Protein Kinase A Activity Research Articles

Mapping myocyte microdomains with optogenetic cAMP signaling

Recent advances in biosensor and optically based techniques have provided a map of the subcellular regions that dictate myocyte behavior. Microdomain level changes of cyclic adenosine 3’5’ monophosphate (cAMP) signaling are known to impact the progression of cardiovascular disease. Yet, tools to direct these site‐specific interactions are limited. To address this issue, we have applied a set of optogenetic protein species with the spatiotemporal resolution necessary to direct cAMP signaling at distinct intracellular sites. We hypothesize that applying these proteins to a cardiac cell system will help resolve the relationship between cAMP microdomain signaling and cardiac cell behavior.Photoactivation studies have been conducted using optogenetic analogues of adenylate cyclase and protein kinase A (PKA) in the H9c2 cell model. Expression and subcellular localization of these light responsive proteins is characterized by live cell microscopy in this cardiac cell line. Site‐specific impacts of signaling are quantified using a genetically encoded PKA activity biosensor as well as pharmacological agonists/antagonists for cAMP signaling mediators and effectors.Results indicate that global cAMP production, through a light activatable adenylate cyclase (bPAC), leads to phosphorylation of a PKA reporter anchored at the outer mitochondrial membrane and plasma membrane. Reporters with nuclear localization do not show this phosphorylation. Experiments validate the expression and recruitment of a light directed protein kinase A ‘optogenetic switch’ analog in cardiac cells. The expression and recruitment are confirmed with live cell microscopy and demonstrate a unique ability to direct PKA activity and retention to specific intracellular subdomains. The impact of this signaling on microdomain organization as well as the site‐specific impacts of light directed PKA microdomain recruitment on cell proliferation, size as a function of biomass, and cell viability compared are considered. This is done in relationship to non illuminated (dark) and catalytically dead optogenetic protein analog controls.We conclude from these results that light directed signaling in cardiac myocytes can provide a site‐specific view of intracellular signaling cascades. The application of this approach represents a ‘first step’ in creating therapies that address the microdomain signaling disruptions associated with cardiac disease.

Protein Kinase A (PKA) as a Master Regulator of the Early Metabolic Reprogramming in Bone Metastatic Prostate Cancer Cells

PURPOSE The arrival of metastatic prostate cancer (PCa) tumor cells to the bone niche requires a metabolic adaptation. We sought to identify metabolic dysregulations fueling PCa metastasis, modulated by bone secreted factors. METHODS By an indirect co-culture system of PCa (PC3) and bone progenitors (MC3T3, pre-osteoblasts, or Raw 264.7, pre-osteoclasts) we assessed the transcriptome of PC3 cells modulated by soluble factors released from bone precursors. We validated the transcriptional profile of metabolic genes in open-access transcriptomic datasets. We performed an Ingenuity Pathway Analysis (IPA) to delineate the regulators of these metabolic genes. Bone secretome was profiled on the conditioned media (CM) by ESI-MS/MS. RESULTS PC3 cells co-cultured with bone progenitors displayed an activation of lipidic categories, including PPAR-signaling and fat absorption/digestion. Principal Component and Unsupervised Clustering analyses using transcriptomic data from human PCa and bone metastatic samples (GSE74685) showed that the metabolic genes deregulated in PC3 accurately clustered samples in primary tumor or bone metastasis. Moreover, four lipid-associated genes, PPARA, VDR, SLC16A1 and GPX1, were associated with a shorter survival time (SU2C-PCF dataset), and were independent risk-predictors of death ( P < .05). An IPA revealed that these genes are regulated by the Protein Kinase A (PKA). Accordingly, PC3 cells treated with the CM of the co-culture presented a decreased ATP content compared to the treatment with the CM of PC3 grown alone, which was restored upon PKA inhibition. Finally, the secretome analysis revealed soluble factors secreted by bone progenitors (Col1a1, Fn1) which could regulate PKA activity. CONCLUSION We identified a novel lipid-associated gene signature important for metastatic PCa, triggered by the dialogue with bone cells. Moreover, PKA could regulate this signature in response to bone-secreted factors reprogramming the metabolic phenotype of metastatic cells, emerging as a potential druggable target for this disease.

