Conformational analysis of d-tubocurarine: Implications for minimal dimensions of its binding site within ion channels

All the minimum-energy conformations of d-tubocurarine were calculated by the method of molecular mechanics. The energy was minimized from 413 closed forms of the 18-member ring. The set of minimum-energy conformations includes 10 forms with energies less than 6 kcal/mol from the most stable one. Among the four lowest minimum-energy conformations, two forms correspond to those known from X-ray studies, whereas two conformations were not detected experimentally earlier. The flexibility of d-tubocurarine was estimated by calculating six paths of interconversion between the four lowest minimum-energy conformations. Using a molecular graphics technique, it was found that the most extended minimum-energy conformation of d-tubocurarine may fit in an ion channel of a rectangular profile of 8.7 × 11.2 Å, while one tetrahydroisoquinoline head may fit a profile as small as 6.9 × 11.0 Å. A possible model of d-tubocurarine location within the ion channel of the neuronal nicotinic acetylcholine receptor is suggested.     

The resting membrane potential of Drosophila melanogaster larval muscle depends strongly on external calcium concentration

The resting membrane potential (RMP) of most cells is not greatly influenced by the transmembrane calcium gradient because at rest, the membrane has very low permeability to calcium. We have observed, however, that the resting membrane potential of muscle cells in the larval bodywall of Drosophila melanogaster varies widely as the external calcium concentration is modified. The RMP depolarized as much as 21.8 mV/mM calcium at low concentrations, and on average, about 10 mV/mM across a range typical of neurophysiological investigations. The extent to which muscle RMP varies has important implications for the measurement of synaptic potentials as well. Two parameters of excitatory junctional potential (EJP) voltage were compared across a range of RMPs. EJP amplitude (ΔV) and peak voltage (maxima) change as a function of RMP; on average, a 10 mV change in RMP elicits a 4-5 mV change in EJP amplitude and peak voltage. The influence of the calcium gradient on resting and synaptic membrane potentials led us to investigate the endogenous ion concentrations of larval hemolymph. In addition to the major monovalent ions and calcium, we report the first voltammetric analysis of magnesium concentration in larval fruit fly hemolymph.     

体外培养新生大鼠皮层神经细胞的形态及电学特性的演变

体外培养新生大鼠皮层神经细胞按形态特点分为三类:锥体形神经细胞、星形神经细胞和双极神经细胞.胞内微电极记录结果表明:随着培龄的增加,星形神经细胞的静息膜电位显著增加,从Ⅱ期(7-10DIV,DIV=Days In Vitro)开始膜输入阻抗显著下降.胞外微电极压力注射L-谷氨酸(10—25μmol/L),引起星形神经细胞去极化;随着培龄的增加,星形神经细胞对L-谷氨酸的反应率增大.     

NMDA and GABA B receptors are involved in controlling nematocyst discharge in hydra

The role of chemical neurotransmission in nematocyst discharge was investigated by stimulating the cnidocils of nematocysts in ablated tentacles of Hydra vulgaris with a piezoelectrically-driven glass probe, in the presence of selected neurotransmitters. Acetylcholine, dopamine, epinephrine, glycine, and serotonin (10^− 4, 10^− 6, 10^− 8 M) per se, did not alter stenotele and desmoneme discharge. γ-Amino-butyric acid (GABA) significantly increased desmoneme discharge when the cnidocil of another desmoneme in the same or adjacent battery cell complex was stimulated without affecting the discharge rates of the directly stimulated desmonemes or stenoteles. Baclofen (GABA_B agonist) mimicked the increase; its antagonist, phaclofen, counteracted it. GABA_A agonists and antagonists did not alter discharge rates. Glutamate caused a dose-dependent increase in the discharge rate of directly stimulated stenoteles; distant stenotele and desmoneme discharge rates were unaffected. Kainate, AMPA, and NMDA, per se, did not alter discharge rates. Co-administration of NMDA and kainate mimicked glutamate's effects. AMPA plus NMDA increased discharge rates. DAP-5 (NMDA antagonist) and CNQX, (kainate/AMPA antagonist) counteracted the increase. The findings suggest that metabotropic GABA is involved in recruiting desmonemes by disinhibiting those previously inhibited, and that the NMDA/kainate–AMPA mechanism regulating Ca⁺⁺ entry in higher neuroeffector systems is an early-evolved process, which, in hydra, modulates nematocyst discharge.     

