Interaction of cyclic AMP and Ca2+ in the control of electrical coupling in heart fibers

The influence of intracellular injection of cAMP on the electrical coupling of canine Purkinje cells was investigated. It was found that the nucleotide enhanced reversibly the cell-to-cell communication through an increase in junctional conductance. Dibutyryl cAMP (5 X 10(-4) M) plus theophylline (0.4 mM) decreased appreciably the intracellular longitudinal resistance (ri). The interactions of cAMP and Ca on the electrical coupling were also investigated. The nucleotide and Ca have opposite effects on the electrical coupling. In the presence of high [Ca2+]o solutions (6 mM), the intracellular injection of cAMP causes a transient increase in the coupling coefficient followed by an appreciable decrease in cell-to-cell coupling. This reduction in intracellular communication was reversed by injecting EGTA into the same cell. The results of this study support the view that cAMP is a modulator of junctional conductance in cardiac muscle and that the compound interacts with Ca in the control of intracellular communication.     

The role of cAMP and Ca on the modulation of junctional conductance: an integrated hypothesis

The role of cAMP and Ca in the modulation of junctional permeability is discussed. An integrated hypothesis is presented which proposes that cAMP modulates the junctional conductance through the activation of specific kinases and phosphorylation of gap junction proteins. A close-loop feed-back between cAMP and Ca is assumed to be relevant in the regulation of junctional conductance under physiological conditions. According to this hypothesis hormones modulate the junctional permeability through variations in the intracellular concentration of cAMP. It is known that in several tissues the cells are connected through low resistance intercellular junctions (Loewenstein, 1966; Bennett, 1973; De Mello, 1975, 1932a). Ions and small molecules can flow freely from cell-to-cell across narrow hydrophilic channels (De Mello, 1982a). This type of intercellular coupling is essential for the fast propagation of the impulse and the synchronization of electrical activity in excitable tissues (Bennett, 1973; De Mello, 1982a). It has been proposed that the exchange of chemical signals between cells is important for metabolic cooperation (Gilula et al. 1972) and growth control (Loewenstein, 1979). Therefore, the modulation of junctional conductance is a significant feature of cell biology. Evidence has been provided that the increase in free [Ca2+]i can produce cell decoupling in Chironomus salivary gland (Loewenstein et al., 1967) and in mammalian cardiac fibers (De Mello, 1972, 1975). The free [Ca2+]i required to suppress cell-to-cell coupling is difficult to determine because Ca ions are continuously taken up by mitochondria, sarcoplasmic reticulum or are extruded from the cell. In salivary gland a concentration of free [Ca2+]i of about 5-8 X 10(-5) M was found to be associated with cell decoupling (Loewenstein et al., 1967). The major difficulty here is that the concentration of the ion determined in the bulk of the cytosol is not necessarily the same near the gap junctions.(ABSTRACT TRUNCATED AT 250 WORDS)     

An electrophysiological study of the junctional membrane of epidermal cells in Tenebrio molitor

The insect epidermis is normally a coupled network with respect to the movement of inorganic ions through the junctional membranes connecting adjacent cells. The high ionic permeability of the junctional membrane may be reversibly abolished by either the iontophoretic injection of Ca into single cells or by replacing the Na in the external medium with Li. After Ca injection, a concomitant loss in ionic permeability of the junctional membrane and of the membrane potential of the injected cell was recorded within 3 min. Ionic coupling was restored by hyperpolarizing current pulses within a few minutes. Li substitution tripled the resistance of the junctional membrane within 30 min although the membrane potential remained stable during this period. After 60 min exposure to Li the membrane potential had decayed to zero and ionic coupling was unrecordable. Junctional membrane permeability and cell membrane potential were restored within 30 min re-exposure to normal saline. Since Li is thought to act by indirectly raising the free Ca level in the cytoplasm by its interaction with cytoplasmic Na, we suggest that a reduction in junctional permeability is a direct consequence of increased Ca activity in the cytoplasm of the epidermal cells.     