Measuring AMPK Activity in Vivo Using a Genetically‐Encoded Biosensor

Adenosine monophosphate‐activated kinase (AMPK) is a highly conserved heterotrimeric protein complex that functions in a broad spectrum of cellular stress response pathways. Most work investigating the cellular dynamics of AMPK activity has been limited to either whole‐organ/tissue or, in the case of smaller genetic models like Caenorhabditis elegans, whole‐organism analyses. Some limitations of these approaches include: 1) An inability to observe cellular heterogeneity of AMPK activation; 2) a lack of the temporal dynamics; 3) an inability to correlate AMPK dynamics with physiological states of a living organism. Thus, we sought to adapt a genetically‐coded AMPK biosensor, called AMPKAR‐EV (Kongaya et al., 2017), for use in C. elegans, which is transparent and genetically tractable. The AMPKAR‐EV biosensor uses fluorescence resonance energy transfer (FRET) to report AMPK phosphorylation of substrates. We expressed codon‐adapted AMPKAR‐EV in C. elegans and made three separate transgenic lines expressing it in intestines, body wall muscles, and neurons. As expected, we find that the biosensor responds to conditions that promote AMPK activation. We crossed the lines expressing AMPKAR‐EV in the intestines into a number of different genetic mutants, which we either generated using CRISPR or obtained from previous studies. For context, work in mammals suggests that protein kinase A (PKA) phosphorylates AMPK at serine 173 (S173 ‐ inhibitory site) and prevents catalytic phosphorylation at threonine 172 (T172 ‐ activation site). These sites are conserved to C. elegans but located at serine 244 (S244) and threonine 243 (T243) respectively; however, the significance of these regulatory sites have not been specifically studied. To test these mechanisms more precisely, we made two C. elegans strains that also express AMPKAR‐EV, one that alters the activation site (aak‐2(T243A)) and another that alters the inhibitory site (aak‐2(S244G)). The third strain we constructed expresses AMPKAR‐EV in the kin‐2(ce179) mutant background, which exhibits constitutively active PKA. Using these strains we are optimizing AMPKAR‐EV in vivo and testing the hypothesis that PKA inhibits AMPK at the S244 inhibitory site, which prevents its phosphorylation at the activation site. We envision that AMPKAR‐EV will be of broad use in C. elegans as an organism well‐known for its study of behavior, aging, and longevity.

PKA/ATGL signaling pathway is involved in ER stress-mediated lipolysis in adipocytes of grass carp (Ctenopharyngodon idella).

The relationship between endoplasmic reticulum stress (ER stress) and lipolysis in mammals has been widely studied, but it is relatively scarce in fish. The present study used grass carp Ctenopharyngodon idella as a model to investigate the effect of ER stress on lipolysis in adipocytes of fish. We found that ER stress evoked by tunicamycin (TM) treatment significantly induced lipolysis in adipocytes. Subsequently, in order to further investigate whether protein kinase A (PKA) is involved in ER stress-induced lipolysis, we treated adipocytes with PKA activator forskolin and inhibitor H89. The results showed that the mechanism was related to the activation of PKA, especially the catalytic subunit PRKACBa. Notably, we also found that PKA regulates lipolysis by targeting mRNA level and protein and enzyme activities of adipotriglyceride lipase (ATGL). Taken together, our findings suggest that PKA/ATGL signaling pathway is involved in ER stress-mediated lipolysis of grass carp adipocytes. It provides a theoretical basis for further study on the mechanism of lipolysis in fish and other vertebrates.

A facile fluorescence turn-on biosensor customized for monitoring of protein kinase activity based on carboxylic carbon nanoparticle-peptide complexes.