GABA对小鼠大脑皮质中GABA受体胚胎发育的调节

本文用ＧＡＢＡ及其受体激动剂和拮抗剂处理培养的胚胎小鼠大脑皮层神经细胞以及精确计时的妊娠小鼠,用放射配体结合法检测ＧＡＢＡＡ及ＧＡＢＡＢ的结合位点数目,研究了ＧＡＢＡ对小鼠大脑皮层ＧＡＢＡ受体胚胎发育的调节作用,结果表明：①ＧＡＢＡ可使培养１５—１７天妊龄的胚胎小鼠大脑皮层神经细胞及出生第１天的仔鼠大脑皮层中的ＧＡＢＡＡ及ＧＡＢＡＢ受体数目增加,这种作用可被蝇蕈醇（Ｍｕｓ）及巴氯芬（Ｂａｃ）分别模拟,对ＧＡＢＡＡ受体的作用可为荷包牡丹碱（Ｂｉｃ）所阻断;②用ＧＡＢＡ处理妊娠７—１３天的小鼠,仔鼠出生第１天其大脑皮层的ＧＡＢＡＡ及ＧＡＢＡＢ受体数目均无变化;③用ＧＡＢＡ处理妊娠１４—１９天的小鼠,仔鼠出生的第１天其大脑皮层中的ＧＡＢＡＡ受体数目增加而ＧＡＢＡＢ受体数目不变;④用ＧＡＢＡ处理妊娠７－１９天的小鼠,仔鼠出生第１天其大脑皮层中ＧＡＢＡＡ及ＧＡＢＡＢ受体数目增加。这说明在胚胎发育的特定时期内,ＧＡＢＡ可诱导其受体数目的增加,这个作用是由ＧＡＢＡ受体调节的。     

The Paramecium circadian clock: synchrony of changes in motility, membrane potential, cyclic AMP and cyclic GMP

The behavior of a ciliate protozoan, Paramecium, is known to represent the electrical state of the cell membrane, and regulation of the membrane potential and ciliary motion are known to involve cAMP and cGMP. The present study shows the synchrony of circadian changes in motility, resting membrane potential and cyclic nucleotides in P. multimicronucleatum. Using an automated system for tracking isolated single microorganisms, the isolated Paramecium cells are confirmed to swim fast and straight during the day (and subjective day) and slowly, with frequent turning, at night (and subjective night). The resting membrane potential is more negative during the day than at night. cAMP and cGMP concentrations oscillate in a manner, such that both cAMP and cGMP are higher during the day (or subjective day) than at night (or subjective night). The ratio of cGMP to cAMP during the light and dark cycle (LD) fluctuates, paralleling the fluctuation of the resting membrane potential measured during the LD. These results suggest that the Paramecium will provide an excellent model to explore daily and circadian orchestration of second messengers mediating signals from ambient light/dark cycles and circadian pacemaker to ion channels and cilia, directly involved in daily and circadian cellular outputs of resting membrane potential and motility. Accepted: 23 January 1997     

The Minimum M3-M4 Loop Length of Neurotransmitter-activated Pentameric Receptors Is Critical for the Structural Integrity of Cytoplasmic Portals

The 5-HT₃A receptor homology model, based on the partial structure of the nicotinic acetylcholine receptor from Torpedo marmorata, reveals an asymmetric ion channel with five portals framed by adjacent helical amphipathic (HA) stretches within the 114-residue loop between the M3 and M4 membrane-spanning domains. The positive charge of Arg-436, located within the HA stretch, is a rate-limiting determinant of single channel conductance (γ). Further analysis reveals that positive charge and volume of residue 436 are determinants of 5-HT₃A receptor inward rectification, exposing an additional role for portals. A structurally unresolved stretch of 85 residues constitutes the bulk of the M3-M4 loop, leaving a >45-Å gap in the model between M3 and the HA stretch. There are no additional structural data for this loop, which is vestigial in bacterial pentameric ligand-gated ion channels and was largely removed for crystallization of the Caenorhabditis elegans glutamate-activated pentameric ligand-gated ion channels. We created 5-HT3A subunit loop truncation mutants, in which sequences framing the putative portals were retained, to determine the minimum number of residues required to maintain their functional integrity. Truncation to between 90 and 75 amino acids produced 5-HT₃A receptors with unaltered rectification. Truncation to 70 residues abolished rectification and increased γ. These findings reveal a critical M3-M4 loop length required for functions attributable to cytoplasmic portals. Examination of all 44 subunits of the human neurotransmitter-activated Cys-loop receptors reveals that, despite considerable variability in their sequences and lengths, all M3-M4 loops exceed 70 residues, suggesting a fundamental requirement for portal integrity.     