Effect of high intracellular calcium ion concentration on the transmembrane current induced by iontophoretic injection of cAMP inHelix pomatia neurons

The effect of increasing the intracellular calcium ion concentration by various methods (iontophoretic injection into the cytoplasm, generation of a burst of action potentials, addition of uncouplers of oxidative phosphorylation to the external solution, causing release of calcium from mitochondria) on the inward current induced by injection of cAMP into the neuron (the cAMP current) was investigated on the neuron membrane ofHelix pomatia under voltage clamp conditions. In all cases an increase in the intracellular calcium ion concentration was found to lead to an increase in amplitude, and in many cases duration, of the cAMP current. It is suggested that membrane structures responsible for appearance of the cAMP current have two phosphorylation centers: cAMP-dependent and calcium-calmodulin-dependent. The possible role of this process in signal integration at the intraneuronal level is discussed.A. A. Bogomolets Institute of Physiology, Academy of Sciences of the Ukrainian SSR, Kiev. Translated from Neirofiziologiya, Vol. 17, No. 1, pp. 78–84, January–February, 1985.     

Cyclic AMP inhibits Akt activity by blocking the membrane localization of PDK1

Akt is a protein serine/threonine kinase that plays an important role in the mitogenic responses of cells to variable stimuli. Akt contains a pleckstrin homology (PH) domain and is activated by phosphorylation at threonine 308 and serine 473. Binding of 3'-OH phosphorylated phosphoinositides to the PH domain results in the translocation of Akt to the plasma membrane where it is activated by upstream kinases such as (phosphoinositide-dependent kinase-1 (PDK1). Over-expression of constitutively active forms of Akt promotes cell proliferation and survival, and also stimulates p70 S6 kinase (p70S6K). In many cells, an increase in levels of intracellular cyclic AMP (cAMP) diminishes cell growth and promotes differentiation, and in certain conditions cAMP is even antagonistic to the effect of growth factors. Here, we show that cAMP has inhibitory effects on the phosphatidylinositol 3-kinase/PDK/Akt signaling pathway. cAMP potently inhibits phosphorylation at threonine 308 and serine 473 of Akt, which is required for the protein kinase activities of Akt. cAMP also negatively regulates PDK1 by inhibiting its translocation to the plasma membrane, despite not affecting its protein kinase activities. Furthermore, when we co-expressed myristoylated Akt and PDK1 mutants which constitutively co-localize in the plasma membrane, Akt activity was no longer sensitive to raised intracellular cAMP concentrations. Finally, cAMP was also found to inhibit the lipid kinase activity of PI3K and to decrease the levels of phosphatidylinositol 3,4,5-triphosphate in vivo, which are required for the membrane localization of PDK1. Collectively, these data strongly support the theory that the cAMP-dependent signaling pathway inhibits Akt activity by blocking the coupling between Akt and its upstream regulators, PDK, in the plasma membrane.     

Effects of transmembrane gradients of bicarbonate and ammonium on junctional and nonjunctional membrane conductances in BHK cells

Weak acids are efficient blockers of gap-junctional conductance. It is generally accepted that intracellular acidification produced by weak acids fully accounts for the gap-junctional uncoupling. Protonation of the cytoplasmic portions of the channel-forming protein connexin is thought to lead to the conformational changes switching the channel from the open into the closed state. If this is the only mechanism of the weak-acid induced uncoupling, then the correlation between junctional conductance (Gj) and intracellular pH (pHin) should not depend on the means of intracellular acidification. We compared the responses of junctional conductance in BHK cells measured in double whole-cell experiments to the applied transmembrane concentration gradients of bicarbonate or ammonium. These treatments were to lower pHin in a predictable way according to the equations: pHin = pHout -lg[[HCO3]out/HCO3-]in) or pHin = PHout - lg[[NH4+]in[NH4+out), respectively. We found that the behavior of Gj depended on the substance used. At a 500-fold bicarbonate gradient (calculated pHin approximately 4.8) the cells remained coupled, while a 100- or 10-fold gradient of ammonium imposing pHin approximately 6.1 produced fast uncoupling. The responses of junctional conductance were often accompanied or preceded by changes of non-junctional membrane conductance. We suggest that the mechanisms of the weak acid/base-induced channel gating may contain an additional "lipophilic" component due to the presence of the non-dissociated form of the acid/base in cell membrane.     

