Margherita Milone

Mutation of the acetylcholine receptor α subunit causes a slow-channel myasthenic syndrome by enhancing agonist binding affinity

In five members of a family and another unrelated person affected by a slow-channel congenital myasthenic syndrome (SCCMS), molecular genetic analysis of acetylcholine receptor (AChR) subunit genes revealed a heterozygous G to A mutation at nucleotide 457 of the alpha subunit, converting codon 153 from glycine to serine (alpha G153S). Electrophysiologic analysis of SCCMS end plates revealed prolonged decay of miniature end plate currents and prolonged activation episodes of single AChR channels. Engineered mutant AChR expressed in HEK fibroblasts exhibited prolonged activation episodes strikingly similar to those observed at the SCCMS end plates. Single-channel kinetic analysis of engineered alpha G153S AChR revealed a markedly decreased rate of ACh dissociation, which causes the mutant AChR to open repeatedly during ACh occupancy. In addition, ACh binding measurements combined with the kinetic analysis indicated increased desensitization of the mutant AChR. Thus, ACh binding affinity can dictate the time course of the synaptic response, and alpha G153 contributes to the low binding affinity for ACh needed to speed the decay of the synaptic response.

Congenital Myasthenic Syndrome Caused by Decreased Agonist Binding Affinity Due to a Mutation in the Acetylcholine Receptor ε Subunit

We describe the genetic and kinetic defects for a low-affinity fast channel disease of the acetylcholine receptor (AChR) that causes a myasthenic syndrome. In two unrelated patients with very small miniature end plate (EP) potentials, but with normal EP AChR density and normal EP ultrastructure, patch-clamp studies demonstrated infrequent AChR channel events, diminished channel reopenings during ACh occupancy, and resistance to desensitization by ACh. Each patient had two heteroallelic AChR epsilon subunit gene mutations: a common epsilon P121L mutation, a signal peptide mutation (epsilon G-8R) (patient 1), and a glycosylation consensus site mutation (epsilon S143L) (patient 2). AChR expression in HEK fibroblasts was normal with epsilon P121L but was markedly reduced with the other mutations. Therefore, epsilon P121L defines the clinical phenotype. Studies of the engineered epsilon P121L AChR revealed a markedly decreased rate of channel opening, little change in affinity of the resting state for ACh, but reduced affinity of the open channel and desensitized states.

Molecular and clinical genetics of mitochondrial diseases due to POLG mutations.

Mutations in the POLG gene have emerged as one of the most common causes of inherited mitochondrial disease in children and adults. They are responsible for a heterogeneous group of at least 6 major phenotypes of neurodegenerative disease that include: 1) childhood Myocerebrohepatopathy Spectrum disorders (MCHS), 2) Alpers syndrome, 3) Ataxia Neuropathy Spectrum (ANS) disorders, 4) Myoclonus Epilepsy Myopathy Sensory Ataxia (MEMSA), 5) autosomal recessive Progressive External Ophthalmoplegia (arPEO), and 6) autosomal dominant Progressive External Ophthalmoplegia (adPEO). Due to the clinical heterogeneity, time‐dependent evolution of symptoms, overlapping phenotypes, and inconsistencies in muscle pathology findings, definitive diagnosis relies on the molecular finding of deleterious mutations. We sequenced the exons and flanking intron region from approximately 350 patients displaying a phenotype consistent with POLG related mitochondrial disease and found informative mutations in 61 (17%). Two mutant alleles were identified in 31 unrelated index patients with autosomal recessive POLG‐related disorders. Among them, 20 (67%) had Alpers syndrome, 4 (13%) had arPEO, and 3 (10%) had ANS. In addition, 30 patients carrying one altered POLG allele were found. A total of 25 novel alterations were identified, including 6 null mutations. We describe the predicted structural/functional and clinical importance of the previously unreported missense variants and discuss their likelihood of being pathogenic. In conclusion, sequence analysis allows the identification of mutations responsible for POLG‐related disorders and, in most of the autosomal recessive cases where two mutant alleles are found in trans, finding deleterious mutations can provide an unequivocal diagnosis of the disease. Published 2008 Wiley‐Liss, Inc.

