Project description:Mitochondrial myopathy and sideroblastic anemia (MLASA) is a rare, autosomal recessive oxidative phosphorylation disorder specific to skeletal muscle and bone marrow. Linkage analysis and homozygosity testing of two families with MLASA localized the candidate region to 1.2 Mb on 12q24.33. Sequence analysis of each of the six known genes in this region, as well as four putative genes with expression in bone marrow or muscle, identified a homozygous missense mutation in the pseudouridine synthase 1 gene (PUS1) in all patients with MLASA from these families. The mutation is the only amino acid coding change in these 10 genes that is not a known polymorphism, and it is not found in 934 controls. The amino acid change affects a highly conserved amino acid, and appears to be in the catalytic center of the protein, PUS1p. PUS1 is widely expressed, and quantitative expression analysis of RNAs from liver, brain, heart, bone marrow, and skeletal muscle showed elevated levels of expression in skeletal muscle and brain. We propose deficient pseudouridylation of mitochondrial tRNAs as an etiology of MLASA. Identification of the pathophysiologic pathways of the mutation in these families may shed light on the tissue specificity of oxidative phosphorylation disorders.

Project description:YARS2 variants have previously been described in patients with myopathy, lactic acidosis and sideroblastic anemia 2 (MLASA2). YARS2 encodes the mitochondrial tyrosyl-tRNA synthetase, which is responsible for conjugating tyrosine to its cognate mt-tRNA for mitochondrial protein synthesis. Here we describe 14 individuals from 11 families presenting with sideroblastic anemia and YARS2 variants that we identified using a sideroblastic anemia gene panel or exome sequencing. The phenotype of these patients ranged from MLASA to isolated congenital sideroblastic anemia. As in previous cases, inter- and intra-familial phenotypic variability was observed, however, this report includes the first cases with isolated sideroblastic anemia and patients with biallelic YARS2 variants that have no clinically ascertainable phenotype. We identified ten novel YARS2 variants and three previously reported variants. In vitro amino-acylation assays of five novel missense variants showed that three had less effect on the catalytic activity of YARS2 than the most commonly reported variant, p.(Phe52Leu), associated with MLASA2, which may explain the milder phenotypes in patients with these variants. However, the other two missense variants had a more severe effect on YARS2 catalytic efficiency. Several patients carried the common YARS2 c.572 G>T, p.(Gly191Val) variant (minor allele frequency =0.1259) in trans with a rare deleterious YARS2 variant. We have previously shown that the p.(Gly191Val) variant reduces YARS2 catalytic activity. Consequently, we suggest that biallelic YARS2 variants, including severe loss-of-function alleles in trans of the common p.(Gly191Val) variant, should be considered as a cause of isolated congenital sideroblastic anemia, as well as the MLASA syndromic phenotype.

Project description:We analyzed samples from two affected brothers (Affected 3 and 4) and their two affected female cousins (Affected 7 and 9) homozygous for the MLASA ? associated C656T mutation in the PUS1 gene; four parents ? heterozygous carriers of the C656T mutation (Parents 1, 2, 5, 6), and an unaffected female carrying wild-type genotype at the PUS1 gene (Control 8). In addition, two females and one male with normal hearing from Arab-Israeli family with nonsyndromic deafness carrying wild-type PUS1 sequence were used as controls (Controls 10, 11, 12). Keywords: Comparison of genome-wide expression in cell lines of patients and controls

Project description:The tissue specificity of mitochondrial diseases is poorly understood. Recently, tissue-specific quantitative differences of the components of the mitochondrial translation system have been found to correlate with disease presentation in fatal hepatopathy caused by mutations in mitochondrial translation factor EFG1. MLASA is an autosomal recessive inherited progressive oxidative phosphorylation disorder that affects muscle and erythroid cells. The disease is caused by the homozygous point mutation C656T (R116W) in the catalytic domain of the pseudouridylate synthase 1 (PUS1) gene, which leads to a complete lack of pseudouridylation at the expected sites in mitochondrial and cytoplasmic tRNAs. Despite the presence of these altered tRNAs, most tissues are unaffected, and even in muscle and erythroid cells the disease phenotype only slowly emerges over the course of years. In order to elucidate intracellular pathways through which the homozygous mutation leads to tissue-restricted phenotype, we performed microarray expression analysis of EBV-transformed lymphoblasts from MLASA patients, heterozygous parents, and controls using human Beadchip microarray with 47,296 transcripts. Genes coding for proteins involved in DNA transcription and its regulation, and metal binding proteins, demonstrated major differences in expression between patients and all other individuals with normal phenotype. Genes coding for ribosomal proteins differed significantly between individual with at least one copy of the mutated PUS1 gene and controls. These findings indicate that the lack of tRNA pseudouridylation can be overcome by compensatory changes in levels of ribosomal proteins, and that the disease phenotype in affected tissues is likely due to pleiotropic effects of PUS1p on non-tRNA molecules involved in DNA transcription and iron metabolism. Similar combinations of mechanisms may play a role in the tissue specificity of other mitochondrial disorders.