Important role of junctophilin in nematode motor function.

Junctional complexes between the plasma membrane and endoplasmic/sarcoplasmic reticulum are shared by excitable cells and seem to be the structural ground for cross-talk between cell-surface and intracellular ionic channels. Our current studies have identified junctophilins (JPs) as members of a novel transmembrane protein family in the junctional membrane complex. Biochemical and gene-knockout studies have suggested that JPs contribute to the formation of the junctional membrane complex by spanning the intracellular store membrane and interacting with the plasma membrane. We report here invertebrate JPs in fruit fly and nematode. Three distinct JP subtype genes are found in the mammalian genome, while a single JP gene exists in either invertebrate genome. Mammalian and invertebrate JPs share characteristic structural features, although some intervening sequences are found in invertebrate JPs. A reporter assay indicated that the JP gene is predominantly activated in muscle cells in nematode. Nematodes, in which expression of JP was inhibited by RNA-mediated interference (RNAi), showed hypolocomotion. Taking account of the cell-type-specific expression and data from previous reports, the hypolocomotion is likely to be due to the deficiency of junctional membrane structures and the resulting reduction of Ca(2+) signaling during excitation-contraction coupling in muscle cells.     

Electrical coupling between cells in islets of langerhans from mouse

Summary Two microelectrodes have been used to measure membrane potentials simultaneously in pairs of mouse pancreatic islet cells. In the presence of glucose at concentrations between 5.6 and 22.2mm, injection of currenti into cell 1 caused a membrane potential change in this cell,V ₁, and, provided the second microelectrode was less than 35 m away, in a second impaled cell 2,V ₂. This result establishes that there is electrical coupling between islet cells and suggests that the space constant of the coupling ratio within the islet tissue is of the order of a few -cell diameters. The current-membrane potential curvesi-V ₁ andi-V ₂ are very similar. By exchange of the roles of the microelectrodes, no evidence of rectification of the current through the intercellular pathways was found. Removal of glucose caused a rapid decrease in the coupling ratioV ₂ /V ₁ . In steady-state conditions, the coupling ratio increases with the concentration of glucose in the range from 0 up to 22mm. Values of the equivalent resistance of the junctional and nonjunctional membranes have been estimated and found to change with the concentration of glucose. Externally applied mitochondrial blockers induced a moderate increase in the junctional resistance possibly mediated by an increase in intracellular Ca²⁺.     

Streamless aggregation of Dictyostelium in the presence of isopropylidenadenosin

Starving cells of Dictyostelium discoideum undergo a developmental cycle where cAMP is autocatalytically produced and relayed from cell to cell, resulting in the propagation of excitation waves over a spatially extended population. Later on the homogeneous cell layer transforms into a pattern of cell streams directed perpendicular to the cAMP waves. Here we chemically influence aggregation competent cells by isopropylidenadenosin (IPA), an adenosine derivative. It can be assumed, that IPA acts via specific adenosine binding sites localized in the cellular membrane. We find, however, that pattern formation and cellular aggregation under the influence of IPA differ considerably compared to experiments with adenosine. In particular, our observations point towards an inhibitory effect on adenylate cyclase (ACA), the key enzyme in the autocatalytic production process of cAMP inside the cell. Our results suggest the existence of a direct coupling (via intracellular affection) or indirect coupling (via inhibition of cAMP binding) of the specific adenosine receptors to the regulatory circuit that controls cyclic intra- and extracellular cAMP concentration.     

