Sustained signalling by PTH modulates IP3 accumulation and IP3 receptors through cyclic AMP junctions.

Parathyroid hormone (PTH) stimulates adenylyl cyclase through type 1 PTH receptors (PTH1R) and potentiates the Ca(2+) signals evoked by carbachol, which stimulates formation of inositol 1,4,5-trisphosphate (IP3). We confirmed that in HEK cells expressing PTH1R, acute stimulation with PTH(1-34) potentiated carbachol-evoked Ca(2+) release. This was mediated by locally delivered cyclic AMP (cAMP), but unaffected by inhibition of protein kinase A (PKA), exchange proteins activated by cAMP, cAMP phosphodiesterases (PDEs) or substantial inhibition of adenylyl cyclase. Sustained stimulation with PTH(1-34) causes internalization of PTH1R-adenylyl cyclase signalling complexes, but the consequences for delivery of cAMP to IP3R within cAMP signalling junctions are unknown. Here, we show that sustained stimulation with PTH(1-34) or with PTH analogues that do not evoke receptor internalization reduced the potentiated Ca(2+) signals and attenuated carbachol-evoked increases in cytosolic IP3. Similar results were obtained after sustained stimulation with NKH477 to directly activate adenylyl cyclase, or with the membrane-permeant analogue of cAMP, 8-Br-cAMP. These responses were independent of PKA and unaffected by substantial inhibition of adenylyl cyclase. During prolonged stimulation with PTH(1-34), hyperactive cAMP signalling junctions, within which cAMP is delivered directly and at saturating concentrations to its targets, mediate sensitization of IP3R and a more slowly developing inhibition of IP3 accumulation.

PKA delivery to the distal lung air spaces increases alveolar liquid clearance after isoproterenol-induced alveolar epithelial PKA desensitization.

Isoproterenol (Iso) infusion for 48 h in rats decreases the ability of beta-adrenoceptor (beta-AR) agonists to increase alveolar liquid clearance (ALC). An impairment in protein kinase A (PKA) function appears to be critical in producing the desensitized ALC response. To test this hypothesis, we used a novel protein delivery reagent (Chariot, Active Motif) to deliver either the PKA catalytic subunit or the PKA holoenzyme to the distal lung epithelium of Iso-infused rats (400 microg.kg(-1).h(-1), 48 h). After this infusion, ALC was measured by mass balance over 2 h. ALC in Iso-infused rats was 27.9% (SD 5.8) of instilled volume absorbed. Delivery of the catalytic PKA subunit to Iso-infused rats increased ALC to 47.7% (SD 8.9) (P < 0.05). ALC in Iso-infused rats delivered the inactive PKA holoenzyme [29.6% (SD 2.5)] was not increased above baseline values. Subsequent holoenzyme activation by intravenous infusion of the stable cAMP analog Sp-8-Bromo-cAMPS increased ALC to 41.7% (SD 8.8) (P < 0.05). Immunohistochemical localization of Chariot-delivered PKA revealed staining in the alveolar and distal airway epithelium. These data indicate that protein delivery reagents can be used to rapidly deliver biologically active proteins to the distal lung epithelium and that PKA desensitization may be an important rate-limiting event in the development of Iso-induced desensitization of the alveolar epithelial beta-AR signaling pathway.

Uptake of liposomally entrapped adenosine-3'-5'-cyclic monophosphate in mouse brain.

[3H] Adenosine-3',5'-cyclic monophosphate (cAMP) could be entrapped efficiently into small unilamellar vesicles when bound to cAMP-dependent protein kinase. The leakage of [3H]cAMP protein kinase complex from liposomes was reduced by more than 60% as compared to free [3H]cAMP. Hyperosmolar mannitol increased the delivery of liposomally entrapped [3H]cAMP protein kinase to the brain with maximum uptake occurring at 10 min after mannitol administration. Optimal delivery to the brain was observed when vesicles composed of total brain lipids or phosphatidylcholine:cholesterol:sulfatides (7:2:1) were used. A slower clearance of liposomally entrapped material from brain tissue was seen under hyperosmolar conditions.