In this study, we present a facile and low-cost approach for detecting protein kinase A (PKA) by assembling a purpose-designed carboxyfluorescein (FAM)-labelled peptide with carboxylic carbon nanoparticles (CNPs). Fluorescence of the FAM-labelled peptide gradually decreases to a low background signal as a result of the electron transfer from CNPs to FAM-labelled peptide via the peptide, which acts as a bridge. The reaction in the sensor in the presence of adenosine 5'-triphosphate and PKA phosphorylates the substrate peptide and disrupts the electrostatic repulsive force between the CNPs and the peptide, therefore altering the spectroscopic signal of the system. The change in fluorescence signal was directly proportional to the PKA concentration in the range 0-1.8 U/ml with a detection limit of 0.04 U/ml. These results suggest that PKA activity can be effectively measured using the developed PKA biosensor. Moreover, the fluorescence biosensor was successfully used in the investigation of PKA in spiked human embryonic kidney (HEK) 293 cells lysates, indicating its potential applications in protein kinase-related biochemical fundamental research.

Intraperitoneal Administration of Forskolin Reverses Motor Symptoms and Loss of Midbrain Dopamine Neurons in PINK1 Knockout Rats.

Background:Parkinson’s disease (PD) is a relentless, chronic neurodegenerative disease characterized by the progressive loss of substantia nigra (SN) neurons that leads to the onset of motor and non-motor symptoms. Standard of care for PD consists of replenishing the loss of dopamine through oral administration of Levodopa; however, this treatment is not disease-modifying and often induces intolerable side effects. While the etiology that contributes to PD is largely unknown, emerging evidence in animal models suggests that a significant reduction in neuroprotective Protein Kinase A (PKA) signaling in the SN contributes to PD pathogenesis, suggesting that restoring PKA signaling in the midbrain may be a new anti-PD therapeutic alternative.Objective:We surmised that pharmacological activation of PKA via intraperitoneal administration of Forskolin exerts anti-PD effects in symptomatic PTEN-induced kinase 1 knockout (PINK1-KO), a bona fide in vivo model of PD.Methods:By using a beam balance and a grip strength analyzer, we show that Forskolin reverses motor symptoms and loss of hindlimb strength with long-lasting therapeutic effects (> 5 weeks) following the last dose.Results:In comparison, intraperitoneal treatment with Levodopa temporarily (24 h) reduces motor symptoms but unable to restore hindlimb strength in PINK1-KO rats. By using immunohistochemistry and an XF24e BioAnalyzer, Forskolin treatment reverses SN neurons loss, elevates brain energy production and restores PKA activity in SN in symptomatic PINK1-KO rats.Conclusion:Overall, our collective in vivo data suggest that Forskolin is a promising disease-modifying therapeutic alternative for PD and is superior to Levodopa because it confers long-lasting therapeutic effects.

Protein Kinase A Regulates Autophagy-Associated Proteins Impacting Growth and Virulence of Aspergillus fumigatus.

Cellular recycling via autophagy-associated proteins is a key catabolic pathway critical to invasive fungal pathogen growth and virulence in the nutrient-limited host environment. Protein kinase A (PKA) is vital for the growth and virulence of numerous fungal pathogens. However, the underlying basis for its regulation of pathogenesis remains poorly understood in any species. Our Aspergillus fumigatus PKA-dependent whole proteome and phosphoproteome studies employing advanced mass spectroscopic approaches identified numerous previously undefined PKA-regulated proteins in catabolic pathways. Here, we demonstrate reciprocal inhibition of autophagy and PKA activity, and identify 16 autophagy-associated proteins as likely novel PKA-regulated effectors. We characterize the novel PKA-phosphoregulated sorting nexin Atg20, and demonstrate its importance for growth, cell wall stress response, and virulence of A. fumigatus in a murine infection model. Additionally, we identify physical and functional interaction of Atg20 with previously characterized sorting nexin Atg24. Furthermore, we demonstrate the importance of additional uncharacterized PKA-regulated putative autophagy-associated proteins to hyphal growth. Our data presented here indicate that PKA regulates the autophagy pathway much more extensively than previously known, including targeting of novel effector proteins with fungal-specific functions important for invasive disease.

Suppressing the activation of protein kinase A as a DNA damage-independent mechanistic lead for dihydromethysticin prophylaxis of NNK-induced lung carcinogenesis.

