholamines in adipose tissue promote lipolysis via cAMP, whereas insulin stimulates lipogenesis. Here we show that H(2)O(2) generated by insulin in rat adipocytes impaired cAMP-mediated amplification cascade of lipolysis. These micromolar concentrations of H(2)O(2) added before cAMP suppressed cAMP activation of type IIbeta cyclic AMP-dependent protein kinase (PKA) holoenzyme, prevented hormone-sensitive lipase translocation from cytosol to storage droplets, and inhibited lipolysis. Similarly, H(2)O(2) impaired activation of type IIalpha PKA holoenzyme from bovine heart and from that reconstituted with regulatory IIalpha and catalytic alpha subunits. H(2)O(2) was ineffective (a) if these PKA holoenzymes were preincubated with cAMP, (b) if added to the catalytic alpha subunit, which is active independently of cAMP activation, and (c) if the catalytic alpha subunit was substituted by its C199A mutant in the reconstituted holoenzyme. H(2)O(2) inhibition of PKA activation remained after H(2)O(2) elimination by gel filtration but was reverted with dithiothreitol or with thioredoxin reductase plus thioredoxin. Electrophoresis of holoenzyme in SDS gels showed separation of catalytic and regulatory subunits after cAMP incubation but a single band after H(2)O(2) incubation. These data strongly suggest that H(2)O(2) promotes the formation of an intersubunit disulfide bond, impairing cAMP-dependent PKA activation. Phylogenetic analysis showed that Cys-97 is conserved only in type II regulatory subunits and not in type I regulatory subunits; hence, the redox regulation mechanism described is restricted to type II PKA-expressing tissues. In conclusion, phylogenetic analysis results, selective chemical behavior, and the privileged position in holoenzyme lead us to suggest that Cys-97 in regulatory IIalpha or IIbeta subunits is the residue forming the disulfide bond with Cys-199 in the PKA catalytic alpha subunit. A new molecular point for cross-talk among heterologous signal transduction pathways is demonstrated.     

Differential binding of cAMP-dependent protein kinase regulatory subunit isoforms Ialpha and IIbeta to the catalytic subunit

Limited trypsin digestion of type I cAMP-dependent protein kinase holoenzyme results in a proteolytic-resistant Delta(1-72) regulatory subunit core, indicating that interaction between the regulatory and catalytic subunits extends beyond the autoinhibitory site in the R subunit at the NH(2) terminus. Sequence alignment of the two R subunit isoforms, RI and RII, reveals a significantly sequence diversity at this specific region. To determine whether this sequence diversity is functionally important for interaction with the catalytic subunit, specific mutations, R133A and D328A, are introduced into sites adjacent to the active site cleft in the catalytic subunit. While replacing Arg(133) with Ala decreases binding affinity for RII, interaction between the catalytic subunit and RI is not affected. In contrast, mutant C(D328A) showed a decrease in affinity for binding RI while maintaining similar affinities for RII as compared with the wild-type catalytic subunit. These results suggest that sequence immediately NH(2)-terminal to the consensus inhibition site in RI and RII interacts with different sites at the proximal region of the active site cleft in the catalytic subunit. These isoform-specific differences would dictate a significantly different domain organization in the type I and type II holoenzymes.     

PKA-I holoenzyme structure reveals a mechanism for cAMP-dependent activation

Protein kinase A (PKA) holoenzyme is one of the major receptors for cyclic adenosine monophosphate (cAMP), where an extracellular stimulus is translated into a signaling response. We report here the structure of a complex between the PKA catalytic subunit and a mutant RI regulatory subunit, RIalpha(91-379:R333K), containing both cAMP-binding domains. Upon binding to the catalytic subunit, RI undergoes a dramatic conformational change in which the two cAMP-binding domains uncouple and wrap around the large lobe of the catalytic subunit. This large conformational reorganization reveals the concerted mechanism required to bind and inhibit the catalytic subunit. The structure also reveals a holoenzyme-specific salt bridge between two conserved residues, Glu261 and Arg366, that tethers the two adenine capping residues far from their cAMP-binding sites. Mutagenesis of these residues demonstrates their importance for PKA activation. Our structural insights, combined with the mutagenesis results, provide a molecular mechanism for the ordered and cooperative activation of PKA by cAMP.     

Molecular basis for isoform-specific autoregulation of protein kinase A

Protein kinase A (PKA) isozymes are distinguishable by the inhibitory pattern of their regulatory (R) subunits with RI subunits containing a pseudophosphorylation P(0)-site and RII subunits being a substrate. Under physiological conditions, RII does not inhibit PrKX, the human X chromosome encoded PKA catalytic (C) subunit. Using a live cell Bioluminescence Resonance Energy Transfer (BRET) assay, Surface Plasmon Resonance (SPR) and kinase activity assays, we identified the P(0)-position of the R subunits as the determinant of PrKX autoinhibition. Holoenzyme formation only takes place with an alanine at position P(0), whereas RI subunits containing serine, phosphoserine or aspartate do not bind PrKX. Surprisingly, PrKX reversibly associates with RII when changing P(0) from serine to alanine. In contrast, PKA-Calpha forms holoenzyme complexes with all wildtype and mutant R subunits; however, holoenzyme re-activation by cAMP is severely affected. Only PKA type II or mutant PKA type I holoenzymes (P(0): Ser or Asp) are able to dissociate fully upon maximally elevated intracellular cAMP. The data are of particular significance for understanding PKA isoform-specific activation patterns in living cells.