Utrophin suppresses low frequency oscillations and coupled gating of mechanosensitive ion channels in dystrophic skeletal muscle.

An absence of utrophin in muscle from mdx mice prolongs the open time of single mechanosensitive channels. On a time scale much longer than the duration of individual channel activations, genetic depletion of utrophin produces low frequency oscillations of channel open probability. Oscillatory channel opening occurred in the dystrophin/utrophin mutants, but was absent in wild-type and mdx fibers.

Utrophin regulates modal gating of mechanosensitive ion channels in dystrophic skeletal muscle.

Dystrophin is a large, submembrane cytoskeletal protein, absence of which causes Duchenne muscular dystrophy. Utrophin is a dystrophin homologue found in both muscle and brain whose physiological function is unknown. Recordings of single-channel activity were made from membrane patches on skeletal muscle from mdx, mdx/utrn(+/-) heterozygotes and mdx/utrn(-/-) double knockout mice to investigate the role of these cytoskeletal proteins in mechanosensitive (MS) channel gating.

Partial opening and subconductance gating of mechanosensitive ion channels in dystrophic skeletal muscle.

We recorded the activity of single mechanosensitive (MS) ion channels in skeletal muscle from the mdx mouse, a deletion mutant that lacks the cytoskeletal protein, dystrophin. Experiments were designed to examine the influence of dystrophin, a major component of skeletal muscle costameres, on the behaviour of single MS channels. In the majority of recordings from cell-attached patches, MS channels have a conductance of ∼23 pS.

Evidence TRPV4 contributes to mechanosensitive ion channels in mouse skeletal muscle fibers.

We recorded the activity of single mechanosensitive (MS) ion channels from membrane patches on single muscle fibers isolated from mice. We investigated the actions of various TRP (transient receptor potential) channel blockers on MS channel activity. 2-aminoethoxydiphenyl borate (2-APB) neither inhibited nor facilitated single channel activity at submillimolar concentrations.

Mechanosensitive ion channels in dystrophic muscle.

Mechanosensitive (MS) ion channels are expressed abundantly in skeletal muscle at all stages of development. In wild-type muscle, MS channels show primarily stretch-activated (SA) gating. In dystrophic myotubes from the mdx mouse, a loss-of-function mutant that lacks dystrophin, there are two types of MS channels.

Mechanosensitive ion channels in skeletal muscle: a link in the membrane pathology of muscular dystrophy.

1. Mechanosensitive (MS) channels are expressed abundantly in skeletal muscle at all stages of development. In recordings from membrane patches, MS channels are constitutively active at the resting potential.

Changes in mechanosensitive channel gating following mechanical stimulation in skeletal muscle myotubes from the mdx mouse.

We studied the effects of membrane stretch and voltage on the gating of single mechanosensitive (MS) channels in myotubes from dystrophin-deficient mdx mice. In earlier studies of MS channels in mdx myotubes, we found a novel class of stretch-inactivated channels. In the present experiments, we used a gentle suction protocol to determine whether seal formation damaged the membrane and altered MS channel gating, since dystrophin-deficiency is known to be associated with an increased susceptibility to mechanically induced damage.

Functional coupling between ryanodine receptors and L-type calcium channels in neurons.

In skeletal muscle, L-type Ca2+ channels act as voltage sensors to control ryanodine-sensitive Ca2+ channels in the sarcoplasmic reticulum. It has recently been demonstrated that these ryanodine receptors generate a retrograde signal that modifies L-type Ca2+ -channel activity. Here we demonstrate a tight functional coupling between ryanodine receptors and L-type Ca2+ channel in neurons.

Multiple components of Ca2+ channel facilitation in cerebellar granule cells: expression of facilitation during development in culture.

The contribution of pharmacologically distinct Ca2+ channels to prepulse-induced facilitation was studied in mouse cerebellar granule cells. Ca2+ channel facilitation was measured as the percentage increase in the whole-cell current recorded during a test pulse before and after it was paired with a positive prepulse. The amount of facilitation was small in recordings made during the first few days in tissue culture but increased substantially after 1 week.

Subconductance block of single mechanosensitive ion channels in skeletal muscle fibers by aminoglycoside antibiotics.

The activity of single mechanosensitive channels was recorded from cell-attached patches on acutely isolated skeletal muscle fibers from the mouse. The experiments were designed to investigate the mechanism of channel block produced by externally applied aminoglycoside antibiotics. Neomycin and other aminoglycosides reduced the amplitude of the single-channel current at negative membrane potentials.

Block of single L-type Ca2+ channels in skeletal muscle fibers by aminoglycoside antibiotics.

The activity of single L-type Ca2+ channels was recorded from cell-attached patches on acutely isolated skeletal muscle fibers from the mouse. The experiments were concerned with the mechanism by which aminoglycoside antibiotics inhibit ion flow through the channel. Aminoglycosides produced discrete fluctuations in the single-channel current when added to the external solution.

Reopening of single L-type Ca2+ channels in mouse cerebellar granule cells: dependence on voltage and ion concentration.

1. We recorded the activity of single L-type Ca2+ channels from cell-attached patches on mouse cerebellar granule cells. The experiments investigated the mechanism of channel reopening at negative membrane potentials following a strong depolarization.

Spontaneous opening of the acetylcholine receptor channel in developing muscle cells from normal and dystrophic mice.