Influence of intracellular injection of H+ on the electrical coupling in cardiac Purkinje fibres

The effect of intracellular injection of H+ on the electrical coupling of canine Purkinje cells was investigated. It was found that H+ increased the intracellular resistance (ri) and caused electrical uncoupling. The effect of high (H+)i on cell communication was partially reverted by intracellular injection of EDTA. These observations seem to indicate that the effect of low pHi on the electrical coupling can be explained, at least in part, by a rise in free [Ca2+]i. Further studies are required.     

Temperature effects on a slow-crustacean neuromuscular system

The membrane potential of the E2 axon and the bender muscle fibers increased with temperature. The input resistance of the axon, the spike amplitude and time course declined with temperature. Excitatory junctional potentials (ejps) exhibited maximum amplitudes and minimum facilitation at about the same temperature. Ejp time course and muscle membrane input resistance declined with temperature. Tension produced by the muscle also declined but then increased when additional spikes were generated in the periphery of the E2 axon.     

Scaling of postcontractile phosphocreatine recovery in fish white muscle: effect of intracellular diffusion

In some fish, hypertrophic growth of white muscle leads to very large fibers. The associated low-fiber surface area-to-volume ratio (SA/V) and potentially long intracellular diffusion distances may influence the rate of aerobic processes. We examined the effect of intracellular metabolite diffusion on mass-specific scaling of aerobic capacity and an aerobic process, phosphocreatine (PCr) recovery, in isolated white muscle from black sea bass (Centropristis striata). Muscle fiber diameter increased during growth and was >250 mum in adult fish. Mitochondrial volume density and cytochrome-c oxidase activity had similar small scaling exponents with increasing body mass (-0.06 and -0.10, respectively). However, the mitochondria were more clustered at the sarcolemmal membrane in large fibers, which may offset the low SA/V, but leads to greater intracellular diffusion distances between mitochondrial clusters and ATPases. Despite large differences in intracellular diffusion distances, the postcontractile rate of PCr recovery was largely size independent, with a small scaling exponent for the maximal rate (-0.07) similar to that found for the indicators of aerobic capacity. Consistent with this finding, a mathematical reaction-diffusion analysis indicated that the resynthesis of PCr (and other metabolites) was too slow to be substantially limited by diffusion. These results suggest that the recovery rate in these fibers is primarily limited by low mitochondrial density. Additionally, the change in mitochondrial distribution with increasing fiber size suggests that low SA/V and limited O(2) flux are more influential design constraints in fish white muscle, and perhaps other fast-twitch vertebrate muscles, than is intracellular metabolite diffusive flux.     

Electrotonic suppression of early afterdepolarizations in isolated rabbit Purkinje myocytes

Many studies suggest that early afterdepolarizations (EADs) arising from Purkinje fibers initiate triggered arrhythmias under pathological conditions. However, electrotonic interactions between Purkinje and ventricular myocytes may either facilitate or suppress EAD formation at the Purkinje-ventricular interface. To determine conditions that facilitated or suppressed EADs during Purkinje-ventricular interactions, we coupled single Purkinje myocytes and aggregates isolated from rabbit hearts to a passive model cell via an electronic circuit with junctional resistance (R(j)). The model cell had input resistance (R(m,v)) of 50 M Omega, capacitance of 39 pF, and a variable rest potential (V(rest,v)). EADs were induced in Purkinje myocytes during superfusion with 1 microM isoproterenol. Coupling at high R(j) to normally polarized V(rest,v) established a repolarizing coupling current during all phases of the Purkinje action potential. This coupling current preferentially suppressed EADs in single cells with mean membrane resistance (R(m,p)) of 297 M Omega, whereas EAD suppression in larger aggregates with mean R(m,p) of 80 M Omega required larger coupling currents. In contrast, coupling to elevated V(rest,v) established a depolarizing coupling current during late phase 2, phase 3, and phase 4 that facilitated EAD formation and induced spontaneous activity in single Purkinje myocytes and aggregates. These results have important implications for arrhythmogenesis in the infarcted heart when reduction of the ventricular mass due to scarring alters the R(m,p)-to-R(m,v) ratio and in the ischemic heart when injury currents are established during coupling between polarized Purkinje myocytes and depolarized ventricular myocytes.     

