Neurotrophins induce BDNF expression through the glutamate receptor pathway in neocortical neurons.

Neurotrophins jointly exert various functions in the nervous system, including neuronal differentiation, survival, and regulation of synaptic plasticity. However, the functional interactions of neurotrophins or mechanisms through which neurotrophins regulate each other are still not clear. In the present study, brain-derived neurotrophic factor (BDNF) mRNA expression is induced by neurotrophin-4/5 (NT-4/5) and by BDNF itself in neocortical neurons. K252a, a specific tyrosine kinase (Trk) inhibitor, completely suppresses BDNF- and NT-4/5-enhanced BDNF mRNA expression. NT-4/5 significantly augments BDNF protein production, which is also reversed by K252a. When neurons are incubated with neurotrophin-3 (NT-3) or nerve growth factor (NGF), there are no significant changes in BDNF mRNA or protein expression. Interestingly, the alpha-amino-3-hydroxy-5-methylisoxazole-4-propionate (AMPA) receptor blocker 6-cyano-7-nitroquinoxaline-2,3-dione (CNQX) or the N-methyl-D-aspartate (NMDA) receptor blocker AP-5 completely suppresses NT-4/5-enhanced BDNF protein production, while tetrodotoxin (TTX) only suppresses NT-4/5-enhanced BDNF production by 50%. Additionally, the mitogen activated protein (MAP) kinase inhibitor PD98059 enhances BDNF-induced glutamate receptor-1 (GluR1) protein expression, but a phosphatidylinositol 3-kinase (PI3K) inhibitor LY294002 strongly reduces BDNF-induced GluR1 protein expression. Taken together, glutamate receptors are important for the regulation of BDNF expression by neurotrophins, and MAP and PI3K kinases differentially modulate AMPA receptor expression in the cortical neurons.

Tyrosine-kinase-dependent recruitment of RGS12 to the N-type calcium channel.

Gamma-aminobutyric acid (GABA)B receptors couple to Go to inhibit N-type calcium channels in embryonic chick dorsal root ganglion neurons. The voltage-independent inhibition, mediated by means of a tyrosine-kinase pathway, is transient and lasts up to 100 seconds. Inhibition of endogenous RGS12, a member of the family of regulators of G-protein signalling, selectively alters the time course of voltage-independent inhibition. The RGS12 protein, in addition to the RGS domain, contains PDZ and PTB domains. Fusion proteins containing the PTB domain of RGS12 alter the rate of termination of the GABA(B) signal, whereas the PDZ or RGS domains of RGS 12 have no observable effects. Using primary dorsal root ganglion neurons in culture, here we show an endogenous agonist-induced tyrosine-kinase-dependent complex of RGS12 and the calcium channel. These results indicate that RGS12 is a multifunctional protein capable of direct interactions through its PTB domain with the tyrosine-phosphorylated calcium channel. Recruitment of RGS proteins to G-protein effectors may represent an additional mechanism for signal termination in G-protein-coupled pathways.

Selective coupling of G protein beta gamma complexes to inhibition of Ca2+ channels.

Several mechanisms couple heterotrimeric guanine nucleotide-binding proteins (G proteins) to cellular effectors. Although alpha subunits of G proteins (Galpha) were the first recognized mediators of receptor-effector coupling, Gbetagamma regulation of effectors is now well known. Five Gbeta and 12 Ggamma subunit genes have been identified, suggesting through their diversity that specific subunits couple selectively to effectors. The molecular determinants of Gbetagamma-effector coupling, however, are not well understood, and most studies of G protein-effector coupling do not support selectivity of Gbetagamma action. To explore this issue further, we have introduced recombinant Gbetagamma complexes into avian sensory neurons and measured the inhibition of Ca(2+) currents mediated by an endogenous phospholipase Cbeta- (PLCbeta) and protein kinase C-dependent pathway. Activities of Gbetagamma in the native cells were compared with enzyme assays performed in vitro. We report a surprising selective activation of the PLCbeta pathway by Gbetagamma complexes containing beta(1) subunits, whereas beta(2)-containing complexes produced no activation. In contrast, when assayed in vitro, PLCbeta and type II adenylyl cyclase did not discriminate among these same Gbetagamma complexes, suggesting the possibility that additional cellular determinants confer specificity in vivo.