Single-channel activity was recorded from cell-attached patches on skeletal muscle cells isolated from wild-type mice and from mice carrying the dy or mdx mutations. Spontaneous openings of the nicotinic acetylcholine receptor channel (nAChR) were detected in virtually all recordings from either dy/dy or dy/+ myotubes, but only infrequently from wild-type or mdx myotubes. Spontaneous openings were also present in most recordings from undifferentiated myoblasts from all of the mouse strains studied.

Modulation of calcium channels by metabotropic glutamate receptors in cerebellar granule cells.

We investigated the mechanisms by which metabotropic glutamate receptors (mGluRs) modulate specific Ca2+ channels in cerebellar granule cells. A large fraction of the current in granule cells is carried by L- and Q-type Ca2+ channels (about 26% each), whereas N- and P-type contribute proportionally less to the global current (9 and 15%, respectively). l-Aminocyclopentane-dicarboxylate (t-ACPD), (2S,3S,4S)-alpha-(carboxycyclopropyl)-glycine (L-CCGI) and (S)-4-carboxy-3-hydroxyphenylglycine [(S)-4C3HPG], but not L(+)-2-amino-4-phosphonobutyrate (L-AP4) reduced the Ca2+ current amplitude.

The role of Mg2+ in the inactivation of inwardly rectifying K+ channels in aortic endothelial cells.

We have studied the role of Mg2+ in the inactivation of inwardly rectifying K+ channels in vascular endothelial cells. Inactivation was largely eliminated in Mg(2+)-free external solutions and the extent of inactivation was increased by raising Mg2+o. The dose-response relation for the reduction of channel open probability showed that Mg2+o binds to a site (KD = approximately 25 microM at -160 mV) that senses approximately 38% of the potential drop from the external membrane surface.

Mechanosensitive ion channels in skeletal muscle from normal and dystrophic mice.

1. We examined the activity of single mechanosensitive ion channels in recordings from cell-attached patches on myoblasts, differentiated myotubes and acutely isolated skeletal muscle fibres from wild-type and mdx and dy mutant mice. The experiments were concerned with the role of these channels in the pathophysiology of muscular dystrophy.

Dihydropyridine- and omega-conotoxin-sensitive Ca2+ currents in cerebellar neurons: persistent block of L-type channels by a pertussis toxin-sensitive G-protein.

The inhibition of high-threshold Ca2+ channel currents by activated G-proteins was studied in mouse cerebellar granule cells making use of the hydrolysis-resistant GTP analog GTP-gamma-S. When individual granule cells were internally dialyzed with GTP-gamma-S, the high-threshold Ca2+ current decreased to approximately 20% of its initial value within approximately 2 min. The GTP-gamma-S-resistant current was reduced further by the subsequent addition of either omega-conotoxin or dihydropyridine antagonist, indicating that both N- and L-type Ca2+ channels carried the remaining current.

Reopening of Ca2+ channels in mouse cerebellar neurons at resting membrane potentials during recovery from inactivation.

Recordings of single-channel activity from cerebellar granule cells show that a component of Ca2+ entry flows through L-type Ca2+ channels that are closed at negative membrane potentials following a strong depolarization, but then open after a delay. The delayed openings can be explained if membrane depolarization drives Ca2+ channels into an inactivated state and some channels return to rest through the open state after repolarization. Whole-cell recordings show that the charge carried by Ca2+ during the tail increases as inactivation progresses, whereas the current during the voltage step decreases.

Developmental regulation of mechanosensitive calcium channels in skeletal muscle from normal and mdx mice.

Single-channel activity was recorded from cell-attached membrane patches on flexor digitorum brevis fibres acutely isolated from normal and mdx mice at different stages of postnatal development. Recordings from cell-attached patches on both normal and mdx fibres were dominated by the activity of mechanosensitive ion channels with a conductance of approximately 17 pS with 110 mM Ba2+ in the patch electrode. In a small fraction of the patches on mdx fibres from young mice, channels showed very high levels of activity.

Inactivating and non-inactivating dihydropyridine-sensitive Ca2+ channels in mouse cerebellar granule cells.

1. Granule cells were dissociated from mouse cerebellum and grown in vitro. Currents through single Ca2+ channels were recorded from the cell body with the patch clamp technique.

Calcium-permeable ion channels in cerebellar neurons from mdx mice.

Recordings of single-channel activity were made from cell-attached patches on cerebellar granule cells from normal and mdx mice. Recordings from mdx granule cells show the activity of ion channels that are open for seconds at negative holding potentials near rest. These channels are permeable to divalent cations and have a conductance of 8-10 pS with either Ca2+ or Ba2+ as the charge carrier in the patch electrode.

Open channel block by gadolinium ion of the stretch-inactivated ion channel in mdx myotubes.

Currents flowing through single stretch-inactivated ion channels were recorded from cell-attached patches on myotubes from mdx mice. Adding micromolar concentrations of gadolinium to patch electrodes containing normal saline produced rapid transitions in the single-channel current between the fully open and closed states. The kinetics of the current fluctuations followed the predictions of a simple model of open channel block in which the transitions in the current arise from the entry and exit of Gd from the channel pore: histograms of the open and closed times were well fit with single exponentials, the blocking rate depended linearly on the concentration of gadolinium in the patch electrode, and the unblocking rate was independent of the concentration of gadolinium.

Inactivation of calcium currents in granule cells cultured from mouse cerebellum.

1. Cells dissociated from mouse cerebellum were grown in vitro. Ca2+ channel currents were recorded from granule cells with the patch-clamp technique under conditions which suppressed currents through Na+ and K+ channels and minimized run-down of current through Ca2+ channels.