成年大鼠视皮层(17区)神经元间的染色耦合--离体脑片研究

在离体脑片上,用生物胞素（biocytin）对成年大鼠视皮层神经元进行胞内注射。在标记成功的49例中,21例（42．9％）有染色耦合现象,耦合细胞的个数从2个到5个不等,平均2．8±1．1个。其中,18例为锥体-锥体神经元之间的耦合,2例为锥体-非锥体神经元之间的耦合,1例为非锥体神经元之间的耦合。在耦合细胞中,只有5例的胞体紧靠在一起,其它细胞的胞体之间都有一定的距离,其中有1例达到了635μm。大多数情况下（19／21例）,耦合细胞的胞体位于同一层次内,只有2例胞体位于不同层次。在Ⅱ／Ⅲ、Ⅳ和Ⅴ层内都观察到染色耦合神经元,但以Ⅱ／Ⅲ层内发生染色耦合的比率为最高。比较了染色耦合与非耦合神经元的某些电生理特性,没有观察到在它们之间有明显的差别。     

Estimation of the junctional resistance between electrically coupled receptor cells in Necturus taste buds

Junctional resistance between coupled receptor cells in Necturus taste buds was estimated by modeling the results from single patch pipette voltage clamp studies on lingual slices. The membrane capacitance and input resistance of coupled taste receptor cells were measured to monitor electrical coupling and the results compared with those calculated by a simple model of electrically coupled taste cells. Coupled receptor cells were modeled by two identical receptor cells connected via a junctional resistance. On average, the junctional resistance was approximately 200-300 M omega. This was consistent with the electrophysiological recordings. A junctional resistance of 200-300 M omega is close to the threshold for Lucifer yellow dye-coupling detection (approximately 500 M omega). Therefore, the true extent of coupling in taste buds might be somewhat greater than that predicted from Lucifer yellow dye coupling. Due to the high input resistance of single taste receptor cells (> 1 G omega), a junctional resistance of 200-300 M omega assures a substantial electrical communication between coupled taste cells, suggesting that the electrical activity of coupled cells might be synchronized.     

Synaptic inhibition and cell communication; impairment of cell-to-cell coupling produced by gamma-aminobutyric acid (GABA) in the somatic musculature of Ascaris lumbricoides

The influence of gamma-aminobutyric acid (GABA) (10(-5) M) on the electrical coupling of giant somatic muscle cells of Ascaris lumbricoides was investigated. GABA enhanced the resting potential of the cells and abolished the spike activity. The coupling coefficient (V2/V1) was reduced by 58.8% while the input resistance (Rin) was decreased by 38.8%. The decline in Rin was not related to unlinearity of the current-voltage relation. As the time constant of cell membrane was reduced by 28.4% by the addition of GABA the effect of the neurotransmitter on cell-to-cell coupling seems to be mainly related to a decrease in resistance of the non-junctional membrane due to an increase in chloride conductance.     

Intracellular cyclic AMP concentration modulates gap junction permeability in parturient rat myometrium.

