Movement of the Na+ Channel Inactivation Gate during Inactivation*

Phenylalanine 1489 in the inactivation gate of the rat brain IIA sodium channel α subunit is required for stable inactivation. It is proposed to move into the intracellular mouth of the pore and occlude it during inactivation, but direct evidence for movement of this residue during inactivation has not been presented. We used the substituted cysteine accessibility method to test the availability of a cysteine residue substituted at position 1489 to modification by methanethiosulfonate reagents applied from the cytoplasmic side. Mutation of Phe-1489 to Cys results in a small (8%) fraction of noninactivating current. Ag+ and methanethiosulfonate reagents irreversibly slowed the inactivation rate and increased the fraction of noninactivating current of F1489C but not wild-type channels. Single channel analysis showed that modification slowed inactivation from both closed and open states and destabilized the inactivated state. Depolarization prevented rapid modification of Cys-1489 by these reagents, and the voltage dependence of their reaction rate correlated closely with steady-state inactivation. Modification was not detectably voltage-dependent at voltages more negative than channel gating. Our results show that, upon inactivation, Phe-1489 in the inactivation gate moves from an exposed and modifiable position outside the membrane electric field to a buried and inaccessible position, perhaps in or near the intracellular mouth of the channel pore.

[1]  H. Takeshima,et al.  Expression of functional sodium channels from cloned cDNA , 1986, Nature.

[2]  R. Aldrich,et al.  Restoration of inactivation in mutants of Shaker potassium channels by a peptide derived from ShB , 1990, Science.

[3]  A. Brown,et al.  Effects of III-IV linker mutations on human heart Na+ channel inactivation gating. , 1994, Circulation Research.

[4]  A L Goldin,et al.  A cluster of hydrophobic amino acid residues required for fast Na(+)-channel inactivation. , 1992, Proceedings of the National Academy of Sciences of the United States of America.

[5]  S. Demo,et al.  The inactivation gate of the Shaker K+ channel behaves like an open-channel blocker , 1991, Neuron.

[6]  R. Horn,et al.  A molecular link between activation and inactivation of sodium channels , 1995, The Journal of general physiology.

[7]  B. Hille,et al.  Gating of Na channels. Inactivation modifiers discriminate among models , 1987, The Journal of general physiology.

[8]  C. Armstrong,et al.  Sodium channels and gating currents. , 1981, Physiological reviews.

[9]  R Horn,et al.  Effect of N-bromoacetamide on single sodium channel currents in excised membrane patches , 1982, The Journal of general physiology.

[10]  R. Aldrich,et al.  Energetics of Shaker K channels block by inactivation peptides , 1993, The Journal of general physiology.

[11]  B. Hille,et al.  Voltage clamp analysis of sodium channels in normal and scorpion toxin- resistant neuroblastoma cells , 1984, The Journal of neuroscience : the official journal of the Society for Neuroscience.

[12]  W. Catterall,et al.  Efficient expression of rat brain type IIA Na+ channel α subunits in a somatic cell line , 1992, Neuron.

[13]  P. Bennett,et al.  On the molecular nature of the lidocaine receptor of cardiac Na+ channels. Modification of block by alterations in the alpha-subunit III-IV interdomain. , 1995, Circulation research.

[14]  R Horn,et al.  Estimating the number of channels in patch recordings. , 1991, Biophysical journal.

[15]  W. Catterall,et al.  Restoration of inactivation and block of open sodium channels by an inactivation gate peptide , 1994, Neuron.

[16]  W. Catterall,et al.  A Critical Role for Transmembrane Segment IVS6 of the Sodium Channel α Subunit in Fast Inactivation (*) , 1995, The Journal of Biological Chemistry.

[17]  R Horn,et al.  Statistical properties of single sodium channels , 1984, The Journal of general physiology.

[18]  P. Vassilev,et al.  Identification of an intracellular peptide segment involved in sodium channel inactivation. , 1988, Science.

[19]  F. Sigworth,et al.  Data transformations for improved display and fitting of single-channel dwell time histograms. , 1987, Biophysical journal.

[20]  F. Conti,et al.  Structural parts involved in activation and inactivation of the sodium channel , 1989, Nature.

[21]  R. Keynes The ionic channels in excitable membranes. , 1975, Ciba Foundation symposium.

[22]  F. Bezanilla,et al.  Destruction of Sodium Conductance Inactivation in Squid Axons Perfused with Pronase , 1973, The Journal of general physiology.

[23]  C. F. Stevens,et al.  A reinterpretation of mammalian sodium channel gating based on single channel recording , 1983, Nature.

[24]  R. Aldrich,et al.  Interactions of amino terminal domains of Shaker K channels with a pore blocking site studied with synthetic peptides , 1993, The Journal of general physiology.

[25]  Ming Zhou,et al.  Sodium channel mutations in paramyotonia congenita uncouple inactivation from activation , 1994, Neuron.

[26]  H. Takeshima,et al.  Existence of distinct sodium channel messenger RNAs in rat brain , 1986, Nature.

[27]  A. L. Goldin,et al.  A rat brain na+ channel α subunit with novel gating properties , 1988, Neuron.

[28]  F. Sigworth,et al.  Impaired slow inactivation in mutant sodium channels. , 1996, Biophysical journal.

[29]  Chung-Chin Kuo,et al.  Na+ channels must deactivate to recover from inactivation , 1994, Neuron.

[30]  T Hoshi,et al.  Biophysical and molecular mechanisms of Shaker potassium channel inactivation , 1990, Science.

[31]  W. Catterall,et al.  Molecular Determinants of High Affinity Binding of α-Scorpion Toxin and Sea Anemone Toxin in the S3-S4 Extracellular Loop in Domain IV of the Na+ Channel α Subunit* , 1996, The Journal of Biological Chemistry.

[32]  I. Dance The structural chemistry of metal thiolate complexes , 1986 .

[33]  A. L. Goldin,et al.  Messenger RNA coding for only the alpha subunit of the rat brain Na channel is sufficient for expression of functional channels in Xenopus oocytes. , 1986, Proceedings of the National Academy of Sciences of the United States of America.

[34]  H. Sullivan Ionic Channels of Excitable Membranes, 2nd Ed. , 1992, Neurology.

[35]  A. Karlin,et al.  Acetylcholine receptor channel structure probed in cysteine-substitution mutants. , 1992, Science.

[36]  H A Fozzard,et al.  Kinetic analysis of single sodium channels from canine cardiac Purkinje cells , 1990, The Journal of general physiology.

[37]  W. Catterall,et al.  Structure and function of the β2 subunit of brain sodium channels, a transmembrane glycoprotein with a CAM motif , 1995, Cell.

[38]  J. Shafer,et al.  Reactivity of small thiolate anions and cysteine-25 in papain toward methyl methanethiosulfonate. , 1986, Biochemistry.

[39]  W. Catterall,et al.  Cellular and molecular biology of voltage-gated sodium channels. , 1992, Physiological reviews.

[40]  W. Catterall,et al.  Inhibition of inactivation of single sodium channels by a site-directed antibody. , 1989, Proceedings of the National Academy of Sciences of the United States of America.

[41]  W. Catterall,et al.  Functional properties of rat brain sodium channels expressed in a somatic cell line. , 1990, Science.

[42]  T. Scheuer,et al.  A mutation in segment IVS6 disrupts fast inactivation of sodium channels. , 1994, Proceedings of the National Academy of Sciences of the United States of America.

[43]  A. Karlin,et al.  Electrostatic potential of the acetylcholine binding sites in the nicotinic receptor probed by reactions of binding-site cysteines with charged methanethiosulfonates. , 1994, Biochemistry.