Regulators of G protein signaling proteins as determinants of the rate of desensitization of presynaptic calcium channels.

Norepinephrine inhibits omega-conotoxin GVIA-sensitive presynaptic Ca2+ channels in chick dorsal root ganglion neurons through two pathways, one mediated by Go and the other by Gi. These pathways desensitize at different rates. We have found that recombinant Galpha interacting protein (GAIP) and regulators of G protein signaling (RGS)4 selectively accelerate the rate of desensitization of Go- and Gi-mediated pathways, respectively. Blockade of endogenous RGS proteins using antibodies raised against Galpha interacting protein and RGS4 slows the rate of desensitization of these pathways in a selective manner. These results demonstrate that different RGS proteins may interact with Gi and Go selectively, giving rise to distinct time courses of transmitter-mediated effects.

Novel form of crosstalk between G protein and tyrosine kinase pathways.

Neuronal Ca2+ channels are inhibited by a variety of transmitter receptors coupled to Go-type GTP-binding proteins. Go has been postulated to work via a direct interaction between an activated G protein subunit and the Ca2+ channel complex. Here we show that the inhibition of sensory neuron N-type Ca2+ channels produced by gamma-aminobutyric acid involves a novel, rapidly activating tyrosine kinase signaling pathway that is mediated by Galphao and a src-like kinase. In contrast to other recently described G protein-coupled tyrosine kinase pathways, the Galphao-mediated modulation requires neither protein kinase C nor intracellular Ca2+. The results suggest that this pathway mediates rapid receptor-G protein signaling in the nervous system and support the existence of a previously unrecognized form of crosstalk between G protein and tyrosine kinase pathways.

Monoclonal antibodies reveal receptor specificity among G-protein-coupled receptor kinases.

Guanine nucleotide-binding regulatory protein (G protein)-coupled receptor kinases (GRKs) constitute a family of serine/threonine kinases that play a major role in the agonist-induced phosphorylation and desensitization of G-protein-coupled receptors. Herein we describe the generation of monoclonal antibodies (mAbs) that specifically react with GRK2 and GRK3 or with GRK4, GRK5, and GRK6. They are used in several different receptor systems to identify the kinases that are responsible for receptor phosphorylation and desensitization. The ability of these reagents to inhibit GRK- mediated receptor phosphorylation is demonstrated in permeabilized 293 cells that overexpress individual GRKs and the type 1A angiotensin II receptor. We also use this approach to identify the endogenous GRKs that are responsible for the agonist-induced phosphorylation of epitope-tagged beta2- adrenergic receptors (beta2ARs) overexpressed in rabbit ventricular myocytes that are infected with a recombinant adenovirus. In these myocytes, anti-GRK2/3 mAbs inhibit isoproterenol-induced receptor phosphorylation by 77%, while GRK4-6-specific mAbs have no effect. Consistent with the operation of a betaAR kinase-mediated mechanism, GRK2 is identified by immunoblot analysis as well as in a functional assay as the predominant GRK expressed in these cells. Microinjection of GRK2/3-specific mAbs into chicken sensory neurons, which have been shown to express a GRK3-like protein, abolishes desensitization of the alpha2AR-mediated calcium current inhibition. The intracellular inhibition of endogenous GRKs by mAbs represents a novel approach to the study of receptor specificities among GRKs that should be widely applicable to many G-protein-coupled receptors.

G protein-coupled receptor kinase mediates desensitization of norepinephrine-induced Ca2+ channel inhibition.

G protein-coupled receptors are essential signaling molecules at sites of synaptic transmission. Here, we explore the mechanisms responsible for the use-dependent termination of metabotropic receptor signaling in embryonic sensory neurons. We report that the inhibition of voltage-dependent Ca2+ channels mediated by alpha2-adrenergic receptors desensitizes slowly with prolonged exposure to the transmitter and that the desensitization is mediated by a G protein-coupled receptor kinase (GRK). Intracellular introduction of recombinant, purified kinases or synthetic blocking peptides into individual neurons demonstrates the specific involvement of a GRK3-like protein. These results suggest that GRK-mediated termination of receptor-G protein coupling is likely to regulate synaptic strength and, as such, may provide one effective mechanism for depression of synaptic transmission.

