Bernhard E. Flucher

Distribution of Na+ channels and ankyrin in neuromuscular junctions is complementary to that of acetylcholine receptors and the 43 kd protein

We have used immunogold electron microscopy to study the organization of the acetylcholine receptor, 43 kd protein, voltage-sensitive Na+ channel, and ankyrin in the postsynaptic membrane of the rat neuromuscular junction. The acetylcholine receptor and the 43 kd protein are concentrated at the crests of the postsynaptic folds, coextensive with the subsynaptic density. In contrast, Na+ channels and ankyrin are concentrated in the membranes of the troughs and in perijunctional membranes, both characterized by discontinuous submembrane electron-dense plaques. This configuration of interspersed postsynaptic membrane domains enriched in either Na+ channels or acetylcholine receptors may facilitate the initiation of the muscle action potential. Furthermore, the results support the involvement of ankyrin in immobilizing Na+ channels in specific membrane domains, analogous to the proposed involvement of the 43 kd protein in acetylcholine receptor immobilization.

Structural analysis of muscle development: Transverse tubules, sarcoplasmic reticulum, and the triad

Increased interest in the mechanism of excitation-contraction (E-C) coupling over the last few years has been accompanied by numerous investigations into the development of the underlying cellular structures. Areas of particular interest include: (1) the compartmentalization and specialization of an external and an internal membrane system, the T-tubules, and the sarcoplasmic reticulum, respectively; (2) interactions between the membrane proteins of both systems upon the formation of a junction, the triad; and (3) membrane-cytoskeletal interactions leading to the orderly arrangement of the triads with respect to the myofibrils. Structural studies using newly available specific molecular probes and a variety of in vivo and in vitro model systems have provided new insights into the cellular and molecular mechanisms involved in the development of the E-C coupling apparatus in skeletal muscle.

Current modulation and membrane targeting of the calcium channel α1C subunit are independent functions of the β subunit

1 The β subunits of voltage‐sensitive calcium channels facilitate the incorporation of channels into the plasma membrane and modulate calcium currents. In order to determine whether these two effects of the β subunit are interdependent or independent of each other we studied plasma membrane incorporation of the channel subunits with green fluorescent protein and immunofluorescence labelling, and current modulation with whole‐cell and single‐channel patch‐clamp recordings in transiently transfected human embryonic kidney tsA201 cells. 2 Coexpression of rabbit cardiac muscle α1C with rabbit skeletal muscle β1a, rabbit heart/brain β2a or rat brain β3 subunits resulted in the colocalization of α1C with β and in a marked translocation of the channel complexes into the plasma membrane. In parallel, the whole‐cell current density and single‐channel open probability were increased. Furthermore, the β2a isoform specifically altered the voltage dependence of current activation and the inactivation kinetics. 3 A single amino acid substitution in the β subunit interaction domain of α1C (α1CY467S) disrupted the colocalization and plasma membrane targeting of both subunits without affecting the β subunit‐induced modulation of whole‐cell currents and single‐channel properties. 4 These results show that the modulation of calcium currents by β subunits can be explained by β subunit‐induced changes of single‐channel properties, but the formation of stable α1C‐β complexes and their increased incorporation into the plasma membrane appear not to be necessary for functional modulation.

Localization of the α1 and α2 subunits of the dihydropyridine receptor and ankyrin in skeletal muscle triads

Abstract We have studied the subcellular distribution of the α 1 and α 2 subunits of the dihydropyridine (DHP) receptor and ankyrin in rat skeletal muscle with immunofluorescence and immunogold labeling techniques. All three proteins were concentrated in the triad junction formed between the T-tubules and sarcoplasmic reticulum. The α 1 and α 2 subunits of the DHP receptor were colocalized in the junctional T-tubule membrane, supporting their proposed association in a functional complex and the possible participation of the α 2 subunit in excitation-contraction coupling. Ankyrin label in the triad showed a distribution different from that of the DHP receptor subunits. In addition, ankyrin was found in longitudinally oriented structures outside the triad. Thus, ankyrin might be involved in organizing the triad and in immobilizing integral membrane proteins in T-tubules and the sarcoplasmic reticulum.