Our earlier work demonstrated varying potency of dihydromethysticin (DHM) as the active kava phytochemical for prophylaxis of tobacco carcinogen nicotine-derived nitrosamine ketone (NNK)-induced mouse lung carcinogenesis. Efficacy was dependent on timing of DHM gavage ahead of NNK insult. In addition to DNA adducts in the lung tissues mitigated by DHM in a time-dependent manner, our in vivo data strongly implicated the existence of DNA damage-independent mechanism(s) in NNK-induced lung carcinogenesis targeted by DHM to fully exert its anti-initiation efficacy. In the present work, RNA seq transcriptomic profiling of NNK-exposed (2 h) lung tissues with/without a DHM (8 h) pretreatment revealed a snap shot of canonical acute phase tissue damage and stress response signaling pathways as well as an activation of protein kinase A (PKA) pathway induced by NNK and the restraining effects of DHM. The activation of the PKA pathway by NNK active metabolite 4-(methylnitrosamino)-1-(3-pyridyl)-1-butanol (NNAL) at a concentration incapable of promoting DNA adduct was confirmed in a lung cancer cell culture model, potentially through NNAL binding to and activation of the β-adrenergic receptor. Our in vitro and in vivo data overall support the hypothesis that DHM suppresses PKA activation as a key DNA damage-independent mechanistic lead, contributing to its effective prophylaxis of NNK-induced lung carcinogenesis. Systems biology approaches with a detailed temporal dissection of timing of DHM intake versus NNK exposure are warranted to fill the knowledge gaps concerning the DNA damage-driven mechanisms and DNA damage-independent mechanisms to optimize the implementation strategy for DHM to achieve maximal lung cancer chemoprevention.

Spatiotemporally Resolved Protein Detection in Live Cells Using Nanopore Biosensors.

Spatiotemporal detection of proteins in living cells is a persistent challenge but is the key to understanding their cellular biology and developing theranostic technologies. We develop a dual-nanopore biosensor using affinity-tunable peptide probes, which enables label-free and spatiotemporal monitoring of protein abundance and its concentration change in single live cells. We demonstrate that by screening for peptide probes with tunable affinities, the nanopore modified with a medium-affinity peptide allowed reversible and sensitive detection of the protein kinase A (PKA) catalytic subunit with a detection limit of 0.04 nM. The sensor is shown to have the ability to effectively eliminate interferences from cell membrane resistance and coexisting species in live cell detection. Moreover, our sensor is successfully implemented in monitoring of dynamic PKA activity changes (PKA catalytic subunit dynamic concentration changes) under different stimulations in single live cells. Our design may provide a paradigm for developing nanopore biosensors for spatiotemporally resolved protein analysis in live cells.

Protein kinase A is activated during bone morphogenetic protein 2-induced osteogenic differentiation of dental follicle stem cells via endogenous parathyroid hormone-related protein

ObjectiveThe aim of this study was to investigate the mechanisms of how protein kinase A (PKA) is activated during bone morphogenetic protein 2 (BMP2)-induced osteogenic differentiation in dental follicle stem cells. DesignHuman dental follicle stem cells were cultured and treated with a BMP2-containing osteogenic differentiation medium or differentiation medium without BMP2. Specific siRNAs and substances/proteins were used to modulate pathways. PKA activity and activity of alkaline phosphatase were determined. Expression of targets was measured by Western Blots and reverse transcription-quantitative polymerase chain reaction, while protein interactions were investigated by immunoprecipitation. Immunofluorescence staining was used for subcellular target localization. ResultsPKA activity is stimulated after osteogenic induction by BMP2. Differentiation medium without BMP2 strongly induces BMP2 gene expression, which correlates with downstream target expression. Elevation of cAMP levels does not affect alkaline phosphatase activity and PKA does not directly interact with Smad 4. However, PKA activation requires expression of parathyroid hormone-related protein (PTHrP), which is stimulated after BMP2-induced differentiation. Furthermore, neither supplementation with PTHrP nor with the receptor antagonist parathyroid hormone (7−34) affects PKA activity. Thus, endogenous PTHrP expression is required for PKA activation and immunofluorescence staining shows that PTHrP is mainly located in the nucleus of dental follicle stem cells. Beyond, knockdown of PKA stimulates the BMP2 signaling pathway and down-stream expression of PTHrP. ConclusionsBMP2-induced osteogenic differentiation activates PKA in dental follicle stem cells via endogenous expression of PTHrP. Additionally, PKA inhibits BMP2 signaling and expression of PTHrP in a negative feedback loop.