Interaction of convergent pathways that inhibit N-type calcium currents in sensory neurons.

Norepinephrine and GABA inhibit omega-conotoxin GVIA-sensitive (N-type) calcium current in embryonic sensory neurons by separate pathways. We have investigated the mechanisms that limit the modulation of N current by varying the level of activation for a single pathway or simultaneously activating multiple pathways. Calcium currents were measured with tight-seal, whole-cell recording methods. Simultaneous application of the two transmitters at saturating concentrations produced a larger inhibition of the current than either transmitter by itself, but the maximal inhibition was not linearly additive. Maximal, direct activation of GTP-binding proteins by intracellular application of guanosine 5'-(3-O-thio)-triphosphate (GTP gamma S) resulted in a similar limit to the inhibition; furthermore, GTP gamma S did not enhance the maximal inhibition produced by co-application of transmitters. Interventions downstream in the modulatory pathway (e.g. direct activation of protein kinase C or inhibition of protein phosphatases) were also unable to alter the maximal limit for inhibition. These results suggest that transmitter-mediated inhibition is not limited by receptor number, levels of G-protein or protein kinase C activation, or degree of phosphorylation; rather, the extent of inhibition may be limited by the structural properties of the N channels themselves.

Transmitter-mediated inhibition of N-type calcium channels in sensory neurons involves multiple GTP-binding proteins and subunits.

The modulation of voltage-activated Ca2+ channels by neurotransmitters and peptides is very likely a primary means of regulating Ca(2+)-dependent physiological functions such as neurosecretion, muscle contraction, and membrane excitability. In neurons, N-type Ca2+ channels (defined as omega-conotoxin GVIA-sensitive) are one prominent target for transmitter-mediated inhibition. This inhibition is widely thought to result from a shift in the voltage independence of channel gating. Recently, however, voltage-independent inhibition has also been described for N channels. As embryonic chick dorsal root ganglion neurons express both of these biophysically distinct modulatory pathways, we have utilized these cells to test the hypothesis that the voltage-dependent and -independent actions of transmitters are mediated by separate biochemical pathways. We have confirmed this hypothesis by demonstrating that the two modulatory mechanisms activated by a single transmitter involve not only different classes of G protein but also different G protein subunits.

Distinct, convergent second messenger pathways modulate neuronal calcium currents.

Norepinephrine (NE) and gamma-aminobutyric acid (GABA) inhibit N-type calcium channels in embryonic chick sensory neurons. We demonstrate here that the modulatory actions of the two transmitters are mediated through distinct biochemical pathways. Intracellular application of the pseudosubstrate inhibitor for protein kinase C blocks the inhibition produced by NE (and the protein kinase C activator oleoylacetylglycerol), but not that produced by GABA. Calcium current inhibition produced by oleoylacetylglycerol occludes inhibition by subsequent application of NE; GABA-mediated inhibition, however, is not eliminated by prior activation of protein kinase C. These results demonstrate that multiple biochemical pathways converge to control N-type calcium channel function.

Multiple actions of extracellular ATP on calcium currents in cultured bovine chromaffin cells.

Hormone secretion from chromaffin cells is evoked by calcium influx through voltage-dependent channels in the plasma membrane. Previous studies have shown that ATP, cosecreted with catecholamines from chromaffin granules, can modulate the secretion resulting from depolarization by nicotinic agonists. The immediate effect of ATP is to enhance secretion; more prolonged exposure to the nucleotide results in inhibition. These receptor-mediated actions of ATP involve the activation of at least two separate classes of GTP-binding protein. Results from electrophysiological experiments reported here demonstrate that the modulatory actions of ATP can, in large part, be explained by the effects of the nucleotide on inward calcium current. ATP shows a rapid enhancement and a slower, persistent inhibition of the depolarization-induced inward current.