Iulia Munteanu

A previously unidentified MECP2 open reading frame defines a new protein isoform relevant to Rett syndrome

Rett syndrome is caused by mutations in the gene MECP2 in ∼80% of affected individuals. We describe a previously unknown MeCP2 isoform. Mutations unique to this isoform and the absence, until now, of identified mutations specific to the previously recognized protein indicate an important role for the newly discovered molecule in the pathogenesis of Rett syndrome.

Mutations in NHLRC1 cause progressive myoclonus epilepsy

Lafora progressive myoclonus epilepsy is characterized by pathognomonic endoplasmic reticulum (ER)-associated polyglucosan accumulations. We previously discovered that mutations in EPM2A cause Lafora disease. Here, we identify a second gene associated with this disease, NHLRC1 (also called EPM2B), which encodes malin, a putative E3 ubiquitin ligase with a RING finger domain and six NHL motifs. Laforin and malin colocalize to the ER, suggesting they operate in a related pathway protecting against polyglucosan accumulation and epilepsy.

Loss-of-function mutations in MICU1 cause a brain and muscle disorder linked to primary alterations in mitochondrial calcium signaling

Mitochondrial Ca2+ uptake has key roles in cell life and death. Physiological Ca2+ signaling regulates aerobic metabolism, whereas pathological Ca2+ overload triggers cell death. Mitochondrial Ca2+ uptake is mediated by the Ca2+ uniporter complex in the inner mitochondrial membrane, which comprises MCU, a Ca2+-selective ion channel, and its regulator, MICU1. Here we report mutations of MICU1 in individuals with a disease phenotype characterized by proximal myopathy, learning difficulties and a progressive extrapyramidal movement disorder. In fibroblasts from subjects with MICU1 mutations, agonist-induced mitochondrial Ca2+ uptake at low cytosolic Ca2+ concentrations was increased, and cytosolic Ca2+ signals were reduced. Although resting mitochondrial membrane potential was unchanged in MICU1-deficient cells, the mitochondrial network was severely fragmented. Whereas the pathophysiology of muscular dystrophy and the core myopathies involves abnormal mitochondrial Ca2+ handling, the phenotype associated with MICU1 deficiency is caused by a primary defect in mitochondrial Ca2+ signaling, demonstrating the crucial role of mitochondrial Ca2+ uptake in humans.

Clinical and genetic findings in a large cohort of patients with ryanodine receptor 1 gene-associated myopathies.

Ryanodine receptor 1 (RYR1) mutations are a common cause of congenital myopathies associated with both dominant and recessive inheritance. Histopathological findings frequently feature central cores or multi‐minicores, more rarely, type 1 predominance/uniformity, fiber‐type disproportion, increased internal nucleation, and fatty and connective tissue. We describe 71 families, 35 associated with dominant RYR1 mutations and 36 with recessive inheritance. Five of the dominant mutations and 35 of the 55 recessive mutations have not been previously reported. Dominant mutations, typically missense, were frequently located in recognized mutational hotspot regions, while recessive mutations were distributed throughout the entire coding sequence. Recessive mutations included nonsense and splice mutations expected to result in reduced RyR1 protein. There was wide clinical variability. As a group, dominant mutations were associated with milder phenotypes; patients with recessive inheritance had earlier onset, more weakness, and functional limitations. Extraocular and bulbar muscle involvement was almost exclusively observed in the recessive group. In conclusion, our study reports a large number of novel RYR1 mutations and indicates that recessive variants are at least as frequent as the dominant ones. Assigning pathogenicity to novel mutations is often difficult, and interpretation of genetic results in the context of clinical, histological, and muscle magnetic resonance imaging findings is essential. Hum Mutat 33:981–988, 2012.

VMA21 deficiency prevents vacuolar ATPase assembly and causes autophagic vacuolar myopathy

X-linked Myopathy with Excessive Autophagy (XMEA) is a childhood onset disease characterized by progressive vacuolation and atrophy of skeletal muscle. We show that XMEA is caused by hypomorphic alleles of the VMA21 gene, that VMA21 is the diverged human ortholog of the yeast Vma21p protein, and that like Vma21p, VMA21 is an essential assembly chaperone of the vacuolar ATPase (V-ATPase), the principal mammalian proton pump complex. Decreased VMA21 raises lysosomal pH which reduces lysosomal degradative ability and blocks autophagy. This reduces cellular free amino acids which leads to downregulation of the mTORC1 pathway, and consequent increased macroautophagy resulting in proliferation of large and ineffective autolysosomes that engulf sections of cytoplasm, merge, and vacuolate the cell. Our results uncover a novel mechanism of disease, namely macroautophagic overcompensation leading to cell vacuolation and tissue atrophy.

Retraction Notice to: VMA21 Deficiency Causes an Autophagic Myopathy by Compromising V-ATPase Activity and Lysosomal Acidification

X-linked myopathy with excessive autophagy (XMEA) is a childhood-onset disease characterized by progressive vacuolation and atrophy of skeletal muscle. We show that XMEA is caused by hypomorphic alleles of the VMA21 gene, that VMA21 is the diverged human ortholog of the yeast Vma21p protein, and that like Vma21p it is an essential assembly chaperone of the V-ATPase, the principal mammalian proton pump complex. Decreased VMA21 raises lysosomal pH, which reduces lysosomal degradative ability and blocks autophagy. This reduces cellular free amino acids, which upregulates the mTOR pathway and mTOR-dependent macroautophagy, resulting in proliferation of large and ineffective autolysosomes that engulf sections of cytoplasm, merge together, and vacuolate the cell. Our results uncover macroautophagic overcompensation leading to cell vacuolation and tissue atrophy as a mechanism of disease.