MTORC1 induces plasma membrane depolarization and promotes preosteoblast senescence by regulating the sodium channel Scn1a

Senescence impairs preosteoblast expansion and differentiation into functional osteoblasts, blunts their responses to bone formation-stimulating factors and stimulates their secretion of osteoclast-activating factors. Due to these adverse effects, preosteoblast senescence is a crucial target for the treatment of age-related bone loss; however, the underlying mechanism remains unclear. We found that mTORC1 accelerated preosteoblast senescence in vitro and in a mouse model. Mechanistically, mTORC1 induced a change in the membrane potential from polarization to depolarization, thus promoting cell senescence by increasing Ca2+ influx and activating downstream NFAT/ATF3/p53 signaling. We further identified the sodium channel Scn1a as a mediator of membrane depolarization in senescent preosteoblasts. Scn1a expression was found to be positively regulated by mTORC1 upstream of C/EBPα, whereas its permeability to Na+ was found to be gated by protein kinase A (PKA)-induced phosphorylation. Prosenescent stresses increased the permeability of Scn1a to Na+ by suppressing PKA activity and induced depolarization in preosteoblasts. Together, our findings identify a novel pathway involving mTORC1, Scn1a expression and gating, plasma membrane depolarization, increased Ca2+ influx and NFAT/ATF3/p53 signaling in the regulation of preosteoblast senescence. Pharmaceutical studies of the related pathways and agents might lead to novel potential treatments for age-related bone loss.

Temporally and Spatially Localized PKA Activity within Learning and Memory Circuitry Regulated by Network Feedback.

Dynamic functional connectivity within brain circuits requires coordination of intercellular signaling and intracellular signal transduction. Critical roles for cAMP-dependent protein kinase A (PKA) signaling are well established in the Drosophila mushroom body (MB) learning and memory circuitry, but local PKA activity within this well-mapped neuronal network is uncharacterized. Here, we use an in vivo PKA activity sensor (PKA-SPARK) to test spatiotemporal regulatory requirements in the MB axon lobes. We find immature animals have little detectable PKA activity, whereas postcritical period adults show high field-selective activation primarily in just 3/16 defined output regions. In addition to the age-dependent PKA activity in distinct α’/β’ lobe nodes, females show sex-dependent elevation compared with males in these same restricted regions. Loss of neural cell body Fragile X mental retardation protein (FMRP) and Rugose [human Neurobeachin (NBEA)] suppresses localized PKA activity, whereas overexpression (OE) of MB lobe PKA-synergist Meng-Po (human SBK1) promotes PKA activity. Elevated Meng-Po subverts the PKA age-dependence, with elevated activity in immature animals, and spatial-restriction, with striking γ lobe activity. Testing circuit signaling requirements with temperature-sensitive shibire (human Dynamin) blockade, we find broadly expanded PKA activity within the MB lobes. Using transgenic tetanus toxin to block MB synaptic output, we find greatly heightened PKA activity in virtually all MB lobe fields, although the age-dependence is maintained. We conclude spatiotemporally restricted PKA activity signaling within this well-mapped learning/memory circuit is age-dependent and sex-dependent, driven by FMRP-Rugose pathway activation, temporally promoted by Meng-Po kinase function, and restricted by output neurotransmission providing network feedback.

Lubabegron fumarate acts as a β-adrenergic receptor antagonist in cultured bovine intramuscular and subcutaneous adipocytes.

