Voltage dependence of acetylcholine receptor channel gating in rat myoballs.

Whole-cell currents from nicotinic acetylcholine receptor (AChR) channels were studied in rat myoballs using a light-activated agonist to determine the voltage dependence of the macroscopic opening and closing rate constants. Myoballs were bathed in a solution containing a low concentration of the inactive isomer of the photoisomerizable azobenzene derivative, cis-Bis-Q. A light flash was then presented to produce a known concentration jump of agonist, trans-Bis-Q, across a wide range of membrane potentials in symmetrical solutions (NaCl or CsCl on both sides) or asymmetrical solutions (NaCl in the bath and CsCl in the pipette). At the low agonist concentration used in this study, the reciprocal of the macroscopic time constants gives an unambiguous measure of the effective closing rate. It showed an exponential decrease with membrane hyperpolarization between +20 and -100 mV, but tended to level off at more depolarized and at more hyperpolarized membrane potentials. The relative effective opening rate was derived from the steady-state conductance, the single-channel conductance, and the apparent closing rate; it decreased sharply in the depolarizing region and tended to level off and then turn up in the hyperpolarizing region. The two effective rate constants were shown to depend on the first, second, and third power of membrane potential.

Low molecular weight poly(A)+ mRNA species encode factors that modulate gating of a non-Shaker A-type K+ channel.

Voltage-dependent K+ channels control repolarization of action potentials and help establish firing patterns in nerve cells. To determine the nature and role of molecular components that modulate K+ channel function in vivo, we coinjected Xenopus oocytes with cRNA encoding a cloned subthreshold A-type K+ channel (mShal1, also referred to as mKv4.1) and a low molecular weight (LMW) fraction (2-4 kb) of poly(A)+ mRNA (both from rodent brain). Coinjected oocytes exhibited a significant (fourfold) increase in the surface expression of mShal1 K+ channels with no change in the open-channel conductance. Coexpression also modified the gating kinetics of mShal1 current in several respects. Macroscopic inactivation of whole oocyte currents was fitted with the sum of two exponential components. Both fast and slow time constants of inactivation were accelerated at all membrane potentials in coinjected oocytes (tau f = 47.2 ms vs 56.5 ms at 0 mV and tau s = 157 ms vs 225 ms at 0 mV), and the corresponding ratios of amplitude terms were shifted toward domination by the fast component (Af/As = 2.71 vs 1.17 at 0 mV). Macroscopic activation was characterized in terms of the time-to-peak current, and it was found to be more rapid at all membrane potentials in coinjected oocytes (9.9 ms vs 13.5 ms at 0 mV). Coexpression also leads to more rapid recovery from inactivation (approximately 2.4-fold faster at -100 mV). The coexpressed K+ currents in oocytes resemble currents expressed in mouse fibroblasts (NIH3T3) transfected only with mShal1 cDNA. These results indicate that mammalian regulatory subunits or enzymes encoded by LMW mRNA species, which are apparently missing or expressed at low levels in Xenopus oocytes, may modulate gating in some native subthreshold A-type K+ channels.

Steady-state gating of batrachotoxin-modified sodium channels. Variability and electrolyte-dependent modulation.

