Annalisa Bernareggi

Autocrine activation of nicotinic acetylcholine receptors contributes to Ca2+ spikes in mouse myotubes during myogenesis

It is widely accepted that nicotinic acetylcholine receptor (nAChR) channel activity controls myoblast fusion into myotubes during myogenesis. In this study we explored the possible role of nAChR channels after cell fusion in a murine cell model. Using videoimaging techniques we showed that embryonic muscle nAChR channel openings contribute to the spontaneous transients of intracellular concentration of Ca2+ ([Ca2+]i) and to twitches characteristic of developing myotubes before innervation. Moreover, we observed a choline acetyltransferase immunoreactivity in the myotubes and we detected an acetylcholine‐like compound in the extracellular solution. Therefore, we suggest that the autocrine activation of nAChR channels gives rise to [Ca2+]i spikes and contractions. Spontaneous openings of the nAChR channels may be an alternative, although less efficient, mechanism. We report also that blocking the nAChRs causes a significant reduction in cell survival, detectable as a decreased number of myotubes in culture. This led us to hypothesize a possible functional role for the autocrine activation of the nAChRs. By triggering mechanical activity, such activation could represent a strategy to ensure the trophism of myotubes in the absence of nerves.

Properties of glutamate receptors of Alzheimer's disease brain transplanted to frog oocytes

It is known that Alzheimers disease (AD) is a synaptic disease that involves various neurotransmitter systems, particularly those where synaptic transmission is mediated by acetylcholine or glutamate (Glu). Nevertheless, very little is known about the properties of neurotransmitter receptors of the AD human brain. We have shown previously that cell membranes, carrying neurotransmitter receptors from the human postmortem brain, can be transplanted to frog oocytes, and their receptors will still be functional. Taking advantage of this fact, we have now studied the properties of Glu receptors (GluRs) from the cerebral cortices of AD and non-AD brains and found that oocytes injected with AD membranes acquired GluRs that have essentially the same functional properties as those of oocytes injected with membranes from non-AD brains. However, the amplitudes of the currents elicited by Glu were always smaller in the oocytes injected with membranes from AD brains. Western blot analyses of the same membrane preparations used for the electrophysiological studies showed that AD membranes contained significantly fewer GluR2/3 subunit proteins. Furthermore, the corresponding mRNAs were also diminished in the AD brain. Therefore, the smaller amplitude of membrane currents elicited by Glu in oocytes injected with membranes from an AD brain is a consequence of a reduced number of GluRs in cell membranes transplanted from the AD brain. Thus, using the comparatively simple method of microtransplantation of receptors, it is now possible to determine the properties of neurotransmitter receptors of normal and diseased human brains. That knowledge may help to decipher the etiology of the diseases and also to develop new treatments.

Myocytes from congenital myotonic dystrophy display abnormal Na+ channel activities

Na+ currents were measured in myocytes from a fetus with congenital myotonic dystrophy type 1 (DM1) using the patch‐clamp whole‐cell technique. Steady‐state activation and inactivation properties of Na+ channels were not substantially different between these cells and age‐matched control cells. However, a decrease in Na+ channel density and a faster rate of recovery from inactivation were found in myocytes from congenital DM1 suggesting that changes in functional Na+ channels may affect cell excitability of muscle cells of patients with this disorder. Muscle Nerve, 2005

Novel role for prepatterned nicotinic acetylcholine receptors during myogenesis

Before the nerve contacts the skeletal muscle, the nicotinic acetylcholine receptors (nAChRs) form aggregates known as prepatterned clusters. We investigated their role in the occurrence of Ca2+ spikes and twitching during myogenesis.

Microtransplantation of acetylcholine receptors from normal or denervated rat skeletal muscles to frog oocytes

Non‐technical summary  Nicotinic acetylcholine receptors (nAChRs) expressed by skeletal muscle are the key proteins of the motoneuron–muscle communication necessary to induce muscle contraction. The biophysical and pharmacological characterization of the receptors in adult human skeletal muscle is limited by the difficulties associated with obtaining, and maintaining, suitable biopsy material. In this paper, we characterized some nAChR properties of innervated and denervated skeletal muscle by injecting the membranes into Xenopus oocytes. Such an approach, termed the microtransplantation technique, offers two main advantages: (1) direct characterization of the original receptors, still embedded in their natural lipid environment with their associated molecules; and (2) the possibility of using membranes isolated from postmortem frozen tissues. We demonstrate that this technique can be a very simple and useful approach to study skeletal muscle receptors and ion channels under different physiological and pathological conditions.