Vasoactive intestinal peptide-stimulated Cl- secretion: activation of cAMP-dependent K+ channels.

Vasoactive intestinal peptide (VIP) stimulates active Cl- secretion by the intestinal epithelium, a process that depends upon the maintenance of a favorable electrical driving force established by a basolateral membrane K+ conductance. To demonstrate the role of this K- conductance, we measured short-circuit current (I(SC)) across monolayers of the human colonic secretory cell line, T84. The serosal application of VIP (50 nM) increased I(SC) from 3 +/- 0.4 microA/cm2 to 75 +/- 11 microA/cm2 (n = 4), which was reduced to a near zero value by serosal applications of Ba2+ (5 mM). The chromanol, 293B (100 microM), reduced I(SC) by 74%, but charybdotoxin (CTX, 50 nM) had no effect. We used the whole-cell voltage-clamp technique to determine whether the K+ conductance is regulated by cAMP-dependent phosphorylation in isolated cells. VIP (300 nM) activated K+ current (131 +/- 26 pA, n = 15) when membrane potential was held at the Cl- equilibrium potential (E(Cl-) = -2 mV), and activated inward current (179 +/- 28 pA, n = 15) when membrane potential was held at the K+ equilibrium potential (E(K+) = -80 mV); however, when the cAMP-dependent kinase (PKA) inhibitor, PKI (100 nM), was added to patch pipettes, VIP failed to stimulate these currents. Barium (Ba2+ , 5 mM), but not 293B, blocked this K+ conductance in single cells. We used the cell-attached membrane patch under conditions that favor K + current flow to demonstrate the channels that underlie this K+ conductance. VIP activated inwardly rectifying channel currents in this configuration. Additionally, we used fura-2AM to show that VIP does not alter the intracellular Ca2+ concentration, [Ca2 +]i. Caffeine (5 mM), a phosphodiesterase inhibitor, also stimulated K+ current (185 +/- 56 pA, n = 8) without altering [Ca2+]i. These results demonstrate that VIP activates a basolateral membrane K+ conductance in T84 cells that is regulated by cAMP-dependent phosphorylation.

Ventricular dysfunction after cardioplegic arrest is improved after myocardial gene transfer of a beta-adrenergic receptor kinase inhibitor.

BACKGROUND: Acute cardiac contractile dysfunction is common after cardiopulmonary bypass (CPB). A potential molecular mechanism is enhanced beta-adrenergic receptor kinase (betaARK1) activity, because beta-adrenergic receptor (betaAR) signaling is altered in cardiomyocytes after cardioplegia. Therefore, we examined whether adenovirus-mediated intracoronary delivery of a betaARK1 inhibitor (Adv-betaARKct) could prevent post-CPB dysfunction. METHODS AND RESULTS: Rabbits were randomized to receive 5x10(11) total viral particles of Adv-betaARKct or PBS. After 5 days, hearts were arrested with University of Wisconsin solution, excised, and stored at 4 degrees C for 15 minutes or 4 hours before reperfusion on a Langendorff apparatus. Left ventricular (LV) function measured by end-diastolic pressure response to preload augmentation, contractility (LV dP/dt(max)), and relaxation (LV dP/dt(min)) was assessed by use of increasing doses of isoproterenol and compared with a control group of nonarrested hearts acutely perfused on the Langendorff apparatus. In the PBS-treated hearts, LV function decreased in a temporal manner and was significantly impaired compared with control hearts after 4 hours of cardioplegic arrest. LV function in Adv-betaARKct-treated hearts, however, was significantly enhanced compared with PBS treatment and was similar to control nonarrested hearts even after 4 hours of cardioplegia. Biochemically, several aspects of betaAR signaling were dysfunctional in PBS-treated hearts, whereas they were normalized in betaARKct-overexpressing hearts. CONCLUSIONS: Myocardial gene transfer of Adv-betaARKct stabilizes betaAR signaling and prevents LV dysfunction induced by prolonged cardioplegic arrest. Thus, betaARK1 inhibition may represent a novel target in limiting depressed ventricular function after CPB.

