Long-term follow-up of patients with congenital myasthenic syndrome caused by COLQ mutations.

Congenital myasthenic syndromes (CMS) are clinically and genetically heterogeneous inherited disorders characterized by impaired neuromuscular transmission. Mutations in the acetylcholinesterase (AChE) collagen-like tail subunit gene (COlQ) cause recessive forms of synaptic CMS with end plate AChE deficiency. We present data on 15 COLQ -mutant CMS carrying 16 different mutations (9 novel ones identified) followed-up for an average period of 10 ears. The mean age at the first examination was 19 ears old (range from 3 to 48). We report relapses during short or long-term periods characterized by worsening of muscle weakness sometimes associated with respiratory crises. All the relapses ended spontaneously or with 3-4 DAP or ephedrine with no residual impairment. The triggering factors identified were esterase inhibitors, effort, puberty or pregnancy highlighting the importance of hormonal factors. There was no genotype-phenotype correlation. At the end of the follow-up, 80% of patients were ambulant and 87% of patients had no respiratory trouble in spite of severe relapses.

Phenotype genotype analysis in 15 patients presenting a congenital myasthenic syndrome due to mutations in DOK7.

Congenital myasthenic syndromes (CMSs) are a heterogeneous group of diseases caused by genetic defects affecting neuromuscular transmission. Mutations of DOK7 have recently been described in recessive forms of CMS. Dok-7 is a cytoplasmic post-synaptic protein co-activator of the muscle-specific receptor-tyrosine kinase (MuSK) involved in neuromuscular synaptogenesis and maintenance. We report clinical, morphological and molecular data on 15 patients with mutations in DOK7. Eleven different mutations (5 novel) were identified and all patients but one were found to carry at least the common c.1124_1127dupTGCC mutation. Patients with DOK7 mutations have a particular limb-girdle pattern, without tubular aggregates but a frequent lipidosis on the muscle biopsy. Changes in pre- and post-synaptic compartments of the neuromuscular junction were also observed in muscle biopsies: terminal axons showed defective branching which resulted in a unique terminal axon contacting en passant postsynaptic cups. Clinical features, muscle biopsy findings or response to therapy were confusing in several patients. Characterization of this distinct phenotype is essential to provide clues for targeted genetic screening and to predict the therapeutic response to anticholinesterase treatments or ephedrine as has been suggested.

[Experimental and pathological changes of the neuromuscular junction]. / Remaniements expérimentaux et pathologiques de la jonction neuromusculaire.

The objective of our study was to investigate the cellular communication between the axon and its postsynaptic targets in the synapse. We used the neuromuscular junction (NMJ) model, which is a highly specialized structure between the nerve, the muscle, and the Schwann cell terminal where the motor neuron orders the muscle to contract. We used experimental models of motor nerve reimplantation in a denervated muscle to determine whether 1) the formation of new NMJ could participate in reinnervation of the muscle necessary to contraction or 2) the blockage of neurotransmitter release using botulinum toxin could be compensated by the formation of new NMJ. We also studied human genetic diseases that affect neuromuscular transmission--congenital myasthenic syndromes--to identify the mutations in the genes coding for synaptic molecules and to analyze the compensatory processes involved in NMJ dysfunction so that muscle contraction can occur in these conditions.

[Pathophysiological, molecular and metabolic changes at the neuromuscular junction and the peripheral nerve after central nervous system lesions in humans]. / Caractérisation physiopathologique, moléculaire et métabolique de la jonction neuromusculaire et du nerf périphérique après lésion du système nerveux central chez l'homme.

From the elaborate information processing that takes place in the brain to the contraction of skeletal muscles, the neurotransmission pathways involve, at least in part, (1) in tissue, Na+, K+-ATPase electrogenesis making action potential (AP) propagation possible and (2) in the cell, the synthesis, maturation, and renewal of an amazing number of molecules concentrated at the neuromuscular junction (NMJ). Our aim is to clarify CNS and peripheral nerve system (PNS) interactions by determining whether the partial motor recovery sometimes observed after a lesion of the first motoneuron is related to (1) changes in active transportation of the ions in peripheral nerve and/or muscle and (2) morphological and/or molecular changes at the NMJ, illustrating a dysfunction. Peripheral nerve surgery is proposed to some spastic patients who have recovered partially after CNS lesions to improve their gait. During these surgical procedures, the nerve and muscle samples that are usually resected can be collected and analyzed. Here, we report on eight patients who showed strictly similar motor recovery 2 years after massive CNS lesions and who underwent a selective tibial neurotomy for a spastic equinus foot. In these eight spastic patients, we performed a pathophysiological, molecular, and metabolic study of their neuromuscular junctions and peripheral nerves to characterize the dysfunction of the neuromuscular transmission after a permanent CNS injury.

