Nerve growth factor increases the number of functional Na channels and induces TTX-resistant Na channels in PC12 pheochromocytoma cells.

The PC12 clone is a line of rat pheochromocytoma cells that undergoes neuronal differentiation in the presence of NGF protein. In the absence of NGF, PC12 cells are electrically inexcitable, while after several weeks of NGF treatment they develope Na+ action potentials. Past estimates made by measuring binding of 3H-saxitoxin (STX) indicate that NGF treatment brings about a large increase in Na channel density that is of sufficient magnitude to account for the induction of excitability. We have now used 22Na uptake to measure the Na permeability of PC12 cells before and after long-term NGF treatment. Treatment with NGF does not change the resting Na+ permeability. The alkaloid toxins veratridine and batrachotoxin (BTX) and scorpion toxin were used to activate Na channels. Such studies demonstrate that these toxins induce TTX-sensitive Na uptake in both NGF-treated and untreated cells and reveal differences in functional Na channel numbers per cell and per unit of membrane area that are similar to those found in the STX binding studies. On the other hand, affinities for drugs that activate these channels are not affected by NGF treatment. We also find that NGF-treated PC12 cells contain a population of Na channels with low affinity for TTX. These channels account for 5-20% of total BTX or veratridine-stimulated flux. Thus, NGF has 2 effects regarding the Na channels of PC12 cells: it increases the number of functional Na channels that otherwise behave similarly to those present before NGF treatment, and it induces the presence of TTX-resistant Na channels. These findings indicate that the PC12 model system may serve to study the developmental regulation of Na channel expression and properties.