Rapsyn Mutations in Humans Cause Endplate Acetylcholine-Receptor Deficiency and Myasthenic Syndrome

Congenital myasthenic syndromes (CMSs) stem from genetic defects in endplate (EP)-specific presynaptic, synaptic, and postsynaptic proteins. The postsynaptic CMSs identified to date stem from a deficiency or kinetic abnormality of the acetylcholine receptor (AChR). All CMSs with a kinetic abnormality of AChR, as well as many CMSs with a deficiency of AChR, have been traced to mutations in AChR-subunit genes. However, in a subset of patients with EP AChR deficiency, the genetic defect has remained elusive. Rapsyn, a 43-kDa postsynaptic protein, plays an essential role in the clustering of AChR at the EP. Seven tetratricopeptide repeats (TPRs) of rapsyn subserve self-association, a coiled-coil domain binds to AChR, and a RING-H2 domain associates with beta-dystroglycan and links rapsyn to the subsynaptic cytoskeleton. Rapsyn self-association precedes recruitment of AChR to rapsyn clusters. In four patients with EP AChR deficiency but with no mutations in AChR subunits, we identify three recessive rapsyn mutations: one patient carries L14P in TPR1 and N88K in TPR3; two are homozygous for N88K; and one carries N88K and 553ins5, which frameshifts in TPR5. EP studies in each case show decreased staining for rapsyn and AChR, as well as impaired postsynaptic morphological development. Expression studies in HEK cells indicate that none of the mutations hinders rapsyn self-association but that all three diminish coclustering of AChR with rapsyn.

Diseased skeletal muscle: a noncardiac source of increased circulating concentrations of cardiac troponin T.

OBJECTIVES The purpose of this study was to determine whether there is immunoreactive cardiac troponin T (cTnT) expression in diseased skeletal muscle that might cause possible false-positive increases in cTnT. BACKGROUND Cardiac troponin (I or T) is the biomarker of choice for the diagnosis of cardiac injury. Recently, we were presented with a case that challenged the specificity of cTnT. METHODS Patients with myopathies seen in the Neuromuscular Clinic at the Mayo Clinic were screened for increases in cTnT. If present, an assay for cTnI was performed. If normal, skeletal biopsy tissue was obtained for Western blot analysis using the capture and detection antibodies from both the fourth-generation and high-sensitivity cTnT assays. Results were compared with findings in normal cardiac tissue. RESULTS Sixteen patients had increases in cTnT but not cTnI. All had a myopathy by clinical evaluation, clinical testing, and biopsy. Four residual biopsy samples were obtained. All 3 antibodies used in the cTnT (M11.7, M7) and high-sensitivity cTnT (5D8, M7) assays were immunoreactive with a 37- to 39-kDa protein in all 4 diseased skeletal muscle biopsy specimens and in cardiac tissue. A second immunoreactive isoform (34 to 36 kDa) was also found in 1 patient. None of the noncardiac control tissues expressed immunoreactive protein. CONCLUSIONS These results document that there are forms in diseased skeletal muscle that could cause increases in circulating levels of cTnT. These increases could reflect re-expressed isoforms. Clinicians need to be aware of the possibility that noncardiac increases in cTnT may occur and lead to a possible false-positive diagnosis of cardiac injury when skeletal muscle pathology is present.

Expedited PublicationDiseased Skeletal Muscle: A Noncardiac Source of Increased Circulating Concentrations of Cardiac Troponin T

OBJECTIVES The purpose of this study was to determine whether there is immunoreactive cardiac troponin T (cTnT) expression in diseased skeletal muscle that might cause possible false-positive increases in cTnT. BACKGROUND Cardiac troponin (I or T) is the biomarker of choice for the diagnosis of cardiac injury. Recently, we were presented with a case that challenged the specificity of cTnT. METHODS Patients with myopathies seen in the Neuromuscular Clinic at the Mayo Clinic were screened for increases in cTnT. If present, an assay for cTnI was performed. If normal, skeletal biopsy tissue was obtained for Western blot analysis using the capture and detection antibodies from both the fourth-generation and high-sensitivity cTnT assays. Results were compared with findings in normal cardiac tissue. RESULTS Sixteen patients had increases in cTnT but not cTnI. All had a myopathy by clinical evaluation, clinical testing, and biopsy. Four residual biopsy samples were obtained. All 3 antibodies used in the cTnT (M11.7, M7) and high-sensitivity cTnT (5D8, M7) assays were immunoreactive with a 37- to 39-kDa protein in all 4 diseased skeletal muscle biopsy specimens and in cardiac tissue. A second immunoreactive isoform (34 to 36 kDa) was also found in 1 patient. None of the noncardiac control tissues expressed immunoreactive protein. CONCLUSIONS These results document that there are forms in diseased skeletal muscle that could cause increases in circulating levels of cTnT. These increases could reflect re-expressed isoforms. Clinicians need to be aware of the possibility that noncardiac increases in cTnT may occur and lead to a possible false-positive diagnosis of cardiac injury when skeletal muscle pathology is present.

Acetylcholine receptor M3 domain: stereochemical and volume contributions to channel gating.