We hypothesized that lubabegron fumarate (LUB) (Experior, Elanco Animal Health, Greenfield, IN) would act as an antagonist to β-adrenergic receptor (β-AR) subtypes in primary bovine subcutaneous (s.c.) and intramuscular (i.m.) adipocytes differentiated in culture. This study employed LUB, dobutamine (DOB, a selective β1-agonist), salbutamol (SAL, a selective β2-agonist), and propranolol (PRO, a non-selective β-AR antagonist). Preadipocytes were isolated by standard techniques from bovine longissimus muscle and overlying s.c. adipose tissue and differentiated to adipocytes for 14 d. The adipocyte source x stage of differentiation interaction was significant for β-adrenergic receptors-1 (ADRB1) (P = 0.001) and ADRB2 (P = 0.01) in that expression of ADRB1 and ADRB2 was greater in s.c. adipocytes than in s.c. preadipocytes; expression of the ADRB1-3 did not change after differentiation of i.m. adipocytes. CCATT/enhancer-binding protein alpha (CEBPA) expression increased upon differentiation in both s.c. and i.m. adipocytes (P = 0.006). The source x stage of differentiation interaction was significant for peroxisome proliferator-activated receptor gamma (PPARG) (P ≤ 0.001) and fatty acid binding protein-4 (FABP4) (P = 0.004). Expression of PPARG increased after differentiation of s.c. preadipocytes to adipocytes, but PPARG expression did not change with differentiation of i.m. preadipocytes to adipocytes. FABP4 expression increased after differentiation of both s.c. and i.m. adipocytes, but FABP4 expression increased to a greater extent in s.c. adipocytes. In s.c. adipocytes, DOB elevated cAMP and glycerol production and protein kinase A (PKA) activity, and SAL increased PKA activity; these effects were abolished by LUB and PRO (P < 0.001). Incubation of i.m. adipocytes with SAL increased cAMP production and PKA activity, which was attenuated by LUB and PRO (P ≤ 0.006). In s.c. adipocytes, SAL, LUB + SAL, and LUB + DOB upregulated hormone sensitive lipase (HSL) (P < 0.001) and perilipin (P = 0.002) gene expression. In i.m. adipocytes, DOB and LUB + DOB increased HSL gene expression (P = 0.001) and LUB + SAL depressed adipose triglyceride lipase expression below control levels (P = 0.001). These results demonstrate that LUB is a β-AR antagonist at the β1-AR and β2-AR subtypes in s.c. adipocytes, and that s.c. and i.m. exhibit different responses to β-AA and LUB.

Breadth and Specificity in Pleiotropic Protein Kinase A Activity and Environmental Responses.

Protein Kinase A (PKA) is an essential kinase that is conserved across eukaryotes and plays fundamental roles in a wide range of organismal processes, including growth control, learning and memory, cardiovascular health, and development. PKA mediates these responses through the direct phosphorylation of hundreds of proteins–however, which proteins are phosphorylated can vary widely across cell types and environmental cues, even within the same organism. A major question is how cells enact specificity and precision in PKA activity to mount the proper response, especially during environmental changes in which only a subset of PKA-controlled processes must respond. Research over the years has uncovered multiple strategies that cells use to modulate PKA activity and specificity. This review highlights recent advances in our understanding of PKA signaling control including subcellular targeting, phase separation, feedback control, and standing waves of allosteric regulation. We discuss how the complex inputs and outputs to the PKA network simultaneously pose challenges and solutions in signaling integration and insulation. PKA serves as a model for how the same regulatory factors can serve broad pleiotropic functions but maintain specificity in localized control.

Reversible lysine fatty acylation of an anchoring protein mediates adipocyte adrenergic signaling

N-myristoylation on glycine is an irreversible modification that has long been recognized to govern protein localization and function. In contrast, the biological roles of lysine myristoylation remain ill-defined. We demonstrate that the cytoplasmic scaffolding protein, gravin-α/A kinase-anchoring protein 12, is myristoylated on two lysine residues embedded in its carboxyl-terminal protein kinase A (PKA) binding domain. Histone deacetylase 11 (HDAC11) docks to an adjacent region of gravin-α and demyristoylates these sites. In brown and white adipocytes, lysine myristoylation of gravin-α is required for signaling via β2- and β3-adrenergic receptors (β-ARs), which are G protein-coupled receptors (GPCRs). Lysine myristoylation of gravin-α drives β-ARs to lipid raft membrane microdomains, which results in PKA activation and downstream signaling that culminates in protective thermogenic gene expression. These findings define reversible lysine myristoylation as a mechanism for controlling GPCR signaling and highlight the potential of inhibiting HDAC11 to manipulate adipocyte phenotypes for therapeutic purposes.