Excitation–contraction coupling is unaffected by drastic alteration of the sequence surrounding residues L720–L764 of the α1S II-III loop

The II-III loop of the skeletal muscle dihydropyridine receptor (DHPR) α1S subunit is responsible for bidirectional-signaling interactions with the ryanodine receptor (RyR1): transmitting an orthograde, excitation–contraction (EC) coupling signal to RyR1 and receiving a retrograde, current-enhancing signal from RyR1. Previously, several reports argued for the importance of two distinct regions of the skeletal II-III loop (residues R681–L690 and residues L720–Q765, respectively), claiming for each a key function in DHPR–RyR1 communication. To address whether residues 720–765 of the II-III loop are sufficient to enable skeletal-type (Ca2+ entry-independent) EC coupling and retrograde interaction with RyR1, we constructed a green fluorescent protein (GFP)-tagged chimera (GFP-SkLM) having rabbit skeletal (Sk) DHPR sequence except for a II-III loop (L) from the DHPR of the house fly, Musca domestica (M). The Musca II-III loop (75% dissimilarity to α1S) has no similarity to α1S in the regions R681–L690 and L720–Q765. GFP-SkLM expressed in dysgenic myotubes (which lack endogenous α1S subunits) was unable to restore EC coupling and displayed strongly reduced Ca2+ current densities despite normal surface expression levels and correct triad targeting (colocalization with RyR1). Introducing rabbit α1S residues L720–L764 into the Musca II-III loop of GFP-SkLM (substitution for Musca DHPR residues E724–T755) completely restored bidirectional coupling, indicating its dependence on α1S loop residues 720–764 but its independence from other regions of the loop. Thus, 45 α1S-residues embedded in a very dissimilar background are sufficient to restore bidirectional coupling, indicating that these residues may be a site of a protein–protein interaction required for bidirectional coupling.

Voltage-activated calcium channel expression profiles in mouse brain and cultured hippocampal neurons.

The importance and diversity of calcium signaling in the brain is mirrored by the expression of a multitude of voltage-activated calcium channel (Ca(V)) isoforms. Whereas the overall distributions of alpha(1) subunits are well established, the expression patterns of distinct channel isoforms in specific brain regions and neurons, as well as those of the auxiliary beta and alpha(2)delta subunits are still incompletely characterized. Further it is unknown whether neuronal differentiation and activity induce changes of Ca(V) subunit composition. Here we combined absolute and relative quantitative TaqMan reverse transcription PCR (RT-PCR) to analyze mRNA expression of all high voltage-activated Ca(V) alpha(1) subunits and all beta and alpha(2)delta subunits. This allowed for the first time the direct comparison of complete Ca(V) expression profiles of mouse cortex, hippocampus, cerebellum, and cultured hippocampal neurons. All brain regions expressed characteristic profiles of the full set of isoforms, except Ca(V)1.1 and Ca(V)1.4. In cortex development was accompanied by a general down regulation of alpha(1) and alpha(2)delta subunits and a shift from beta(1)/beta(3) to beta(2)/beta(4). The most abundant Ca(V) isoforms in cerebellum were Ca(V)2.1, beta(4), and alpha(2)delta-2, and in hippocampus Ca(V)2.3, beta(2), and alpha(2)delta-1. Interestingly, cultured hippocampal neurons also expressed the same Ca(V) complement as adult hippocampus. During differentiation specific Ca(V) isoforms experienced up- or down-regulation; however blocking electrical activity did not affect Ca(V) expression patterns. Correlation analysis of alpha(1), beta and alpha(2)delta subunit expression throughout all examined preparations revealed a strong preference of Ca(V)2.1 for beta(4) and alpha(2)delta-2 and vice versa, whereas the other alpha(1) isoforms were non-selectively expressed together with each of the other beta and alpha(2)delta isoforms. Together our results revealed a remarkably stable overall Ca(2+) channel complement as well as tissue specific differences in expression levels. Developmental changes are likely determined by an intrinsic program and not regulated by changes in neuronal activity.

The small conductance Ca2+-activated K+ channel SK3 is localized in nerve terminals of excitatory synapses of cultured mouse hippocampal neurons.

In the central nervous system small conductance Ca2+‐activated K+ (SK) channels are important for generating the medium/slow afterhyperpolarization seen after single or trains of action potentials. Three SK channel isoforms (SK1,‐2,‐3) are differentially distributed throughout the brain, but little is known about their specific expression in particular neuronal compartments. In the hippocampus SK3 was found in the neuropil, predominantly in the terminal field of the mossy fibres and in fine varicose fibres, but excluded from the pyramidal and granule cell layers. Because this expression pattern suggested a presynaptic localization, we examined the subcellular distribution of SK3 in cultured hippocampal neurons using high‐resolution immunofluorescence analysis. SK3 was localized in a punctate, synaptic pattern. The SK3 clusters were precisely colocalized with the presynaptic marker synapsin and at close range (0.4–0.5 µm) from NMDA‐receptors and PSD‐95. This arrangement is consistent with a localization of SK3 in the presynaptic nerve terminal, but not restricted to the synaptic membrane proper. In agreement with the increasing expression of SK3 during early postnatal development in vivo, the fraction of synapses containing SK3 increased from 14% to 57% over a six‐week culture period. SK3‐containing synapses were equally observed on spiny, glutamatergic and smooth GABAergic neurons. In contrast to its close association with NMDA‐receptors and PSD‐95, SK3 was rarely associated with GABAA‐receptor clusters. Thus, SK3 is a presynaptic channel in excitatory hippocampal synapses, with no preference for glutamatergic or GABAergic postsynaptic neurons, and is probably involved in regulating neurotransmitter release.

