Adenosine A2A receptor induces protein kinase A-dependent functional modulation of human (alpha)3(beta)4 nicotinic receptor.

Adenosine modulates the function of nicotinic ACh receptors (nAChRs) in a variety of preparations, possibly through pathways involving protein kinase A (PKA), but these phenomena have not yet been investigated in detail. In this work we studied, using the patch clamp technique, the functional modulation of recombinant human α3ß4 nAChR by the A2A adenosine receptor, co-expressed in HEK cells. Tonic activation of A2A receptor slowed current decay during prolonged applications of nicotine and accelerated receptor recovery from desensitization. Together, these changes resulted into a more sustained current response upon multiple nicotine or ACh applications. These findings were confirmed in cultured mouse superior cervical ganglion neurones, which express nAChR containing the α3 subunit together with ß2 and/or ß4 and A2A receptor. Expression of the A2A receptor in HEK cells also increased the apparent potency of nAChR for nicotine, further supporting a general A2A-induced gain of function for nAChR. These effects were dependent on PKA since the direct activation of PKA mimicked, and its inhibition prevented almost completely, the effects of the A2A receptor. Mutations of R385 and S388 in the cytoplasmic loop of the α3 subunit abolished the functional modulation of nAChR induced by activation of A2A receptor, PKA and other Ser/Thr kinases, suggesting that this region constitutes a putative consensus site for these kinases. These data provide conclusive evidence that activation of the A2A receptor determines functional changes

Mutant human ß4 subunit identified in amyotrophic lateral sclerosis patients impairs nicotinic receptor function.

Recently identified mutations in the genes encoding the neuronal nicotinic ACh receptor (nAChR) subunits in patients affected by sporadic amyotrophic lateral sclerosis (sALS) may represent a factor which enhances disease susceptibility, in particular in association with ambient causes such as cigarette smoking. In this work, we characterize the functional properties of nAChRs containing the ß4R349C subunit, the mutation most frequently encountered in sALS patients. The mutation was coexpressed with wild-type α3 or α4 subunits or with mutant α4R487Q subunit, which has been detected in one patient together with ß4R349C mutation. None of the functional parameters examined showed differences between α4ß4 and α4R487Qß4 nAChRs. By contrast, ß4R349C mutation, independent of the companion α subunit, caused the reduction in potency of both ACh and nicotine, decreased the density of whole-cell current evoked by maximal transmitter concentrations, and altered the kinetics of ACh-evoked whole-cell currents. These data confirm that sALS-associated mutations in nicotinic subunits may markedly perturb cholinergic transmission in individuals bearing the mutations.

Lack of dystrophin functionally affects α3ß2/ß4-nicotinic acethylcholine receptors in sympathetic neurons of dystrophic mdx mice.

In the sympathetic superior cervical ganglion (SCG), nicotinic acetylcholine receptors (nAChRs) mediate fast synaptic transmission. We previously demonstrated that in SCG neurons of mdx mice, an animal model for Duchenne muscular dystrophy, lack of dystrophin causes a decrease, compared to the wild-type, in post-synaptic nAChRs containing the α3 subunit associated with ß2 and/or ß4 (α3ß2/ß4-nAChRs), but not in those containing the α7 subunit. Here we show, by whole cell patch-clamp recordings from cultured SCG neurons, that both nicotine and acetylcholine-evoked currents through α3ß2/ß4-nAChRs are significantly reduced in mdx mice compared to the wild-type, while those through α7-nAChR are unaffected. This reduction associates with that of protein levels of α3, ß2 and ß4 subunits. Therefore, we suggest that, in mdx mouse SCG neurons, lack of dystrophin, by specifically affecting membrane stabilization of α3ß2/ß4-nAChRs, could determine an increase in receptor internalization and degradation, with consequent reduction in the fast intraganglionic cholinergic transmission.