Ion physiology of vitellogenic follicles

The ion physiology of vitellogenic follicles from a lepidopteran (Hyalophora cecropia) and a hemipteran (Rhodnius prolixus) are compared. Similarities that can be expected to occur in vitellogenic follicles of many other insects include: (1) gap junctions, which unite the cells of a follicle into an integrated electrical system, (2) transmembrane K⁺ and H⁺ gradients that account for over 60% of follicular membrane potentials, (3) absence of a Cl⁻ potential, (but the opening of channels to this anion when vitellogenesis terminates in H. cecropia), (4) an electrogenic proton pump that supplements follicular membrane potentials, (5) Ca²⁺ action potentials evoked by injecting depolarizing currents into oocytes, and (6) the use of osmotic pressure to control epithelial patency. Differences include: a Na⁺/K⁺-ATPase that accounts for about 20% of the follicular resting potential in R. prolixus but is absent from H. cecropia, and an intrafollicular Ca²⁺ current that moves from oocyte to nurse cells through cytoplasmic bridges in H. cecropia. Evidence is also summarized for two promising mechanisms that require further substantiation: (1) transmission via gap junctions of a follicle cell product that promotes endocytosis in the oocyte; and (2) transport of the proton pump back and forth between cell surface and endosomes as the membrane that carries it recycles through successive rounds of vitellogenin uptake.     

Incompatibility between a pair of residues from the pre-M1 linker and Cys-loop blocks surface expression of the glycine receptor

Regulation of cell membrane excitability can be achieved either by modulating the functional properties of cell membrane-expressed single channels or by varying the number of expressed channels. Whereas the structural basis underlying single channel properties has been intensively studied, the structural basis contributing to surface expression is less well characterized. Here we demonstrate that homologous substitution of the pre-M1 linker from the β subunit prevents surface expression of the α1 glycine receptor chloride channel. By investigating a series of chimeras comprising α1 and β subunits, we hypothesized that this effect was due to incompatibility between a pair of positively charged residues, which lie in close proximity to each other in the tertiary structure, from the pre-M1 linker and Cys-loop. Abolishing either positive charge restored surface expression. We propose that incompatibility (electrostatic repulsion) between this pair of residues misfolds the glycine receptor, and in consequence, the protein is retained in the cytoplasm and prevented from surface expression by the quality control machinery. This hypothesis suggests a novel mechanism, i.e. residue incompatibility, for explaining the mutation-induced reduction in channel surface expression, often present in the cases of hereditary hyperekplexia.     

Introduction to Thematic Minireview Series on Celebrating the Discovery of the Cysteine Loop Ligand-gated Ion Channel Superfamily

The year 2012 marks the 25th anniversary of the discovery of the Cys loop ligand-gated ion channel superfamily of neurotransmitter receptors. This minireview series celebrates this with a series of articles reviewing current information for each of the family members, nicotinic acetylcholine receptors, glycine receptors, GABA_A receptors, serotonin-3 (5-HT₃) receptors, and glutamate-gated chloride ion channels of proteasome invertebrate phyla.     