RyR1 Deficiency in Congenital Myopathies Disrupts Excitation-Contraction Coupling

In skeletal muscle, excitation–contraction (EC) coupling is the process whereby the voltage‐gated dihydropyridine receptor (DHPR) located on the transverse tubules activates calcium release from the sarcoplasmic reticulum by activating ryanodine receptor (RyR1) Ca2+ channels located on the terminal cisternae. This subcellular membrane specialization is necessary for proper intracellular signaling and any alterations in its architecture may lead to neuromuscular disorders. In this study, we present evidence that patients with recessive RYR1‐related congenital myopathies due to primary RyR1 deficiency also exhibit downregulation of the alfa 1 subunit of the DHPR and show disruption of the spatial organization of the EC coupling machinery. We created a cellular RyR1 knockdown model using immortalized human myoblasts transfected with RyR1 siRNA and confirm that knocking down RyR1 concomitantly downregulates not only the DHPR but also the expression of other proteins involved in EC coupling. Unexpectedly, this was paralleled by the upregulation of inositol‐1,4,5‐triphosphate receptors; functionally however, upregulation of the latter Ca2+ channels did not compensate for the lack of RyR1‐mediated Ca2+ release. These results indicate that in some patients, RyR1 deficiency concomitantly alters the expression pattern of several proteins involved in calcium homeostasis and that this may influence the manifestation of these diseases.

FINE-MAPPING THE GENE FOR X-LINKED MYOPATHY WITH EXCESSIVE AUTOPHAGY

Myopathies with autophagic vacuoles with sarcolemmal features (MAVSF) are a group of skeletal muscle diseases exhibiting autophagic vacuolation of myofibers. The vacuoles have membranes of mixed sarcolemmal, lysosomal, and autophagosomal origin. They contain partially degraded cell components including proteins, glycogen, membrane whorls, and organelles.1 The two most common MAVSF are Danon disease and X-linked myopathy with excessive autophagy (XMEA). Danon disease is caused by mutations in the LAMP2B isoform of the lysosome-associated membrane protein-2 ( LAMP2 ) gene.2 LAMP2B may play a role in approaching lysosomes to merge with autophagosomes.1 The genes for XMEA and the other MAVSF are unknown. We previously mapped the XMEA gene to chromosomal band Xq28, one of the most gene-rich regions of the genome, in a 4.64 Mb locus containing over 110 genes.3 We now refine this locus to 0.58 Mb containing only six genes. XMEA is inherited recessively, affecting boys and sparing carrier females. Onset is between ages 6 and 18 years with weakness and gradual wasting of the proximal muscles of the lower extremities. Other skeletal muscle groups are progressively affected including the upper limb girdle and distal muscles. Patients are wheelchair-bound in their 50s, and lifespan appears to be shortened due to respiratory muscle involvement. Considerable variation from this clinical picture can be seen, with some patients exhibiting extremely mild and sometimes no weakness or wasting (see below). The central and …

Congenital autophagic vacuolar myopathy is allelic to X-linked myopathy with excessive autophagy

X-linked myopathy with excessive autophagy (XMEA) is characterized by weakness and wasting primarily of the proximal muscles of the lower extremities. Onset is usually after age 5 and progression is extremely slow with ambulation maintained well into the 50s. The heart, CNS, peripheral nervous system, and other organs are clinically spared. Pathology reveals large autophagic vacuoles enclosing incompletely degraded cytoplasmic components, which translocate to the myofiber surface and extrude their contents, forming a field of cell debris between multiplied layers of basal lamina.1 XMEA is caused by mutations of the VMA21 gene, which reduce, but do not eliminate, expression of the chief assembly chaperone (VMA21) of the main proton pump (V-ATPase [vacuolar-type H+–adenosine triphosphatase]) of all mammalian cells.2

Cardiac autophagic vacuolation in severe X-linked myopathy with excessive autophagy

X-linked myopathy with excessive autophagy (XMEA), caused by mutations of the VMA21 gene, is a strictly skeletal muscle disease. Extensive studies in yeast established VMA21 as the master assembly chaperone of V-ATPase, the complex multisubunit proton pump that acidifies organelles and that is vital to all mammalian tissues. As such, skeletal muscle disease exclusivity in XMEA is highly surprising. We now show that the severest VMA21 mutation, c.164-6t>g, does result in XMEA-typical pathology with autophagic vacuolar changes outside skeletal muscle, namely in the heart. However, even patients with this mutation do not exhibit clinical extramuscular disease, including cardiac disease, despite extreme skeletal muscle wasting to the extent of ventilation dependence. Uncovering the unique skeletal muscle vulnerability to defective organellar acidification, and resultant tissue-destructive excessive autophagy, will be informative to the understanding of muscle physiology. Alternatively, understanding extramuscular resistance to VMA21 mutation might disclose heretofore unknown mammalian V-ATPase assembly chaperones other than VMA21.