The steady-state gating of individual batrachotoxin-modified sodium channels in neutral phospholipid bilayers exhibits spontaneous, reversible changes in channel activation, such that the midpoint potential (Va) for the gating curves may change, by 30 mV or more, with or without a change in the apparent gating valence (za). Consequently, estimates for Va and, in particular, za from ensemble-averaged gating curves differ from the average values for Va and za from single-channel gating curves. In addition to these spontaneous variations, the average Va shifts systematically as a function of [NaCl] (being -109, -88, and -75 mV at 0.1, 0.5, and 1.0 M NaCl), with no systematic variation in the average za (approximately 3.7). The [NaCl]-dependent shifts in Va were interpreted in terms of screening of fixed charges near the channels' gating machinery. Estimates for the extracellular and intracellular apparent charge densities (sigma e = -0.7 and sigma i = -0.08 e/nm2) were obtained from experiments in symmetrical and asymmetrical NaCl solutions using the Gouy-Chapman theory. In 0.1 M NaCl the extracellular and intracellular surface potentials are estimated to be -94 and -17 mV, respectively. The intrinsic midpoint potential, corrected for the surface potentials, is thus about -30 mV, and the standard free energy of activation is approximately -12 kJ/mol. In symmetrical 0.1 M NaCl, addition of 0.005 M Ba2+ to the extracellular solution produced a 17-mV depolarizing shift in Va and a slight reduction in za. The shift is consistent with predictions using the Gouy-Chapman theory and the above estimate for sigma e. Subsequent addition of 0.005 M Ba2+ to the intracellular solution produced a approximately 5-mV hyperpolarizing shift in the ensemble-averaged gating curve and reduced za by approximately 1. This Ba(2+)-induced shift is threefold larger than predicted, which together with the reduction in za implies that Ba2+ may bind at the intracellular channel surface.

The kinetics of recovery and development of potassium channel inactivation in perfused squid (Loligo pealei) giant axons.

K+ currents were studied at a normal (-69 mV) and at a depolarized (-49 mV) membrane potential in voltage-clamped squid giant axons perfused with 350 mM-K+ and bathed in K+-free artificial sea water containing tetrodotoxin to block the Na+ channels. Steady-state and instantaneous K+ currents were reduced by over 50% at corresponding voltages at the depolarized membrane potential. Instantaneous chord conductance-voltage curves showed that the depolarized membrane potential caused a uniform reduction of K+ conductance across the voltage range under study. The driving force for K+ ions was comparable at both membrane potentials when a short (2 ms) pre-pulse was used to open the K+ channels. When a longer (7.5 ms) pre-pulse was used, the driving force was actually larger at the depolarized membrane potential. The depolarized membrane potential did drive some K+ ions into the periaxonal space. The amount of K+ ions driven into the periaxonal space was estimated by two independent methods, with similar results. The resulting increase of K+ ions in the periaxonal space (10 mM) was about 40 times too small to account for the large reduction in currents in terms of a reduced driving force for K+ ions. The kinetics of recovery and development of inactivation were monitored by repeatedly applying a 7.5 ms test pulse followed by a long conditioning potential. Both recovery and development of inactivation, from the depolarized membrane potential, were described by the sum of two exponential terms plus a constant. The time constant-voltage curves for both phases of inactivation peaked at about -54 mV at 10 degrees C. The time constant of the slow phase of inactivation at -54 mV was about 12.4 s, while the corresponding time constant for the fast phase was about 2.3 s. The slow relaxation had an apparent plateau of about 11 s at more depolarized membrane potentials. Recovery from inactivation was rapid at hyperpolarized membrane potentials. The steady-state inactivation curve of the K+ channel was incomplete in the depolarizing region; and apparent plateau was reached with about 75% of the K+ current inactivated. The temperature sensitivity of both phases of inactivation corresponded to a Q10 of about 3. Elevated external concentrations of K+ ions did not block either phase of the inactivation process, although the kinetics of recovery from inactivation were slightly faster under these conditions.(ABSTRACT TRUNCATED AT 400 WORDS)

Carbodiimide modification reduces the conductance and increases the tetrodotoxin sensitivity in batrachotoxin-modified sodium channels.

The relationship between the channel entrance and the tetrodotoxin (TTX) binding site was investigated by chemical modification at the extracellular surface of bilayer-incorporated batrachotoxin-(BTX) modified sodium channels using an impermeant carbodiimide in the presence or absence of exogenous nucleophiles. Two (classes of) groups could be modified such that the open-channel conductance was decreased while TTX binding was unaffected, and TTX did not protect against this modification. Because the final conductance level depends on the exogenous nucleophile, each covalent modification appears to involve a carboxyl group. In addition, a third (carboxyl) group could be modified such that TTX binding affinity was increased. These results suggest that the channel entrance and the TTX binding site are spatially separate, which supports previous suggestions that the mechanism by which guanidinium toxins close sodium channels involves a conformational change subsequent to toxin binding.

