Development of saxitoxin-sensitive and insensitive sodium channels in cultured neonatal rat astrocytes.

Voltage-sensitive Na channels were studied in cultures of neonatal rat cortical astrocytes. These channels were present at all times in culture as determined by tracer 22Na+ influx in the presence of batrachotoxin (BTX) and sea anemone polypeptide toxin (AxTx). The affinity of saxitoxin (STX) binding and sensitivity to STX inhibition of sodium influx were utilized to characterize these channels. Up to 7 d in culture, high-affinity 3H-STX binding (Kd of 0.2 nM at 4 degrees C) was very low, and 22Na+ influx was inhibited only by high concentrations (Ki = 170 nM) of STX. From 7 to 14 d, total specific binding of STX increased to a maximum of over 2 pmol/mg protein and remained constant for 28 d. By 14 d, inhibition of 22Na+ influx by STX was clearly biphasic, indicating the presence of 2 populations of channels with Ki's of 0.2 nM and 150 nM. At 14 d in culture, binding of 3H-STX to astrocyte membranes revealed the presence of 2 specific sites. During this second week, increasing numbers of high-affinity STX binding sites and increasing sensitivity to the inhibition of BTX + AxTx-stimulated 22Na+ influx by STX coincided with the change in morphology of primitive flat polygonal cells to highly branched stellate forms characteristic of mature astrocytes in vivo. Changes in culture conditions modified the time course of the onset of high STX affinity binding. Twenty-four hours after changing to serum-free G5 medium, there was both an 8-fold increase in STX binding sites and a change to a stellate shape in all cells. The results suggest that although low-affinity STX Na channels are always present in astrocytes, after 7 d in culture a different population of channels appears with the high affinity for STX characteristic of adult neuronal sodium channels. This spontaneous process is greatly accelerated by changing to a chemically defined medium.