Wolfram syndrome is an autosomal recessive disorder characterized by juvenile diabetes mellitus, diabetes insipidus, optic atrophy and a number of neurological symptoms including deafness, ataxia and peripheral neuropathy. Mitochondrial DNA deletions have been described in a few patients and a locus has been mapped to 4p16 by linkage analysis. Susceptibility to psychiatric illness is reported to be high in affected individuals and increased in heterozygous carriers in Wolfram syndrome families. We screened four candidate genes in a refined critical linkage interval covered by an unfinished genomic sequence of 600 kb. One of these genes, subsequently named wolframin, codes for a predicted transmembrane protein which was expressed in various tissues, including brain and pancreas, and carried loss-of-function mutations in both alleles in Wolfram syndrome patients.
Many muscular and neurological disorders are associated with mitochondrial dysfunction and are often accompanied by changes in mitochondrial morphology. Mutations in the gene encoding OPA1, a protein required for fusion of mitochondria, are associated with hereditary autosomal dominant optic atrophy type I. Here we show that mitochondrial fragmentation correlates with processing of large isoforms of OPA1 in cybrid cells from a patient with myoclonus epilepsy and ragged-red fibers syndrome and in mouse embryonic fibroblasts harboring an error-prone mitochondrial mtDNA polymerase ␥. Furthermore, processed OPA1 was observed in heart tissue derived from heart-specific TFAM knock-out mice suffering from mitochondrial cardiomyopathy and in skeletal muscles from patients suffering from mitochondrial myopathies such as myopathy encephalopathy lactic acidosis and stroke-like episodes. Dissipation of the mitochondrial membrane potential leads to fast induction of proteolytic processing of OPA1 and concomitant fragmentation of mitochondria. Recovery of mitochondrial fusion depended on protein synthesis and was accompanied by resynthesis of large isoforms of OPA1. Fragmentation of mitochondria was prevented by overexpressing OPA1. Taken together, our data indicate that proteolytic processing of OPA1 has a key role in inducing fragmentation of energetically compromised mitochondria. We present the hypothesis that this pathway regulates mitochondrial morphology and serves as an early response to prevent fusion of dysfunctional mitochondria with the functional mitochondrial network.
We showed that the human respiratory chain is organized in supramolecular assemblies of respiratory chain complexes, the respirasomes. The mitochondrial complexes I (NADH dehydrogenase) and III (cytochrome c reductase) form a stable core respirasome to which complex IV (cytochrome c oxidase) can also bind. An analysis of the state of respirasomes in patients with an isolated deficiency of single complexes provided evidence that the formation of respirasomes is essential for the assembly/stability of complex I, the major entry point of respiratory chain substrates. Genetic alterations leading to a loss of complex III prevented respirasome formation and led to the secondary loss of complex I. Therefore, primary complex III assembly deficiencies presented as combined complex III/I defects. This dependence of complex I assembly/stability on respirasome formation has important implications for the diagnosis of mitochondrial respiratory chain disorders.
Mutations of the WFS1 gene are responsible for Wolfram syndrome, a rare, recessive disorder characterized by early-onset, non-autoimmune diabetes mellitus, optic atrophy and further neurological and endocrinological abnormalities. The WFS1 gene encodes wolframin, a putative multispanning membrane glycoprotein of the endoplasmic reticulum. The function of wolframin is completely unknown. In order to characterize wolframin, we have generated polyclonal antibodies against both hydrophilic termini of the protein. Wolframin was found to be ubiquitously expressed with highest levels in brain, pancreas, heart and insulinoma beta-cell lines. Analysis of the structural features provides experimental evidence that wolframin contains nine transmembrane segments and is embedded in the membrane in an N(cyt)/C(lum) topology. Wolframin assembles into higher molecular weight complexes of approximately 400 kDa in the membrane. Pulse-chase experiments demonstrate that during maturation wolframin is N-glycosylated but lacks proteolytical processing. Moreover, N-glycosylation appears to be essential for the biogenesis and stability of wolframin. Here we investigate, for the first time, the molecular mechanisms that cause loss-of-function of wolframin in affected individuals. In patients harboring nonsense mutations complete absence of the mutated wolframin is caused by instability and rapid decay of WFS1 nonsense transcripts. In a patient carrying a compound heterozygous missense mutation, R629W, we found markedly reduced steady-state levels of wolframin. Pulse-chase experiments of mutant wolframin expressed in COS-7 cells indicated that the R629W mutation leads to instability and strongly reduced half-life of wolframin. Thus, the Wolfram syndrome in patients investigated here is caused by reduced protein dosage rather than dysfunction of the mutant wolframin.