[Tools and techniques dedicated to neuromuscular junction observation]. / Modalités et outils d'observation de la jonction neuromusculaire.

A few decades ago, the neuromuscular junction (NMJ) concept was reduced to two elements: the nerve ending and the facing muscular zone. This description has since changed substantially based on recent studies conducted on the molecular aspects of neurotransmission. The aim of this paper is to provide a synthetic view of the major morphological, molecular and electrophysiological tools used in the analysis of NMJ architecture and its functional characterization.

[The anatomical substrate of muscle contractility]. / Le support anatomique de la contraction musculaire.

Muscle fiber action participates in a true contractile machinery associated with noncontractile components providing mechanical stability. The myofibril, the muscle fiber subentity, has an extremely consistent architecture, composed of longitudinal cylindrical units called sarcomeres, the skeletal muscle length functional unit, a highly important place in the transduction of chemical signal into mechanical contractile energy, for the most part mediated by calcium. The sarcoplasmic reticulum is the other major component of muscle fiber and is dedicated to calcium storage, liberation and distribution to the fiber, under the influence of action potential propagation. This phenomenon is called excitation-contraction coupling. This paper explores muscle anatomy from its main embryologic stages of development to its histochemical specificity, including its molecular constitution, and details the main morphofunctional relations supporting muscle contraction.

[Synapse formation and regeneration]. / Formation et régénération synaptique.

Synapse formation is probably the key process in neural development allowing signal transmission between nerve cells. As an interesting model of synapse maturation, we considered first the neuromuscular junction (NMJ), whose development is particularly dependent on intercellular interactions between the motor nerve and the skeletal muscle. Nerve and muscle have distinct roles in synaptic compartment differentiation. The initial steps of this differentiation and motor endplate formation require several postsynaptic molecular agents including agrin, the tyrosine kinase receptor MuSK and rapsyn. The agrin or motoneuron dependence of this process continues to be debated while the following steps of axonal growth and postsynaptic apparatus maintenance essentially depend on neuronal agrin and a neuron-specific signal dispersing ectopic AChR aggregate remainders, possibly mediated by acetylcholine itself. Neuregulin is essentially involved in Schwann's cell survival and guidance for axonal growth. In this paper, we will discuss the similarities between Central Nervous System (CNS) synaptic formation and Motor innervation. The limited ability of the CNS to create new synapses after nervous system injury will be then discussed with a final consideration of some new strategies elaborated to circumvent the limitations of lesion extension processes.

[Major mechanisms involved in the synaptic transmission of the neuromuscular apparatus]. / Principaux mécanismes impliqués dans la transmission synaptique au sein de l'appareil neuromusculaire.

Neuromuscular transmission results from a double signal transduction from electric impulses to chemical messengers, taking place at a highly differentiated region, the neuromuscular junction (NMJ). A nerve cell responds to a specific stimulus by modifications of its plasmic membrane properties, generating an action potential (AP). This electric signal is transmitted along the axon to the NMJ, where it induces the voltage-gated calcium channels to open. Intracellular calcium entry leads to acetylcholine release in the synaptic space at the active zones but all scientists do not consider it the major release factor. Acetylcholine binding with its receptor at the muscle membrane generates an endplate potential when the induced depolarization is greater than the sodium voltage channel opening threshold. Muscle AP causes a muscle contraction involving the three phases. This paper will successively review the electrophysiological and molecular mechanisms involved at the pre-, inter- and postsynaptic levels. The last part of the article will discuss electromechanical considerations directly affecting the mechanical properties of the muscle fiber, most particularly the factors influencing the predetermined involvement of motor units, motor neuron electrical properties determining responses to synaptic inputs and finally the impact of recruited motor neurons and their electrical impulse rates on muscle contraction strength and velocity.

[Structural and molecular organization, development and maturation of the neuromuscular junction]. / Organisation structurale, moléculaire, formation et maturation de la jonction neuromusculaire.

The neuromuscular junction is made up of the apposition of highly differentiated domains of three types of cell: the motor neuronal ending, the terminal Schwann cell and the muscle postsynaptic membrane. These three components are surrounded by a basal lamina, dedicated to molecular signal exchanges controlling neuromuscular formation, maturation and maintenance. This functional and structural differentiated complex conducts synaptic neurotransmission to the skeletal muscle fiber. Nerve and muscle have distinct roles in synaptic compartment differentiation. The initial steps of this differentiation and the motor endplate formation require several postsynaptic molecular agents including agrin, the tyrosine kinase receptor MuSK. Neuregulin is essentially involved in Schwann cell survival and guidance for axonal growth.

