Induced Ion Channel Research Articles

Physostigmine and acetylcholine differentially activate nicotinic receptor subpopulations in Locusta migratoria neurons

The effects of acetylcholine (ACh) and physostigmine (PHY) on thoracic ganglion neurons of Locusta migratoria were investigated using whole-cell and cell-attached voltage clamp. ACh activated whole-cell currents with variable amplitudes, time course and ion channel block between cells, suggesting differential expression of nicotinic acetylcholine receptor (nAChR) subtypes. This was supported by selective block of the peak of the currents by the α7-specific α-conotoxin ImI. PHY at 100 μM evoked smaller whole-cell currents with variable amplitudes and marginal desensitization. The PHY/ACh amplitude ratio varied between cells, and was positively related to the time constant of decay of the ACh response. EC 50 values for the peak amplitude of the ACh- and PHY-induced currents were 50 μM and 3 μM, respectively. Both agonists activated nAChR, indicated by equal voltage-dependence and reversal potentials and the same pharmacological properties of ACh and PHY responses. In addition, PHY and ACh induced ion channel block. Co-application and cross-desensitization experiments showed that ACh and PHY activate the same nAChR subpopulations. Both agonists activated nicotinic single channels with three conductance levels, which were equal for ACh and PHY, indicating activation of the same nAChR subtypes by both agonists. However, for all levels PHY displayed a lower open probability than ACh. Taken together, different whole-cell responses appear to originate from differential activation, desensitization and ion channel block by ACh and PHY of distinct nAChR populations.

Characterization and ion channel activities of novel antibacterial proteins from the skin mucosa of carp (Cyprinus carpio).

A detergent-solubilized fraction of skin mucus of carp (Cyprinus carpio) induced ion channels after reconstitution into planar lipid bilayers. A differential extraction using a non-ionic detergent followed by electrophoretic separation led to the isolation of two hydrophobic 31-kDa and 27-kDa proteins. In contrast to the 27-kDa protein, which was glycosylated, the 31-kDa did not bind to concanavalin A. The reconstitution of these proteins into a planar lipid bilayer restored the ionophore behavior already observed with the crude mucus. The main unit conductance levels were about 900 pS for the 27-kDa protein and 500 pS for the 31-kDa protein, and selectivity measurements gave Pcl/Pk ratios of 0.6 and 1.0, respectively. These proteins had large potent microbicidal activities (0.018-0.18 microM) against different strains of gram-negative and gram-positive bacteria. This behavior can be compared with insect defensins that are known to form large ion channels in the bacterial membrane. To exclude the eventuality of bacterial origin, the bacterial flora of the crude mucus were analysed and the following were identified: Pseudomonas cepacia; Micrococcus luteus; Micrococcus roseus; Flavobacterium sp.; Aeromonas hydrophila. Antibacterial assays with both proteins were performed against these specific strains and revealed good growth inhibition activities. Furthermore, microsequencing analysis showed that the 31-kDa protein was protected on its N-terminal extremity in contrast to the 27-kDa protein, which had a 19-amino-acid sequence. This last sequence, when compared with sequences in protein data banks, did not reveal any significant similarities to other proteins. These results suggest that these novel proteins could be involved in antibacterial defense processes in fish.

Nuclear ion channel activity is regulated by actin filaments.

Actin filaments are novel second messengers involved in ion channel regulation. Because cytoskeletal components interact with the nuclear envelope, the actin cytoskeleton may also control nuclear membrane function. In this report, the patch-clamp technique was applied to isolated nuclei from amphibian A6 epithelial cells to assess the role of actin filaments on nuclear ion channel activity under nucleus-attached or -excised conditions. The most prevalent spontaneous nuclear ion channel species, 76% (n = 46), was cation selective and had a maximal single-channel conductance of approximately 420 pS. Nuclear ion channels also displayed multiple subconductance states, including channel activity of 26 pS that was frequently observed. Nuclear ion channel activity on otherwise quiescent patches was induced by either addition of the actin cytoskeleton disrupter cytochalasin D (CD; 5 micrograms/ml, 60%, 3 of 5 patches) or actin (10-1,000 micrograms/ml) to the bathing solution of nucleus-attached patches (59%, 13 of 22 patches). Actin also induced ion channel activity in quiescent excised inside-out patches from the nuclear envelope (80%, 4 of 5 patches). In contrast, addition of bovine serum albumin (10-1,000 micrograms/ml) to the bathing solution of nucleus-attached patches was without effect on nuclear ion channel activity (5 of 5 patches). The monoclonal antibody MAb414, specific for nuclear pore complex proteins, completely prevented either spontaneous or cytosolic actin-induced nuclear ion channels under nucleus-attached conditions (4 of 4 patches) but not intranuclear actin-induced nuclear ion channels under excised inside-out conditions (3 of 3 patches). In nucleus-attached patches, channel activity was readily activated by addition of the G-actin-binding protein deoxyribonuclease I to nucleus-attached patches (56%, 5 of 9 patches) or further addition of the actin-cross-linker filamin in the presence of actin (57%, 4 of 7 patches). The data indicate that dynamic changes in actin filament organization may represent a novel mechanism to control nuclear function.

β-Alanine induced ion channels in the membrane of cultured spinal cord neurons

β-Alanine (β-ALa) is a structural analog of the putative inhibitory transmitters γ-aminobutyric acid (GABA) and glycine. β-ALa itself depresses firing in cultured mouse spinal cord (SC) neurons, by selectively increasing membrane conductance to chloride ions. Patch clamp recordings now reveal that β-ALa-sensitive chloride channels in SC cells can open to at least 5 conductance states, 4 of which are very similar to states seen when GABA or glycine is applied to these cells. However, a large, 80 pS conductance state is activated at detectable frequency only in the presence of β-ALa itself.