Xenopus laevis Oocytes as a Model System for Studying the Interaction Between Asbestos Fibres and Cell Membranes

The mode of interaction of asbestos fibres with cell membranes is still debatable. One reason is the lack of a suitable and convenient cellular model to investigate the causes of asbestos toxicity. We studied the interaction of asbestos fibres with Xenopus laevis oocytes, using electrophysiological and morphological methods. Oocytes are large single cells, with a limited ability to endocytose molecular ligands; we therefore considered these cells to be a good model for investigating the nature of asbestos/membrane interactions. Electrophysiological recordings were performed to compare the passive electrical membrane properties, and those induced by applying positive or negative voltage steps, in untreated oocytes and those exposed to asbestos fibre suspensions. Ultrastructural analysis visualized in detail, any morphological changes of the surface membrane caused by the fibre treatment. Our results demonstrate that Amosite and Crocidolite-type asbestos fibres significantly modify the properties of the membrane, starting soon after exposure. Cells were routinely depolarized, their input resistance decreased, and the slow outward currents evoked by step depolarizations were dramatically enhanced. Reducing the availability of surface iron contained in the structure of the fibres with cation chelators, abolished these effects. Ultrastructural analysis of the fibre-exposed oocytes showed no evidence of phagocytic events. Our results demonstrate that asbestos fibres modify the oocyte membrane, and we propose that these cells represent a viable model for studying the asbestos/cell membrane interaction. Our findings also open the possibly for finding specific competitors capable of hindering the asbestos-cell membrane interaction as a means of tackling the long-standing asbestos toxicity problem.

Adenosine enhances acetylcholine receptor channel openings and intracellular calcium 'spiking' in mouse skeletal myotubes.

The autocrine activity of the embryonic isoform of the nicotinic acetylcholine receptor is crucial for the correct differentiation and trophism of skeletal muscle cells before innervation. The functional activity of extracellular adenosine and adenosine receptor subtypes expressed in differentiating myotubes is still unknown. In this study, we performed a detailed analysis of the role of adenosine receptor‐mediated effects on the autocrine‐mediated nicotinic acetylcholine receptor channel openings and the associated spontaneous intracellular calcium ‘spikes’ generated in differentiating mouse myotubes in vitro.

Adenosine Promotes Endplate nAChR Channel Activity in Adult Mouse Skeletal Muscle Fibers via Low Affinity P1 Receptors.

Adenosine is a powerful modulator of skeletal neuromuscular transmission, operating via inhibitory or facilitatory purinergic-type P1 receptors. To date, studies have been focused mainly on the effect of adenosine on presynaptic P1 receptors controlling transmitter release. In this study, using two-microelectrode voltage-clamp and single-channel patch-clamp recording techniques, we have explored potential postsynaptic targets of adenosine and their modulatory effect on nicotinic acetylcholine receptor (nAChR)-mediated synaptic responses in adult mouse skeletal muscle fibers in vitro. In the whole-mount neuromuscular junction (NMJ) preparation, adenosine (100 μM) significantly reduced the frequency of the miniature endplate currents (MEPCs) and slowed their rising and decay time. Consistent with a postsynaptic site of action, adenosine and the potent P1 receptor agonist NECA significantly increased the open probability, the frequency and the open time of single nAChR channels, recorded at the endplate region. Using specific ligands for the P1 receptor subtypes, we found that the low-affinity P1 receptor subtype A2B was responsible for mediating the effects of adenosine on the nAChR channel openings. Our data suggest that at the adult mammalian NMJ, adenosine acts not only presynaptically to modulate acetylcholine transmitter release, but also at the postsynaptic level, to enhance the activity of nAChRs. Our findings open a new scenario in understanding of purinergic regulation of nAChR activity at the mammalian endplate region.