[Molecular architecture of the sarcoplasmic reticulum and its role in the ECC]. / Architecture moléculaire du réticulum sarcoplasmique et son rôle dans le couplage excitation-contraction.

The sarcoplasmic reticulum (SR) plays a fundamental role in excitation-contraction coupling, which propagates the electric signal conversion along the muscle fiber's plasmic membrane to a mechanical event manifested as a muscle contraction. It plays a crucial role in calcium homeostasis and intracellular calcium storage control (storage, liberation and uptake) necessary for fiber muscle contraction and then relaxation. These functions take place at the triad, made up of individualized SR subdomains where the protein-specific organization provides efficient and fast coupling. Ryanodine receptors (RyR) and dihydropyridine receptors (DHPR) mainly act in calcium exchanges in the SR. This particular structural and molecular architecture must be correlated to its functional specificity.

[Morphological study of CNS lesions and the consequences on rat neuromuscular junction and peripheral nerve using confocal laser scanning microscopy and Koelle's technique]. / Existe-t-il un retentissement sur la jonction neuromusculaire de rat lors de lésions du système nerveux central ? Etude morphologique en microscopie confocale et technique de Koelle.

STATE OF THE ART: In humans, it is currently believed that peripheral nerves remain intact after central nervous system (CNS) injuries. This should lead us to observe a lack of amyotrophy in the peripheral projection areas of CNS damage. Nevertheless, the appearance of amyotrophy, described as underuse amyotrophy, is common in victims of CNS injury. Its pathophysiology remains poorly understood and is currently being debated. Amyotrophy could result directly from the structural deterioration of a nervous fiber in the muscular area corresponding to the CNS injury caused by neuromuscular junction (NMJ) changes. AIMS OF THIS STUDY: The aims of this study were to assess the repercussions of a CNS injury on the NMJ and peripheral nerve complex and to evaluate the involvement of peripheral nerves and NMJs in plasticity. METHODOLOGY: Peripheral nerve and muscle biopsies were collected from a group of 35 female Wistar rats that had previously undergone a thoracic spinal cord hemisection (15 rats at the T2 level (group 1), 15 rats at the T6 level (group 2), and 5 matched rats used as controls). We studied the localization and expression of the NMJ molecular components in muscle specimens by immunohistochemistry using confocal microscopy. We also searched for signs of nerve and muscle degeneration using light and electron microscopy. RESULTS: We observed nonpathologic NMJs coexisting with completely denervated and partially reinnervated NMJs. We also found characteristics of embryonic behavior in rat axons secondary to axonal caliber distortions. Some authors associate this decrease in axonal activity with physiological denervation. CONCLUSION: This project was designed to improve the understanding of the mechanisms involved in the interactions between the first and second motoneurons after different types of CNS injuries, with variable functional repercussions. Our results strongly suggest that CNS injuries lead to both morphological and functional repercussions at the NMJ and the peripheral nerve.

[Anatomy and physiology of the peripheral nerve]. / Organisation anatomique et physiologique du nerf périphérique.

The peripheral nerve provides the pathway for motor, sensory and vegetative axons belonging to the peripheral nervous system. It transmits information between these neurons and their peripheral effectors in both directions (sensory receptors, skeletal muscles and viscera). The afferences to the periphery correspond to the nerve motor content, whereas efferences from the periphery, in charge of delivering information to the central integrators, correspond to nerve-sensitive content. This information support depends on intrinsic properties of the nerve itself. Recent advances in cellular and molecular biology have provided a better understanding of nerve physiology, which are reviewed here as an indispensable basis to the study of its pathology.

The CHRNE 1293insG founder mutation is a frequent cause of congenital myasthenia in North Africa.

