Discharge patterns evoked by depolarizing current injection in basal optic nucleus neurons of the pigeon

Voltage-gated potassium channels involved in regulation of physiological function in MrgprA3-specific itch neurons

Itch is described as an unpleasant or irritating skin sensation that elicits the desire or reflex to scratch. MrgprA3, one of members of the Mrgprs family, is specifically expressed in a subpopulation of dorsal root ganglion (DRG) in the peripheral nervous system (PNS). These MrgprA3-expressing DRG neurons have been identified as itch-specific neurons. They can be activated by the compound, chloroquine, which is used as a drug to treat malaria. In the present study, we labeled these itch-specific neurons using the method of molecular genetic markers, and then studied their electrophysiological properties. We also recorded the cutaneous MrgprA3(-) neurons retrogradely labeled by Dil dye (MrgprA3(-)-Dil). We first found that MrgprA3(+) neurons have a lower excitability than MrgprA3(-) neurons (MrgprA3(-)-non-Dil and MrgprA3(-)-Dil). The number of action potential (AP) was reduced more obviously in MrgprA3(+) neurons than that of in MrgprA3(-) neurons. In most cases, MrgprA3(+) neurons only generated single AP; however, in MrgprA3(-) neurons, the same stimulation could induce multiple AP firing due to the greater voltage-gated potassium (Kv) current existence in MrgprA3(+) than in MrgprA3(-) neurons. Thus, Kv current plays an important role in the regulation of excitability in itch-specific neurons.

Firing properties and dye coupling of neurons in the pigeon nucleus semilunaris

Our previous study indicated that the nucleus semilunaris in birds is a visual center. The present study using pigeon brain slices shows that 84 semilunar cells examined could be grouped into five types according to responses to depolarizing current injections. Type I cells (early bursting, 44%) fire a single burst followed by regular spiking. Type II cells (regular spiking, 13%) regularly produce spikes, the rates of which are enhanced as currents are increased. Type III cells (bursting, 17%) discharge a series of bursts each consisting of 2-4 spikes. Type IV cells (dual spiking, 15%) evoke both spikes and spikelets. Type V cells (inhibition-following, 11%) are characterized by regular spiking followed by an inhibitory period after current cessation. Morphologically, semilunar neurons have piriform, round, or fusiform somata of 12-23 mum in diameter, which give rise to 2-4 primary dendrites with sparse branches. Dual spiking activity is invariably correlated with dye coupling, and bursting cells have a tendency to be fusiform in shape. Other types of semilunar cells do not show a correlation between their firing patterns and morphological features.