By defining the functional defect in a congenital myasthenic syndrome (CMS), we show that the third transmembrane domain (M3) of the muscle acetylcholine receptor governs the speed and efficiency of gating of its channel. The clinical phenotype of this CMS results from the mutation V285I in M3 of the α subunit, which attenuates endplate currents, accelerates their decay and causes abnormally brief acetylcholine-induced single-channel currents. Kinetic analysis of engineered αV285I receptors demonstrated a predominant effect on channel gating, with abnormally slow opening and rapid closing rates. Analysis of site-directed mutations revealed stereochemical and volume-dependent contributions of αV285 to channel gating. Thus, we demonstrate a functional role for the M3 domain as a key component of the nicotinic acetylcholine receptor channel-gating mechanism.By defining the functional defect in a congenital myasthenic syndrome (CMS), we show that the third transmembrane domain (M3) of the muscle acetylcholine receptor governs the speed and efficiency of gating of its channel. The clinical phenotype of this CMS results from the mutation V285I in M3 of the α subunit, which attenuates endplate currents, accelerates their decay and causes abnormally brief acetylcholine-induced single-channel currents. Kinetic analysis of engineered αV285I receptors demonstrated a predominant effect on channel gating, with abnormally slow opening and rapid closing rates. Analysis of site-directed mutations revealed stereochemical and volume-dependent contributions of αV285 to channel gating. Thus, we demonstrate a functional role for the M3 domain as a key component of the nicotinic acetylcholine receptor channel-gating mechanism.

Mitochondrial DNA polymerase γ mutations: an ever expanding molecular and clinical spectrum

Mutations in the POLG gene have emerged as one of the most common causes of inherited mitochondrial diseases in children and adults. This study sequenced the exons and flanking intronic regions of the POLG gene from 2697 unrelated patients with clinical presentations suggestive of POLG deficiency. Informative mutations have been identified in 136 unrelated individuals (5%), including 92 patients with two recessive pathogenic alleles and three patients harbouring a dominant mutation. Twenty-four novel recessive mutations and a novel possible dominant mutation, p.Y951N, were identified. All missense mutations occurred at evolutionarily conserved amino acids within functionally important regions identified by molecular modelling analyses. Oligonucleotide array comparative genomic hybridisation analyses performed on DNA samples from 81 patients with one mutant POLG allele identified a large intragenic deletion in only one patient, suggesting that large deletions in POLG are rare. The 92 patients with two mutant alleles exhibited a broad spectrum of disease. Almost all patients in all age groups had some degree of neuropathy. Seizures, hepatopathy, and lactic acidaemia were predominant in younger patients. By comparison, patients who developed symptoms in adulthood had a higher percentage of myopathy, sensory ataxia, and chronic progressive external ophthalmoplegia (CPEO)/ptosis. In conclusion, POLG mutations account for a broad clinical spectrum of mitochondrial disorders. Sequence analysis of the POLG gene should be considered as a part of routine screening for mitochondrial disorders, even in the absence of apparent mitochondrial DNA abnormalities.

The spectrum of mutations causing end-plate acetylcholinesterase deficiency.

The end‐plate species of acetylcholinesterase (AChE) is an asymmetric enzyme consisting of a collagenic tail subunit composed of three collagenic strands (ColQ), each attached to a tetramer of the T isoform of the catalytic subunit (AChET) via a proline‐rich attachment domain. The principal function of the tail subunit is to anchor asymmetric AChE in the synaptic basal lamina. Human end‐plate AChE deficiency was recently shown to be caused by mutations in COLQ. We here report nine novel COLQ mutations in 7 patients with end‐plate AChE deficiency. We examine the effects of the mutations on the assembly of asymmetric AChE by coexpressing each genetically engineered COLQ mutant with ACHET in COS cells. We classify the newly recognized and previously reported COLQ mutations into four classes according to their position in ColQ and their effect on AChE expression. We find that missense mutations in the proline‐rich attachment domain abrogate attachment of catalytic subunits, that truncation mutations in the ColQ collagen domain prevent the assembly of asymmetric AChE, that hydrophobic missense residues in the C‐terminal domain prevent triple helical assembly of the ColQ collagen domain, and that other mutations in the C‐terminal region produce asymmetric species of AChE that are likely insertion incompetent. Ann Neurol 2000;47:162–170.

Mode Switching Kinetics Produced by a Naturally Occurring Mutation in the Cytoplasmic Loop of the Human Acetylcholine Receptor ε Subunit

We describe the genetic and kinetic defects in a congenital myasthenic syndrome caused by heteroallelic mutations of the acetylcholine receptor (AChR) epsilon subunit gene. The mutations are an in-frame duplication of six residues in the long cytoplasmic loop (epsilon1254ins18) and a cysteine-loop null mutation (epsilonC128S). The epsilon1254 ins18 mutation causes mode switching in the kinetics of receptor activation in which three modes activate slowly and inactivate rapidly. The epsilon1245ins18-AChR at the endplate shows abnormally brief activation episodes during steady state agonist application and appears electrically silent during the synaptic response to acetylcholine. The phenotypic consequences are endplate AChR deficiency, simplification of the postsynaptic region, and compensatory expression of fetal AChR that restores electrical activity at the endplate and rescues the phenotype.