P2Y2 receptor activation regulates the expression of acetylcholinesterase and acetylcholine receptor genes at vertebrate neuromuscular junctions.

At the vertebrate neuromuscular junction (nmj), ATP is known to be coreleased with acetylcholine from the synaptic vesicles. We have previously shown that the P2Y1 receptor is localized at the nmj. Here, we extend the findings to show that another nucleotide receptor, P2Y2, is also localized there and with P2Y1 jointly mediates trophic responses to ATP. The P2Y2 receptor mRNA in rat muscle increased during development and peaked in adulthood. The P2Y2 receptor protein was shown to become restricted to the nmjs during embryonic development, in chick and in rat. In both rat and chick myotubes, P2Y1 and P2Y2 are expressed, increasing with differentiation, but P2Y4 is absent. The P2Y2 agonist UTP stimulated there inositol trisphosphate production and phosphorylation of extracellular signal-regulated kinases, in a dose-dependent manner. These UTP-induced responses were insensitive to the P2Y1-specific antagonist MRS 2179 (2'-deoxy-N6-methyl adenosine 3',5'-diphosphate diammonium salt). In differentiated myotubes, P2Y2 activation induced expression of acetylcholinesterase (AChE) protein (but not control alpha-tubulin). This was shown to arise from AChE promoter activation, mediated by activation of the transcription factor Elk-1. Two Elk-1-responsive elements, located in intron-1 of the AChE promoter, were found by mutation to act in this gene activation initiated at the P2Y2 receptor and also in that initiated at the P2Y1 receptor. Furthermore, the promoters of different acetylcholine receptor subunits were also stimulated by application of UTP to myotubes. These results indicate that ATP regulates postsynaptic gene expressions via a common pathway triggered by the activation of P2Y1 and P2Y2 receptors at the nmjs.

ATP acts via P2Y1 receptors to stimulate acetylcholinesterase and acetylcholine receptor expression: transduction and transcription control.

At the vertebrate neuromuscular junction ATP is known to stabilize acetylcholine in the synaptic vesicles and to be co-released with it. We have shown previously that a nucleotide receptor, the P2Y1 receptor, is localized at the junction, and we propose that this mediates a trophic role for synaptic ATP there. Evidence in support of this and on its mechanism is given here. With the use of chick or mouse myotubes expressing promoter-reporter constructs from genes of acetylcholinesterase (AChE) or of the acetylcholine receptor subunits, P2Y1 receptor agonists were shown to stimulate the transcription of each of those genes. The pathway to activation of the AChE gene was shown to involve protein kinase C and intracellular Ca 2+ release. Application of dominant-negative or constitutively active mutants, or inhibitors of specific kinases, showed that it further proceeds via some of the known intermediates of extracellular signal-regulated kinase phosphorylation. In both chick and mouse myotubes this culminates in activation of the transcription factor Elk-1, confirmed by gel mobility shift assays and by the nuclear accumulation of phosphorylated Elk-1. All of the aforementioned activations by agonist were amplified when the content of P2Y1 receptors was boosted by transfection, and the activations were blocked by a P2Y1-selective antagonist. Two Elk-1 binding site sequences present in the AChE gene promoter were jointly sufficient to drive ATP-induced reporter gene transcription. Thus ATP regulates postsynaptic gene expression via a pathway to a selective transcription factor activation.

cDNA encodes Xenopus P2Y(1) nucleotide receptor: expression at the neuromuscular junctions.

A cDNA encoding P2Y(1) receptor was isolated by cross-hybridization with chicken homolog. The deduced amino acid sequence of P2Y(1) receptor with 361 amino residues is 80-85% identical to human, rodent and avian homologs. When the cDNA was expressed in mammalian cells, the activation of P2Y(1) receptor by adenine nucleotides stimulated the accumulation of inositol phosphate, and adenosine 3',5'-bismonophosphate (A3P5P) or other antagonists blocked its action; these pharmacological properties showed resemblance of P2Y(1) receptor family in higher vertebrate. A transcript encoding P2Y(1) receptor at approximately 3.2 kb was revealed in the brain, spinal cord and muscle of adult, and it is strongly expressed in developing brain, spinal cord and myotomal muscles of the embryos by hybridization. P2Y(1) receptor was shown to be restricted to the neuromuscular junctions and co-localized with AChRs in adult muscle. These results support the notion that ATP and its P2Y(1) receptor subtype are effectors in organizing the post-synaptic apparatus.

ATP induces post-synaptic gene expressions in vertebrate skeletal neuromuscular junctions.

In vertebrate neuromuscular junctions (nmjs), adenosine 5'-triphosphate (ATP) is stored at the motor nerve terminals and is co-released with acetylcholine during neural stimulation. Several lines of evidence suggest that the synaptic ATP can act as a synapse-organizing factor at the nmjs, mediated by metabotropic P2Y(1) receptors. P2Y(1) receptor mRNAs in chicken and rat muscles are low in embryo but increases markedly in the adult, and decreased after denervation. The P2Y(1) receptor protein is restricted to the nmjs and co-localized with AChRs in adult muscles. The activation of P2Y(1) receptor by adenine nucleotides in cultured chick myotubes stimulated the accumulation of inositol phosphates, intracellular Ca(2+) mobilization, protein kinase C activity and phosphorylation of extracellular signal-regulated kinases. The receptor activation led to an increase in the expression of transcripts encoding AChE catalytic subunit and AChR subunits. The ATP-induced post-synaptic gene expression is possibly mediated by the activation of signaling cascades of mitogen-activated protein kinase. Therefore, a model is being proposed here that the synaptic ATP has a role of synergy with other regulatory signals, such as neuregulin, which act via their post-synaptic receptors to activate second signaling molecules locally to enhance the transcription of AChR/AChE genes specifically in the adjacent sub-synaptic nuclei during the formation and, especially, the maintenance of post-synaptic specializations at the nmjs.