Cardioprotection of Immature Heart by Simultaneous Activation of PKA and Epac: A Role for the Mitochondrial Permeability Transition Pore.

Metabolic and ionic changes during ischaemia predispose the heart to the damaging effects of reperfusion. Such changes and the resulting injury differ between immature and adult hearts. Therefore, cardioprotective strategies for adults must be tested in immature hearts. We have recently shown that the simultaneous activation of protein kinase A (PKA) and exchange protein activated by cAMP (Epac) confers marked cardioprotection in adult hearts. The aim of this study is to investigate the efficacy of this intervention in immature hearts and determine whether the mitochondrial permeability transition pore (MPTP) is involved. Isolated perfused Langendorff hearts from both adult and immature rats were exposed to global ischaemia and reperfusion injury (I/R) following control perfusion or perfusion after an equilibration period with activators of PKA and/or Epac. Functional outcome and reperfusion injury were measured and in parallel, mitochondria were isolated following 5 min of reperfusion to determine whether cardioprotective interventions involved changes in MPTP opening behaviour. Perfusion for 5 min preceding ischaemia of injury-matched adult and immature hearts with 5 µM 8-Br (8-Br-cAMP-AM), an activator of both PKA and Epac, led to significant reduction in post-reperfusion CK release and infarct size. Perfusion with this agent also led to a reduction in MPTP opening propensity in both adult and immature hearts. These data show that immature hearts are innately more resistant to I/R injury than adults, and that this is due to a reduced tendency of MPTP opening following reperfusion. Furthermore, simultaneous stimulation of PKA and Epac causes cardioprotection, which is additive to the innate resistance.

Melatonin alleviates traumatic brain injury-induced anxiety-like behaviors in rats: Roles of the protein kinase A/cAMP-response element binding signaling pathway.

Melatonin is a hormone produced by the pineal gland. Given its capabilities of neuroprotection and low neurotoxicity, melatonin could be a therapeutic strategy for traumatic brain injury (TBI). The present study was conducted to determine the neuroprotective effects of melatonin on TBI-induced anxiety and the possible molecular mechanism. Rats were randomly divided into seven groups. The rodent model of TBI was established using the weight-drop method. Melatonin was administered by intraperitoneal injection at a dose of 10 mg/kg after TBI. H89 (0.02 mg/kg), a special protein kinase A (PKA) inhibitor, or dibutyryl-cyclic adenosine monophosphate (cAMP; 0.1 mg/kg), an activator of PKA, were administered by stereotactic injection of the brain to evaluate the roles of PKA and cAMP-response element-binding protein (CREB) in melatonin-related mood regulation, respectively. At 30 days post-TBI, the changes in anxiety-like behaviors in rats were measured using the open field and elevated plus maze tests. At 24 h post-TBI, the number of activated astrocytes and neuronal apoptosis were evaluated using immunofluorescence assay. The expression levels of inflammatory cytokines (TNF-α and IL-6) in the amygdala were measured using an enzyme-linked immunosorbent assay. The expression levels of PKA, phosphorylated (p)-PKA, CREB, p-CREB, NF-κB and p-NF-κB in the amygdala were detected using western blotting. It was revealed that melatonin partially reversed TBI-induced anxiety-like behavior in rats, and decreased the number of activated astrocytes and neuronal apoptosis in the amygdala induced by TBI. H89 partially blocked the neuroprotective effects of melatonin; while dibutyryl-cAMP not only reduced the H89-induced emotional disturbance but also enhanced the protective effects of melatonin against TBI. Overall, melatonin can alleviate TBI-induced anxiety-like behaviors in rats. Moreover, the underlying mechanism may be associated with the activation of the PKA/CREB signaling pathway.