Mitochondrial (mt)DNA haplogroups in a German control group (n = 67) were characterized by screening mitochondrial coding regions encompassing most of the ND, tRNA and cyt b genes. We used a PCR-SSCP screening approach followed by direct sequencing of polymorphic mtDNA fragments. Five major mtDNA lineages, diverging in at least nine different haplogroups, could be defined by characteristic polymorphic sites in mitochondrial genes. Additional sequencing of two hypervariable segments (HVS-I and II) of the non-coding displacement (D) loop in all control subjects revealed that certain D loop variants were strongly correlated with lineages and haplogroups, while others represented hotspots occurring frequently in different haplogroups. The existence of identified lineages and haplogroups received support from data in the literature, obtained by use of different approaches. Subsequently, we investigated four disease groups for association with these haplogroups: (i) LHON patients (n = 55) carrying at least one of the primary/intermediate LHON mutations at nt 3460, 11778, 14484 and/or 15257; (ii) patients suffering from Wolfram or DIDMOAD syndrome (n = 8); (iii) MELAS patients (n = 9); (iv) a group of children, who died from 'sudden infant death syndrome' (SIDS) (n = 9). The distribution patterns among the haplogroups of the disease groups (LHON, DIDMOAD and SIDS) differed considerably from the control population. LHON and DIDMOAD were significantly under-represented in the most frequent German haplogroup DC, but were concentrated in a mtDNA lineage defined by polymorphisms at nt 4216 + 11251 + 16126. As this lineage diverged into two precisely defined haplogroups, LHON and DIDMOAD could be assigned to the two haplogroups separately. Strikingly, SIDS was often found in association with two rare German haplogroups. MELAS patients were equally distributed among German haplogroups and, moreover, did not reveal any accumulation of specific D loop variants. We conclude that certain European mtDNA haplogroups define a genetic susceptibility basis for various disorders.
Mutations of SURF‐1, a gene located on chromosome 9q34, have recently been identified in patients affected by Leigh syndrome (LS), associated with deficiency of cytochrome c oxidase (COX), the terminal component of the mitochondrial respiratory chain. To investigate to what extent SURF‐1 is responsible for human disorders because of COX deficiency, we undertook sequence analysis of the SURF‐1 gene in 46 unrelated patients. We analyzed 24 COX‐defective patients classified as having typical Leigh syndrome (LSCOX), 6 patients classified as Leigh‐like (LLCOX) cases, and 16 patients classified as non‐LSCOX cases. Frameshift, stop, and splice mutations of SURF‐1 were detected in 18 of 24 (75%) of the LSCOX cases. No mutations were found in the LLCOX and non‐LSCOX group of patients. Rescue of the COX phenotype was observed in transfected cells from patients harboring SURF‐1 mutations, but not in transfected cell lines from 2 patients in whom no mutations were detected by sequence analysis. Loss of function of SURF‐1 protein is specifically associated with LSCOX, although a proportion of LSCOX cases must be the result of abnormalities in genes other than SURF‐1. SURF‐1 is the first nuclear gene to be consistently mutated in a major category of respiratory chain defects. DNA analysis can now be used to accurately diagnose LSCOX, a common subtype of Leigh syndrome. Ann Neurol 1999;46:161–166
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