We investigated whether cell-to-cell coupling between myometrial cells of parturient rats is influenced by intracellular adenosine 3',5'-cyclic monophosphate (cAMP) concentration. To evaluate the coupling, we measured input resistance (Ro) and injected Lucifer Yellow (LY) using microelectrode techniques. The intercellular spread of the dye was then observed. Longitudinal muscle strips from rat myometrium were exposed to isoproterenol, forskolin, or dibutyryl cAMP (DB-cAMP) to elevate cAMP. Isoproterenol (10(-11)-10(-6) M) and DB-cAMP (10(-5)-10(-3) M) hyperpolarized the resting membrane potential (Em) and increased Ro in a dose-dependent fashion. Forskolin (10(-6) M) also hyperpolarized Em and increased Ro. When LY was injected into a single cell, LY spread rapidly and extensively to neighboring cells in parturient control tissues, while LY transfer was completely blocked by any of the three agents at high concentrations. The increased Ro and blocked transfer of LY owing to these agents indicate that the cell-to-cell coupling was decreased both electrically and metabolically. Myometrial cells of parturient rats show increased number and size of gap junctions (GJs). The rapid and reversible decrease in coupling is interpreted to reflect the reduced permeability of GJs between the muscle cells because of an elevation of cAMP. Control of GJ permeability by this second messenger may be important for the physiological regulation of intercellular coupling and the extent of synchronizing and coordinating electrical, metabolic, and contractile activity in the uterine wall during pregnancy and parturition.     

Deficiency of triad junction and contraction in mutant skeletal muscle lacking junctophilin type 1

In skeletal muscle excitation-contraction (E-C) coupling, the depolarization signal is converted from the intracellular Ca2+ store into Ca2+ release by functional coupling between the cell surface voltage sensor and the Ca2+ release channel on the sarcoplasmic reticulum (SR). The signal conversion occurs in the junctional membrane complex known as the triad junction, where the invaginated plasma membrane called the transverse-tubule (T-tubule) is pinched from both sides by SR membranes. Previous studies have suggested that junctophilins (JPs) contribute to the formation of the junctional membrane complexes by spanning the intracellular store membrane and interacting with the plasma membrane (PM) in excitable cells. Of the three JP subtypes, both type 1 (JP-1) and type 2 (JP-2) are abundantly expressed in skeletal muscle. To examine the physiological role of JP-1 in skeletal muscle, we generated mutant mice lacking JP-1. The JP-1 knockout mice showed no milk suckling and died shortly after birth. Ultrastructural analysis demonstrated that triad junctions were reduced in number, and that the SR was often structurally abnormal in the skeletal muscles of the mutant mice. The mutant muscle developed less contractile force (evoked by low-frequency electrical stimuli) and showed abnormal sensitivities to extracellular Ca2+. Our results indicate that JP-1 contributes to the construction of triad junctions and that it is essential for the efficiency of signal conversion during E-C coupling in skeletal muscle.     

Differential determinants for coupling of distinct G proteins with the class B secretin receptor

The secretin receptor is a prototypic class B G protein-coupled receptor that is activated by binding of its natural peptide ligand. The signaling effects of this receptor are mediated by coupling with Gs, which activates cAMP production, and Gq, which activates intracellular calcium mobilization. We have explored the molecular basis for the coupling of each of these G proteins to this receptor using systematic site-directed mutagenesis of key residues within each of the intracellular loop regions, and studying ligand binding and secretin-stimulated cAMP and calcium responses. Mutation of a conserved histidine in the first intracellular loop (H157A and H157R) markedly reduced cell surface expression, resulting in marked reduction in cAMP and elimination of measurable calcium responses. Mutation of an arginine (R153A) in the first intracellular loop reduced calcium, but not cAMP responses. Mutation of a dibasic motif in the second intracellular loop (R231A/K232A) had no significant effects on any measured responses. Mutations in the third intracellular loop involving adjacent lysine and leucine residues (K302A/L303A) or two arginine residues separated by a leucine and an alanine (R318A/R321A) significantly reduced cAMP responses, while the latter also reduced calcium responses. Additive effects were elicited by combining the effective mutations, while combining all the effective mutations resulted in a construct that continued to bind secretin normally, but that elicited no significant cAMP or calcium responses. These data suggest that, while some receptor determinants are clearly shared, there are also distinct determinants for coupling with each of these G proteins.