Biogenesis of transverse tubules in skeletal muscle in vitro

The transverse (T) tubules of skeletal muscle are membrane tubules that are continuous with the plasma membrane and penetrate the mature muscle fiber radially to carry surface membrane depolarization to the sites of excitation-contraction coupling. We have studied the development of the T-tubule system in cultured amphibian and mammalian muscle cells using a fluorescent lipid probe and antibodies against T-tubules and plasma membranes. Both the lipid probe and the T-tubule antibody recognized an extensive tubular membrane system which subsequently differentiated into the T-system. At all developmental stages, the molecular composition of the T-system was distinct from that of the plasma membrane, suggesting that during myogenesis T-tubules and the plasma membrane form independently from each other and that exchange of membrane proteins between the two continuous compartments is restricted. In rat muscle cultures, T-tubule-specific antigens were first expressed in terminally differentiated myoblasts. Prior to myoblast fusion the antigens appeared as punctate label throughout the cytoplasm. Shortly after fusion the T-tubule-specific antibody labeled a tubular membrane system that extended from the perinuclear region and penetrated most parts of the cells. In contrast, the lipid probe, which labels the T-tubules by virtue of their direct continuity with the plasma membrane, only labeled short tubules extending from the plasma membrane into the periphery of the myotubes at the early stage in development. Thus, the assembly of the T-tubules appears to begin before their connections with the plasma membrane are established.

Coordinated development of myofibrils, sarcoplasmic reticulum and transverse tubules in normal and dysgenic mouse skeletal muscle, in vivo and in vitro.

We studied the development of transverse (T)-tubules and sarcoplasmic reticulum (SR) in relationship to myofibrillogenesis in normal and dysgenic (mdg/mdg) mouse skeletal muscle by immunofluorescent labeling of specific membrane and myofibrillar proteins. At E16 the development of the myofibrils and membranes in dysgenic and normal diaphragm was indistinguishable, including well developed myofibrils, a delicate network of T-tubules, and a prominent SR which was not yet cross-striated. In diaphragms of E18 dysgenic mice, both the number and size of muscle fibers and myofibrillar organization were deficient in comparison to normal diaphragms, as previously reported. T-tubule labeling was abnormal, showing only scattered tubules and fragments. However, many muscle fibers displayed cross striation of sarcomeric proteins and SR comparable to normal muscle. In cultured myotubes, cross-striated organization of sarcomeric proteins proceeded essentially in two stages: first around the Z-line and later in the A-band. Sarcomeric organization of the SR coincided with the first stage, while the appearance of T-tubules in the mature transverse orientation occurred infrequently, only after A-band maturation. In culture, myofibrillar and membrane organization was equivalent in normal and dysgenic muscle at the earlier stage of development, but half as many dysgenic myotubes reached the later stage as compared to normal. We conclude that the mdg mutation has little effect on the initial stage of membrane and myofibril development and that the deficiencies often seen at later stages result indirectly from the previously described absence of dihydropyridine receptor function in the mutant.

Depolarization-Transcription Signals in Skeletal Muscle Use Calcium Flux through L Channels, but Bypass the Sarcoplasmic Reticulum

Membrane depolarization inactivates acetylcholine receptor (AChR) genes in skeletal muscle. We have studied this process in C2C12 cells, focusing on the role of calcium. Cytoplasmic calcium was monitored with flue-3, and the activity of receptor genes was measured with a sensitive transcript elongation assay. Removal of extracellular calcium or blockage of L-type calcium channels disrupts signaling, even when release of calcium from the sarcoplasmic reticulum (SR) is not impeded, whereas L channel agonists induce signaling without membrane depolarization or release of calcium from intracellular stores. Activators of calcium release from the SR do not inhibit AChR genes, either in C2C12 or in chicken skeletal muscle in vivo. It appears that calcium ions do not act as messengers between sarcolemma and nucleus but target a sensor near their port of entry where they initiate a signal that bypasses the SR.