Activation of acetylcholine receptor channels by covalently bound agonists in cultured rat myoballs.

Kinetic and equilibrium aspects of receptor activation by two irreversibly bound ('tethered') agonists, QBr and bromoacetylcholine (BrACh), were examined in cultured embryonic rat muscle. Myoballs were treated with dithiothretitol (2 mM), washed, exposed to BrACh or QBr, and then washed again. Voltage-clamp recordings were made both in the whole-cell mode and with excised outside-out patches at 15 degrees C. Whole-cell voltage-jump relaxations resembled those observed with reversibly bound agonists. The relaxation time constants were 5 ms for tethered QBr and 10 ms for tethered BrACh (-100 mV, 15 degrees C). At more positive membrane potentials, the relaxation rate constants increased and the conductance decreased. Whole-cell light-flash relaxations with tethered QBr were also studied. The conductance was increased and decreased, respectively, by cis----trans and trans----cis photoisomerizations. The relaxation time constants equalled those for voltage jumps. The functional stoicheiometry of tethered QBr was investigated by studying the relaxations in response to light flashes that produced known changes in the mole fractions of the two isomers. It is concluded that the open state of each receptor channel is controlled by the isomeric state of a single tethered QBr molecule. In single-channel recordings, tethered agonists opened channels with the same conductance as reversibly bound agonists (30 pS at 15 degrees C and -100 mV). More than 80% of the conductance was contributed by a population of openings with an average burst duration (lifetime) of 5 ms for QBr and 10 ms for BrACh. Thus the single-channel and macroscopic currents seem to be dominated by the same type of channel; these are presumably monoliganded receptors. About 30% of the openings belonged to a population with an average lifetime of about 0.5 ms. This population contributed less than 5% of the conductance. There were also more long openings (greater than 50 ms) than expected from a simple exponential distribution. A few patches from BrACh-treated cells showed openings with a conductance of 45 pS (-100 mV) and an average duration of approximately 2 ms. These data allow one to assess whether the agonist-receptor binding step plays a role in generating the brief openings. The main population of openings (burst durations 5 ms with QBr and 10 ms with BrACh) seem to be contributed by monoliganded receptors. One can therefore rule out the hypothesis that the brief channels arise exclusively from mono- and biliganded receptors, respectively.

Photoactivation and dissociation of agonist molecules at the nicotinic acetylcholine receptor in voltage-clamped rat myoballs.

The photochemical properties of the azobenzene derivative, Bis-Q, were exploited to carry out an agonist concentration jump followed by a molecular rearrangement of bound agonist molecules at acetylcholine (ACh) receptor channels of voltage-clamped rat myoballs. Myoballs were bathed in solutions containing low concentrations of cis-Bis-Q, the inactive isomer. Whole-cell current relaxations were studied following a light flash that produced a concentration jump of agonist, trans-Bis-Q, followed by a second flash that produced net trans----cis photoisomerizations of Bis-Q molecules. The concentration-jump relaxation provided a measure of the mean burst duration for ACh receptor channels occupied by trans-Bis-Q (7.7 ms, 22 degrees C). The second current relaxation was a more rapid conductance decrease (phase 1, tau = 0.8 ms). Phase 1 may represent either the burst duration for receptors initially occupied by a single cis- and a single trans-Bis-Q molecule or that for unliganded receptors. Single-channel current recordings from excised outside-out membrane patches showed that single channels open following an agonist concentration jump comparable to that used in the whole-cell experiments; when many such records were averaged, a synthetic macroscopic relaxation was produced. Individual open channels closed faster following a flash that promoted trans----cis photoisomerizations of the bound ligand, thus confirming the whole-cell observations of phase 1.

Dose-response of acetylcholine receptor channels opened by a flash-activated agonist in voltage-clamped rat myoballs.

