Functional reconstitution and characterization of recombinant human alpha 1-glycine receptors.

By utilizing a baculoviral expression system described previously (Cascio, M., Schoppa, N. E.

Regulation of the eel electroplax Na channel and phosphorylation of residues on amino- and carboxyl-terminal domains by cAMP-dependent protein kinase.

Previous studies have shown that the short-motif electroplax Na channel is phosphorylated in vitro by cyclic AMP-dependent protein kinase (PKA) at serines 6 or 7 and 1776 and threonine 17 (Emerick & Agnew, 1989). We here show that phosphatase treatment of solubilized, purified Na channels enhanced subsequent PKA labeling of four of five tryptic phosphopeptides, indicating that these sites are phosphorylated in vivo. Microsequencing and analysis of PTH-amino acid products revealed endogenous labeling of serines 6, 444, 1680, and 1776.

Patch recordings from the electrocytes of electrophorus. Na channel gating currents.

Gating currents were recorded at 11 degrees C in cell-attached and inside-out patches from the innervated membrane of Electrophorus main organ electrocytes. With pipette tip diameters of 3-8 microns, maximal charge measured in patches ranged from 0.74 to 7.

Patch recordings from the electrocytes of Electrophorus electricus. Na currents and PNa/PK variability.

Sodium currents were recorded in cell-attached and inside-out patches from the innervated membrane of Electrophorus electrocytes. Electrocytes from Sachs and main electric organs were prepared as described by Pasquale et al. (1986.

Voltage-sensitive sodium channels: agents that perturb inactivation gating.

In summary, the voltage-sensitive sodium channel from eel electroplax provides an optimal preparation for biochemical and biophysical studies of molecular structure and gating. We have demonstrated that the purified and reconstituted protein is capable of functioning normally, exhibiting, among other properties, voltage-dependent activation and inactivation gating mechanisms. We have been able to recreate the classical electrophysiological studies in which inactivation gating can be removed by proteolytic modification of the cytoplasmic surface of the molecule, and have mapped the probable site of modification to the peptide segment lying between subunit domains III and IV.