Intracellular distribution of mammalian protein kinase A catalytic subunit altered by conserved Asn2 deamidation.

The catalytic (C) subunit of protein kinase A functions both in the cytoplasm and the nucleus. A major charge variant representing about one third of the enzyme in striated muscle results from deamidation in vivo of the Asn2 residue at the conserved NH(2)-terminal sequence myrGly-Asn-Ala (Jedrzejewski, P.T., A. Girod, A. Tholey, N. König, S. Thullner, V. Kinzel, and D. Bossemeyer. 1998. Protein Sci. 7:457-469). Because of the increase of electronegativity by generation of Asp2, it is reminiscent of a myristoyl-electrostatic switch. To compare the intracellular distribution of the enzymes, both forms of porcine or bovine heart enzyme were microinjected into the cytoplasm of mouse NIH 3T3 cells after conjugation with fluorescein, rhodamine, or in unlabeled form. The nuclear/cytoplasmic fluorescence ratio (N/C) was analyzed in the presence of cAMP (in the case of unlabeled enzyme by antibodies). Under all circumstances, the N/C ratio obtained with the encoded Asn2 form was significantly higher than that with the deamidated, Asp2 form; i.e., the Asn2 form reached a larger nuclear concentration than the Asp2 form. Comparable data were obtained with a human cell line. The differential intracellular distribution of both enzyme forms is also reflected by functional data. It correlates with the degree of phosphorylation of the key serine in CREB family transcription factors in the nucleus. Microinjection of myristoylated recombinant bovine Calpha and the Asn2 deletion mutant of it yielded N/C ratios in the same range as encoded native enzymes. Thus, Asn2 seems to serve as a potential site for modulating electronegativity. The data indicate that the NH(2)-terminal domain of the PKA C-subunit contributes to the intracellular distribution of free enzyme, which can be altered by site-specific in vivo deamidation. The model character for other signaling proteins starting with myrGly-Asn is discussed.

Cardiac calcium channels expressed in Xenopus oocytes are modulated by dephosphorylation but not by cAMP-dependent phosphorylation.

Enhancement of cardiac L-type Ca2+ channel activity by norepinephrine via phosphorylation by protein kinase A (PKA) underlines the positive inotropic effect of this transmitter and is a classical example of an ion channel modulation. However, it is not clear whether the channel protein itself (and which subunit) is a substrate for PKA. We have expressed various combinations of the cardiac Ca2+ channel subunits in Xenopus oocytes by injecting subunit mR-NAs. Expression of beta or alpha 2/delta + beta subunits potentiated the native (endogenous) Ca2+ channel currents in the oocyte (similar to T or N but not L-type). This potentiated endogenous current was enhanced by intracellular injection of cAMP or of the catalytic subunit of PKA, and this effect was reversed by the injection of a PKA inhibitor suggesting the presence of basal phosphatase activity. When a cardiac channel of alpha 1 + beta, alpha 1 + alpha 2/delta or alpha 1 + alpha 2/delta + beta composition was expressed at levels high enough that the contribution of the endogenous current became negligible, cAMP and PKA failed to increase the Ca2+ channel current, whereas PKA inhibitors and the catalytic subunit of protein phosphatase 1 reduced the amplitude of the current. Reduction of the current by PKA inhibitors was observed regardless of the presence of the beta subunit, suggesting a major role for the alpha 1 subunit in this process. These results suggest that, like in the heart, when expressed in Xenopus oocytes, the cardiac L-type Ca2+ channels are phosphorylated in basal state and dephosphorylation reduces their activity. However, unlike the situation in the heart, the activity of the channel cannot be enhanced by PKA-catalyzed phosphorylation, suggesting that the channel is already fully phosphorylated in its basal state.