Whole-cell or single-channel currents through acetylcholine (ACh) receptor channels were studied in voltage-clamped rat myoballs or in excised membrane patches from myoballs. The recording pipette contained CsCl to suppress outward currents, and tetrodotoxin was used to help suppress Na+ currents. To minimize problems associated with bath applied agonists, myoballs were bathed in a solution containing the inactive (cis) isomer of the photo-isomerizable azobenzene derivative, Bis-Q. Calibrated light flashes of varying intensity were presented to produce concentration jumps of agonist, trans-Bis-Q. The resulting whole-cell current relaxations through ACh channels approach a steady state along an exponential time course, then decline as the newly created agonist diffuses away over the next few seconds. The dose-response relationship was inferred from Hill (double-log) plots for myoballs bathed in 500 nM-cis-Bis-Q at three membrane potentials. At low agonist concentrations (less than 300 nM-trans-Bis-Q), the slope of the Hill plot averaged 1.62 at -150 mV, 1.89 at -100 mV, and 2.05 at +80 mV. These results are consistent with an apparent agonist affinity constant that decreases with membrane depolarization and shifts the responses further down on the dose-response curve. When the myoballs were bathed in higher concentrations of cis-Bis-Q (1.5-20 microM), the slope of the Hill plot was reduced at all membrane potentials, although it was still closer to two at positive potentials. This is expected from the known sigmoid shape of the dose-response relation. The shallow dependence of the Hill slope on agonist concentration suggests the presence of negative cooperativity in the over-all binding of agonist molecules. Following treatment of the membrane with dithiothreitol to reduce disulphide groups, the Hill slope for the reversibly bound agonist, trans-Bis-Q, remained near two. The kinetics of currents at hyperpolarized membrane potentials became complicated at higher agonist concentrations in a manner that was consistent with open-channel block by trans-Bis-Q; the currents showed a slow secondary increase in conductance. Averaged single-channel recordings at higher agonist concentrations resemble macroscopic relaxations under comparable conditions. Furthermore, those recordings also suggested that open channels are blocked by trans-Bis-Q at concentrations greater than 2 microM; the block depends strongly on membrane potential and increases with hyperpolarization. Currents at positive membrane potentials showed no evidence of open-channel block.(ABSTRACT TRUNCATED AT 400 WORDS)

cis-3,3'-Bis-[alpha-(trimethylammonium)methyl]azobenzene (cis-Bis-Q). Purification and properties at acetylcholine receptors of Electrophorus electroplaques.

The cis and trans isomers of the photoisomerizable compound, 3,3'-bis-[alpha-(trimethylammonium)methyl]azobenzene (Bis-Q), were purified by high-performance liquid chromatography using the ion-pair partitioning technique on a reverse-phase column. Solutions of cis-Bis-Q are stable at -20 degrees; at 25 degrees, thermal isomerization proceeds at a rate of 0.65%/day. cis-Bis-Q is less than 1% as potent a nicotinic agonist as the trans configuration. At concentrations of 1.5 microM or less, cis-Bis-Q exerts little or no blockade of the conductances induced by agonists. In voltage-clamped Electrophorus electroplaques exposed to cis-Bis-Q, laser flashes induce cis leads to trans photoisomerizations and increase the agonist-induced current by a factor of 20 within a few milliseconds.

A microscope stage temperature controller for the study of whole-cell or single-channel currents.

The construction of a microscope stage temperature controller is described that works equally well with upright or inverted microscopes. The control circuit directly regulates the bath temperature near the physiological preparation from 0.0 degree C to 40.0 degrees C with a stability of +/- 0.1 degrees C; it allows biophysical studies of whole-cell or single channel currents to be carried out at different temperatures without introducing additional electrical noise into the measurements. The device may also be of interest to neurobiologists who work with tissue-culture preparations.

Capture, transport, and maintenance of live squid (Loligo pealei) for electrophysiological studies.

The capture, transport, and maintenance of live adult Atlantic coast squid (Loligo pealei) are described. The objective was to obtain healthy live squid from a coastal region and to maintain them at an inland research facility long enough to provide at least 4 days of electrophysiological research. An inexpensive closed aquarium system is described, which utilizes an ion-exchange resin in the filter, that allows a typical survival time of at least 4.5 days. Similar closed aquarium systems may be of interest to other biophysicists who wish to maintain live squid away from coastal research facilities.