Effects of a monoclonal anti-acetylcholine receptor antibody on the avian end-plate.

1. The effects of anti-acetylcholine receptor (AChR) monoclonal antibodies (mAbs) 370 and 132A on miniature end-plate potentials (MEPPs) and end-plate currents (EPCs) in the posterior latissimus dorsi muscle of adult chickens were investigated. 2. After incubation of the electrophysiological preparation with mAb 370 (5-50 micrograms/ml), which blocks both agonist (carbamylcholine) and alpha-bungarotoxin (alpha-BTX) binding and induces a hyperacute form of experimental autoimmune myasthenia gravis (EAMG), MEPP and EPC amplitudes were irreversibly reduced. 3. This effect was not associated with any significant change in the time constant describing EPC decay (tau EPC), current reversal potential, or the voltage dependence of tau EPC. The tau EPC at -80 mV was 5.9 +/- 0.6 ms before incubation with mAb 370 (50 micrograms/ml) and 6.0 +/- 0.9 ms afterwards. Current reversal potential was -3.9 +/- 0.4 mV before mAb incubation and -4.8 +/- 1.5 mV afterwards. The change in membrane potential required to produce an e-fold change in tau EPC was 128 +/- 2.3 mV before antibody incubation compared to 125 +/- 6.6 mV after incubation. 4. A second anti-AChR mAb, 132A (50 micrograms/ml), which is capable of inducing the classically described form of EAMG without blocking agonist or alpha-BTX binding, or inducing hyperacute EAMG, produced no significant change in MEPP amplitude, EPC amplitude, tau EPC or EPC reversal potentials. 5. The mAb 370 (50 micrograms/ml) induced a partially reversible decrease of the quantal content of the neurally evoked end-plate potential (EPP). This effect was not observed with mAb 132A, (+)tubocurarine (10(-7)-10(-5) g/ml) or an irrelevant anti-oestrogen receptor mAb. 6. These data suggest that the rapid onset of weakness observed in chicken hatchlings after the injection of mAb 370 (Gomez & Richman, 1983) can be attributed to a combined effect of a block of acetylcholine (ACh)-induced ion channel activity in the postsynaptic membrane and a reduction of the neurally evoked release of acetylcholine from the nerve terminal.

Mechanisms of acetylcholine receptor loss from the neuromuscular junction.

At the normal mammalian neuromuscular junction the half-life of the acetylcholine receptor (AChR) ranges from 6 to 13 days (estimates from seven different laboratories). Indirect evidence suggests that the internalized receptor is degraded by a lysosomal mechanism. We have now traced the fate of the AChR labelled in vivo with peroxidase-alpha-bungarotoxin. Segments of junctional folds bearing AChRs are internalized by endocytosis. The endocytosed vesicles are engulfed by tubules and larger vesicles which, by electron cytochemical criteria, represent secondary lysosomes. Pathological mechanisms increased AChR loss from the end-plate. These include destruction of junctional folds, formation of immature junctions with a few or no junctional folds, accelerated internalization of AChR, impaired membrane insertion of new AChR and, possibly decreased AChR synthesis. The common mechanism for destruction of the junctional folds is an altered subsynaptic ionic milieu, and especially focal calcium excess. This can be induced by antibody and complement, too frequent or prolonged openings of the acetylcholine (ACh)-induced ion channel, and other membrane defects. In acquired autoimmune myasthenia gravis there is (a) antibody-dependent complement-mediated lysis of the junctional folds, (b) accelerated internalization of AChR cross-linked by antibody and (c) decreased insertion of AChR into the postsynaptic membrane. The last mechanism is attributed to lack of membrane patches available for tight packing and secure anchoring of the receptor. In acute, but not in chronic, experimental autoimmune myasthenia gravis, and infrequently in human myasthenia gravis, macrophages destroy junctional folds opsonized by antibody and C3. In a recently recognized congenital syndrome attributed to a prolonged open time of the ACh-induced ion channel, and to a lesser extent in congenital end-plate acetylcholinesterase deficiency, AChR is lost with degradation of junctional folds. In other, less well-defined, congenital syndromes there is deficiency or abnormal function of AChR. This could arise from decreased synthesis or membrane insertion or accelerated degradation of AChR, or from a structurally abnormal AChR with reduced affinity for ACh or with a diminished conductance or open time of its ion channel.

Chemically Induced ION Channels in Nerve Cell Membranes

Publisher Summary This chapter discusses how application of fluctuation analysis, voltage-jump relaxation, and extracellular patch-clamp methods has increased knowledge of the action of agonists and other drugs at the membrane of nerve cells from both vertebrate and invertebrate preparations. Considerable technical problems exist in the application of the new biophysical methods to the study of transmitter actions on neurons in the intact vertebrate central nervous system (CNS). In the case of fluctuation analysis and voltage-jump relaxations, control of membrane voltage at higher frequencies may be difficult to achieve in nerve cells with complex geometries. A number of transmitter substances appear to utilize ion-permeable channels to induce a charge transfer across the postsynaptic membrane. It seems probable, then, that all three biophysical methods will be required to probe the action of putative transmitters on neurons in the intact vertebrate CNS. Within a few years, the elementary events induced by some transmitters in mammalian CNS neurons will become amenable to study without the need for cell dissociation and culture methods. This achievement will realize one of the long-standing goals of cellular neurobiology.