OBJECTIVE: Mutations in various genes of the neuromuscular junction cause congenital myasthenic syndrome (CMS). A single truncating mutation (epsilon1293insG) in the acetylcholine receptor epsilon subunit gene (CHRNE) was most often identified in CMS families originating from North Africa and was possibly a founder mutation. METHODS: Twenty-three families were studied with an early onset form of CMS and originating from Tunisia, Algeria, Morocco, and Libya. Screening for the mutation epsilon1293insG was performed by direct sequencing. Haplotype analysis was done with 9 (CA)n repeat microsatellite markers and 6 SNPs flanking epsilon1293insG on chromosome 17p13-p12. Dating was calculated using the ESTIAGE method for rare genetic diseases. RESULTS: The epsilon1293insG mutation was identified in 14 families (about 60% of the initial 23). The expression of the CMS in affected members of these families was relatively homogeneous, without fetal involvement or being life-threatening, with moderate hypotonia and oculobulbar involvement, mild and stable disease course, and good response to cholinesterase inhibitors. Haplotype analysis revealed a common conserved haplotype encompassing a distance of 63 kb. The estimated age of the founder event was at least 700 years. CONCLUSIONS: These results strongly support the hypothesis that epsilon1293insG derives from an ancient single founder event in the North African population. Identification of founder mutations in isolated or inbred populations may have important implications in the context of molecular diagnosis and genetic counseling of patients and families by detection of heterozygous carriers.

Towards the molecular elucidation of congenital myasthenic syndromes: identification of mutations in MuSK.

Congenital myasthenic syndromes (CMS) are rare genetic diseases affecting the neuromuscular junction (NMJ) and characterized by a dysfunction of the neurotransmission. They are heterogeneous at the pathophysiological level and can be classified in three categories according to their origin: presynaptic, synaptic or postsynaptic. The strategy for the diagnosis and characterization of CMS relies on the clinic, EMG, muscle biopsy, identification of mutations in genes known to be responsible for CMS and the demonstration that the gene mutations are the cause of the disease by using experimental approaches. As an example of such strategy, we report briefly here the characterization of the first case of a human neuromuscular transmission dysfunction due to mutations in the gene encoding a postsynaptic molecule, the muscle-specific receptor tyrosine kinase (MuSK). Gene analysis identified two heteroallelic mutations, a frameshift mutation (c.220insC) and a missense mutation (V790M). The muscle biopsy showed marked pre- and postsynaptic structural abnormalities of the neuromuscular junction as well as a severe decrease in acetylcholine receptor epsilon-subunit and MuSK expression. In vitro and in vivo expression experiments were performed using mutant MuSK reproducing the human mutations. The results obtained strongly suggested that the missense mutation, in the presence of a null mutation on the other allele, was responsible for the severe synaptic changes observed in the patient and, hence, is causing the disease. However the molecular origin of a large number of CMS is still unknown. There are hundreds of molecules known to be present at the NMJ and mutations in the genes coding for these synaptic molecules are likely to be responsible for a neuromuscular block.

[Congenital myasthenic syndromes due to mutations in the rapsyn gene]. / Syndromes myasthéniques congénitaux dus à des mutations du gène de la rapsyne.

Congenital myasthenic syndromes (CMS) are genetic diseases characterized by dysfunctional neuromuscular transmission and usually start during the neonatal period. Most are due to postsynaptic abnormalities, specifically to mutations in the acetylcholine receptor (AChR) genes. In 2002, the group of A Engel reported the first cases of CMS with mutations in the gene coding rapsyn, a postsynaptic molecule which stabilizes AChR aggregates at the neuromuscular junction. Since this first publication, more than 30 other cases, including six in France, have been reported. Study of these published cases allows us to distinguish three classes of phenotypes: 1) severe neonatal cases; 2) more benign cases, starting during infancy; 3) cases with facial malformations, involving Jewish patients originating from the Near-East. Comparison of the observations of other groups with our own has led us to the following conclusions: the N88K mutation is frequent (homozygous in 50% of cases); besides the N88K mutation, the second mutation varies considerably; heterozygous allelic cases (N88K + another mutation) are severe; there is probably a founder effect in the European population. There is phenotypic variability in the homozygous N88K cases, with benign cases and severe cases of early expression. A Engel and colleagues report that the seven cases of benign CMS with facial malformation, previously described in the Jewish population of Iraq and Iran, were caused by mutation in the promoter region of the rapsyn gene.

Multicenter linkage study of schizophrenia loci on chromosome 22q.

The hypothesis of the existence of one or more schizophrenia susceptibility loci on chromosome 22q is supported by reports of genetic linkage and association, meta-analyses of linkage, and the observation of elevated risk for psychosis in people with velocardiofacial syndrome, caused by 22q11 microdeletions. We tested this hypothesis by evaluating 10 microsatellite markers spanning 22q in a multicenter sample of 779 pedigrees. We also incorporated age at onset and sex into the analysis as covariates. No significant evidence for linkage to schizophrenia or for linkage associated with earlier age at onset, gender, or heterogeneity across sites was observed. We interpret these findings to mean that the population-wide effects of putative 22q schizophrenia susceptibility loci are too weak to detect with linkage analysis even in large samples.