Fast detection of PKA activity in Saccharomyces cerevisiae cell population using AKAR fluorescence resonance energy transfer probes

In Saccharomyces cerevisiae, the protein kinase A (PKA) plays a central role in the control of metabolism, stress resistance and cell cycle progression. In a previous work, we used a FRET-based A-kinase activity reporter (AKAR3 probe) to monitor changes in PKA activity in vivo in single S. cerevisiae cells. Since this procedure is quite complex and time-consuming, in this work we used the AKAR3 probe (evenly distributed within the cells) and the plate reader Victor-X3™ (Perkin Elmer®) to measure PKA activity in vivo in a whole cell population. We show that in wild type strains, the FRET increases after addition of glucose to glucose-starved cells, while no changes are observed when this sugar is added to strains with either absent or attenuated PKA activity. Moreover, using the pm-AKAR3 probe, mainly expressed at the plasma membrane and partially at the vacuolar membrane, we could monitor PKA activity from the starting site of the signal to internal regions, where the signal is propagated. Finally, we also show evidence for direct activation of PKA by glucose, independent of cAMP. In conclusion, our data show that AKAR3 and pm-AKAR3 probes are useful biosensors to monitor PKA activity in a S. cerevisiae cell population using a plate reader.

Phosphodiesterase 4D promotes angiotensin II-induced hypertension in mice via smooth muscle cell contraction

Hypertension is a common chronic disease, which leads to cardio-cerebrovascular diseases, and its prevalence is increasing. The cyclic adenosine monophosphate (cAMP)-protein kinase A (PKA) pathway participates in multiple cardiovascular diseases. Phosphodiesterase (PDE) 4 has been shown to regulate PKA activity via cAMP specific hydrolysis. However, whether PDE4-cAMP-PKA pathway influences hypertension remains unknown. Herein, we reveal that PDE4D (one of PDE4 isoforms) expression is upregulated in the aortas of experimental hypertension induced by angiotensin II (Ang II). Furthermore, knockout of Pde4d in mouse smooth muscle cells (SMCs) attenuates Ang II-induced hypertension, arterial wall media thickening, vascular fibrosis and vasocontraction. Additionally, we find that PDE4D deficiency activates PKA-AMP-activated protein kinase (AMPK) signaling pathway to inhibit myosin phosphatase targeting subunit 1 (MYPT1)-myosin light chain (MLC) phosphorylation, relieving Ang II-induced SMC contraction in vitro and in vivo. Our results also indicate that rolipram, a PDE4 inhibitor, may be a potential drug for hypertension therapy.

PTH1R Actions on Bone Using the cAMP/Protein Kinase A Pathway.

After the initial signaling action of parathyroid hormone (PTH) on bone was shown to be activation of adenylyl cyclase, its target was found to be cells of the osteoblast lineage, to the exclusion of osteoclasts and their precursors. This led to the view that the osteoblast lineage regulated osteoclast formation, a proposal that was established when the molecular mechanisms of osteoclast formation were discovered. This is in addition to the effect of PTH1Rv signaling throughout the osteoblast differentiation process to favour the formation of bone-forming osteoblasts. Initial signaling in the PTH target cells through cAMP and protein kinase A (PKA) activation is extremely rapid, and marked by an amplification process in which the later event, PKA activation, precedes cAMP accumulation in time and is achieved at lower concentrations. All of this is consistent with the existence of “spare receptors”, as is the case with several other peptide hormones. PTH-related protein (PTHrP), that was discovered as a cancer product, shares structural similarity with PTH in the amino-terminal domain that allows the hormone, PTH, and the autocrine/paracrine agent, PTHrP, to share actions upon a common G protein coupled receptor, PTH1R, through which they activate adenylyl cyclase with equivalent potencies. Studies of ligand-receptor kinetics have revealed that the PTH/PTH1R ligand-receptor complex, after initial binding and adenylyl cyclase activation at the plasma membrane, is translocated to the endosome, where adenylyl cyclase activation persists for a further short period. This behavior of the PTH1R resembles that of a number of hormones and other agonists that undergo such endosomal translocation. It remains to be determined whether and to what extent the cellular effects through the PTH1R might be influenced when endosomal is added to plasma membrane activation.