Project description:Mitochondrial respiratory chain disorders are a heterogeneous group of disorders in which the underlying genetic defect is often unknown. We have identified a pathogenic mutation (c.156C>G [p.F52L]) in YARS2, located at chromosome 12p11.21, by using genome-wide SNP-based homozygosity analysis of a family with affected members displaying myopathy, lactic acidosis, and sideroblastic anemia (MLASA). We subsequently identified the same mutation in another unrelated MLASA patient. The YARS2 gene product, mitochondrial tyrosyl-tRNA synthetase (YARS2), was present at lower levels in skeletal muscle whereas fibroblasts were relatively normal. Complex I, III, and IV were dysfunctional as indicated by enzyme analysis, immunoblotting, and immunohistochemistry. A mitochondrial protein-synthesis assay showed reduced levels of respiratory chain subunits in myotubes generated from patient cell lines. A tRNA aminoacylation assay revealed that mutant YARS2 was still active; however, enzyme kinetics were abnormal compared to the wild-type protein. We propose that the reduced aminoacylation activity of mutant YARS2 enzyme leads to decreased mitochondrial protein synthesis, resulting in mitochondrial respiratory chain dysfunction. MLASA has previously been associated with PUS1 mutations; hence, the YARS2 mutation reported here is an alternative cause of MLASA.

Project description:Myopathy, lactic acidosis and sideroblastic anaemia (MLASA) is a rare condition that combines early-onset myopathy with lactic acidosis and sideroblastic anaemia. MLASA has been associated with a missense mutation in pseudouridylate synthase 1 (PUS1), an enzyme located in both nucleus and mitochondria, which converts uridine into pseudouridine in several cytosolic and mitochondrial tRNA positions and increases the efficiency of protein synthesis in both compartments. We examined two Italian brothers with MLSA and sequenced the PUS1 gene. We found combined defects in mitochondrial respiratory chain complexes in muscle and fibroblast homogenates of both patients, and low levels of mtDNA translation products in fibroblast mitochondria. A novel, homozygous stop mutation was present in PUS1 (E220X). The stop mutation in PUS1 is likely to determine the loss of function of the protein, since it predicts the synthesis of a protein missing 208/427 amino acid residues on the C terminus, and was associated with low mtDNA translation.

Project description:IntroductionMyopathy, lactic acidosis and sideroblastic anaemia (MLASA) is a rare condition that combines early-onset myopathy with lactic acidosis and sideroblastic anaemia. MLASA has been associated with a missense mutation in pseudouridylate synthase 1 (PUS1), an enzyme located in both nucleus and mitochondria, which converts uridine into pseudouridine in several cytosolic and mitochondrial tRNA positions and increases the efficiency of protein synthesis in both compartments.Subjects and methodsWe have identified two Italian brothers, offspring of distantly related parents, both of whom are affected by MLASA. The six exons of the PUS1 gene were analysed by automated sequencing.ResultsWe found combined defects in mitochondrial respiratory chain complexes in muscle and fibroblast homogenates of both patients, and low levels of mtDNA translation products in fibroblast mitochondria. A novel, homozygous stop mutation was present in PUS1 (E220X). We have investigated the structural and mechanistic aspects of the double localisation of PUS1, demonstrating that the isoform located in the nucleus contains an N-terminal extension which is absent in the mature mitochondrial isoform.ConclusionsThe stop mutation in PUS1 is likely to determine the loss of function of the protein, since it predicts the synthesis of a protein missing 208/427 amino acid residues on the C terminus, and was associated with low mtDNA translation. The structural differences in nuclear versus mitochondrial isoforms of PUS1 may be implicated in the variability of the clinical presentations in MLASA.

Project description:Sideroblastic anemias are acquired or inherited anemias that result in a decreased ability to synthesize hemoglobin in red blood cells and result in the presence of iron deposits in the mitochondria of red blood cell precursors. A common subtype of congenital sideroblastic anemia is due to autosomal recessive mutations in the SLC25A38 gene. The current treatment for SLC25A38 congenital sideroblastic anemia is chronic blood transfusion coupled with iron chelation. The function of SLC25A38 is not known. Here we report that the SLC25A38 protein, and its yeast homolog Hem25, are mitochondrial glycine transporters required for the initiation of heme synthesis. To do so, we took advantage of the fact that mitochondrial glycine has several roles beyond the synthesis of heme, including the synthesis of folate derivatives through the glycine cleavage system. The data were consistent with Hem25 not being the sole mitochondrial glycine importer, and we identify a second SLC25 family member Ymc1, as a potential secondary mitochondrial glycine importer. Based on these findings, we observed that high levels of exogenous glycine, or 5-aminolevulinic acid (5-Ala) a metabolite downstream of Hem25 in heme biosynthetic pathway, were able to restore heme levels to normal in yeast cells lacking Hem25 function. While neither glycine nor 5-Ala could ameliorate SLC25A38 congenital sideroblastic anemia in a zebrafish model, we determined that the addition of folate with glycine was able to restore hemoglobin levels. This difference is likely due to the fact that yeast can synthesize folate, whereas in zebrafish folate is an essential vitamin that must be obtained exogenously. Given the tolerability of glycine and folate in humans, this study points to a potential novel treatment for SLC25A38 congenital sideroblastic anemia.

Project description:Not available.

Project description:Mitochondrial myopathy, lactic acidosis and sideroblastic anemia (MLASA) is a rare mitochondrial disorder that has previously been associated with mutations in PUS1 and YARS2. In the present report, we describe a 6-year old male with an MLASA plus phenotype. This patient had features of MLASA in the setting of developmental delay, sensorineural hearing loss, epilepsy, agenesis of the corpus callosum, failure to thrive, and stroke-like episodes. Sequencing of the mitochondrial genome identified a novel de novo, heteroplasmic mutation in the mitochondrial DNA (mtDNA) encoded ATP6 gene (m.8969G>A, p.S148N). Whole exome sequencing did not identify mutations or variants in PUS1 or YARS2 or any known nuclear genes that could affect mitochondrial function and explain this phenotype. Studies of fibroblasts derived from the patient revealed a decrease in oligomycin-sensitive respiration, a finding which is consistent with a complex V defect. Thus, this mutation in MT-ATP6 may represent the first mtDNA point mutation associated with the MLASA phenotype.