Spatial electrical patterns in simulated neuronal dendrites

Steady state longitudinal distributions of (a) the density of channels conducting an inward transmembrane current of cations, (b) the submembrane concentrations of these cations, and (c) the resting membrane potential, were investigated in a phenomenological model of a cylinder-shaped dendritic process of the neuron. It was found that spatially non-uniform patterns of these distributions occur only if one of the following conditions held (i) an increase in the intracellular concentration of cations conducting an inward passive transmembrane current amplified the active efflux of those cations by the pump and attenuated their passive influx through the voltage dependent channels, with amplification of the efflux lower than attenuation of the influx; (ii) molecules of mobile channels bore a negative electrophoretic charge exposed to the intracellular space and were subject to lateral electrodiffusion in the membrane; (iii) the cations induced a further release of cations from intracellular stores. Numerical simulation studies of the membrane with Na and K channels and Na/K pumps with conditions (i) and (ii) have demonstrat-ed the possibility of the creation of inhomogeneous patterns in the neurites. These inhomogeneous patterns are dissipative structures (DSs), and they can be spatially periodic. Received: 23 October 1996 / Accepted: 21 May 1997     

Electrical properties of soybean plasma membrane measured in heterotrophic suspension callus

Previous work on heterotrophic suspension-cultured cells has failed to detect the electrogenic processes normally associated with the plasma membranes of non-animal cells. This study reports measurements on heterotrophic cells from soybean (Glycine max L.) suspension cultures, which are shown to be amenable to impalement with microelectrodes. The plasma membrane clearly exhibits fundamental characteristics which are common to many other plant cell types: (i) a resting membrane potential significantly more negative than-100mV (measured value:121±4mV); (ii) obvious electrogenic activity, as evidenced by the marked depolarization of the membrane (87±6mV) by cyanide, and by the fact the membrane potential was frequently more negative than the equilibrium potential for K⁺; (iii) a finite permeability to K⁺ ions; (iv) electrophoretic transport of glucose. The development of a recording medium consisting primarily of 1:5 diluted growth medium was critical for successful impalement of these cells. It is proposed that the novel identification of electrogenic processes in heterotrophic suspension-cultured cells results from the deployment of electrodes with relatively dilute filling solutions, thus avoiding substantial changes in intracellular ion concentrations.The overwhelming majority of cells in soybean suspension cultures exist in small clusters, and the possibility of intercellular coupling potentially precludes assessment of membrane specific resistance and current density. Furthermore, as with most higher-plant cells, the vacuole occupies a large fraction of the intracellular volume. However, a model in which the measuring electrode is cytosolically located and the cells are electrically well-coupled is the only one which satisfactorily generates values for membrane specific resistance in a manner which is not strongly dependent on the number of cells in the cluster: other models in which the electrode tip is located in the vacuole and-or the impaled cell is electrically isolated from the others do not seem to apply. The measured values of membrane specific resistance are in the range 5.4 to 8.4 ·m², which is in excellent agreement with comparable measurements on other plant and fungal cells. The results are discussed with respect to mechanisms of transmembrane signalling in soybean, as well as to general electrophysiological studies on higher-plant cells in suspension culture and in tissues.Abbreviations and symbols R_m membrane resistance - r_p plasma-membrane resistivity - SRB Soybean Recording Buffer - V_m membrane potential     

Unique after-hyperpolarization accompanying action potential inChara globularis

A unique after-hyperpolarization was found in internodal cells ofChara globularis. The cells generated an ordinary action potential due to regenerative depolarization induced by the outward electric current pulse larger than a threshold stimulus. After reaching a depolarizing peak, the membrane potential repolarized and overshooted the resting potential to a value which was somehow 40 mV more negative than the resting potential before stimulation (after-hyperpolarization). Since the membrane resistance increased during the after-hyperpolarization, the after-hyperpolarization is thought to be caused by an increase in the resistance (decrease in the conductance) of the passive diffusion channel.     

Electrogenic steps of the SR Ca-ATPase enzymatic cycle and the effect of curcumin

Sarcoplasmic reticulum (SR) vesicles were adsorbed on an octadecanethiol/phosphatidylcholine mixed bilayer anchored to a gold electrode, and the Ca-ATPase contained in the vesicles was activated by ATP concentration jumps in the presence of calcium ions. The resulting capacitive current transients are compared with those calculated on the basis of the enzymatic cycle of the calcium pump. This comparison provides information on the kinetics of the E₂-E₁ conformational change and on its pH dependence. The alteration in the current transients following ATP concentration jumps in the presence of curcumin is examined. In particular, curcumin decreases the rate of slippage of the Ca-ATPase, and at concentrations above 10 μM reduces calcium transport by this pump.