Marie T. Lott

Myoclonic epilepsy and ragged-red fiber disease (MERRF) is associated with a mitochondrial DNA tRNALys mutation

An A to G transition mutation at nucleotide pair 8344 in human mitochondrial DNA (mtDNA) has been identified as the cause of MERRF. The mutation alters the T psi C loop of the tRNA(Lys) gene and creates a CviJI restriction site, providing a simple molecular diagnostic test for the disease. This mutation was present in three independent MERRF pedigrees and absent in 75 controls, altered a conserved nucleotide, and was heteroplasmic. All MERRF patients and their less-affected maternal relatives had between 2% and 27% wild-type mtDNAs and showed an age-related association between genotype and phenotype. This suggests that a small percentage of normal mtDNAs has a large protective effect on phenotype. This mutation provides molecular confirmation that some forms of epilepsy are the result of deficiencies in mitochondrial energy production.

An enhanced MITOMAP with a global mtDNA mutational phylogeny

The MITOMAP () data system for the human mitochondrial genome has been greatly enhanced by the addition of a navigable mutational mitochondrial DNA (mtDNA) phylogenetic tree of ∼3000 mtDNA coding region sequences plus expanded pathogenic mutation tables and a nuclear-mtDNA pseudogene (NUMT) data base. The phylogeny reconstructs the entire mutational history of the human mtDNA, thus defining the mtDNA haplogroups and differentiating ancient from recent mtDNA mutations. Pathogenic mutations are classified by both genotype and phenotype, and the NUMT sequences permits detection of spurious inclusion of pseudogene variants during mutation analysis. These additions position MITOMAP for the implementation of our automated mtDNA sequence analysis system, Mitomaster.

MITOMAP: a human mitochondrial genome database--2004 update.

MITOMAP (http://www.MITOMAP.org), a database for the human mitochondrial genome, has grown rapidly in data content over the past several years as interest in the role of mitochondrial DNA (mtDNA) variation in human origins, forensics, degenerative diseases, cancer and aging has increased dramatically. To accommodate this information explosion, MITOMAP has implemented a new relational database and an improved search engine, and all programs have been rewritten. System administrative changes have been made to improve security and efficiency, and to make MITOMAP compatible with a new automatic mtDNA sequence analyzer known as Mitomaster.

Mitochondrial DNA variation in human evolution and disease.

Analysis of mitochondrial DNA (mtDNA) variation has permitted the reconstruction of the ancient migrations of women. This has provided evidence that our species arose in Africa about 150000 years before present (YBP), migrated out of Africa into Asia about 60000 to 70000 YBP and into Europe about 40000 to 50000 YBP, and migrated from Asia and possibly Europe to the Americas about 20000 to 30000 YBP. Although much of the mtDNA variation that exists in modern populations may be selectively neutral, studies of the mildly deleterious mtDNA mutations causing Lebers hereditary optic neuropathy (LHON) have demonstrated that some continent-specific mtDNA lineages are more prone to manifest the clinical symptoms of LHON than others. Hence, all mtDNA lineages are not equal, which may provide insights into the extreme environments that were encountered by our ancient ancestor, and which may be of great importance in understanding the pathophysiology of mitochondrial disease.

Association of mitochondrial DNA damage with aging and coronary atherosclerotic heart disease.

The role of somatic mitochondrial DNA (mtDNA) damage in human aging and progressive diseases of oxidative phosphorylation (OXPHOS) was examined by quantitating the accumulation of mtDNA deletions in normal hearts and hearts with coronary atherosclerotic disease. In normal hearts, mtDNA deletions appeared after 40 and subsequently accumulated with age. The common 4977 nucleotide pair (np) deletion (mtDNA4977) reached a maximum of 0.007%, with the mtDNA7436 and mtDNA10,422 deletions appearing at the same time. In hearts deprived of mitochondrial substrates due to coronary artery disease, the level of the mtDNA4977 deletion was elevated 7-220-fold over age-matched controls, with the mtDNA7436 and mtDNA10,422 deletions increasing in parallel. This cumulative mtDNA damage was associated with a compensatory 3.5-fold induction of nuclear OXPHOS gene mRNA and regions of ischemic hearts subjected to the greatest work load (left ventricle) showed the greatest accumulation of mtDNA damage and OXPHOS gene induction. These observations support the hypothesis that mtDNA damage does accumulate with age and indicates that respiratory stress greatly elevates mitochondrial damage.

The Clinical Characteristics of Pedigrees of Leber's Hereditary Optic Neuropathy With the 11778 Mutation

In a study of the phenotypic characteristics of pedigrees of Lebers hereditary optic neuropathy positive for the mitochondrial DNA mutation at position 11778, 28 of 49 pedigrees were represented by singleton cases. Seven families, including six singleton pedigrees, had maternal family members with a mixture of mutant and normal mitochondrial DNA (heteroplasmy). Seventy-two affected individuals from 43 families showed a male predominance of 81.9% (59/72) and ages of onset of visual loss ranging from 8 to 60 years. The time interval between affected eyes averaged 1.8 months; the duration of progression of visual loss in each eye averaged 3.7 months. Visual acuity was 20/200 or worse in 107 of 109 (98.2%) eyes. Telangiectatic microangiopathy, disk pseudoedema, or vascular tortuosity, ophthalmoscopic features believed to be classic of Lebers hereditary optic neuropathy, were noted in 30 of 52 patients. Visual-evoked responses were typically absent or abnormal. Electrocardiograms, fluorescein angiograms, cerebrospinal fluid analyses, brain computed tomography, and magnetic resonance imaging were usually normal. There were no consistent neurologic or systemic illnesses associated with these Lebers pedigrees. In many cases, the diagnosis would not have been suspected because of the absence of a compatible family history, typical clinical profile, or ophthalmoscopic appearance. Genetic analysis showed the mitochondrial DNA mutation at position 11778, which established the diagnosis of Lebers hereditary optic neuropathy and has allowed for a broader view of the clinical features of this disease.

Mitochondrial DNA mutations in human degenerative diseases and aging.

A wide variety of mitochondrial DNA (mtDNA) mutations have recently been identified in degenerative diseases of the brain, heart, skeletal muscle, kidney and endocrine system. Generally, individuals inheriting these mitochondrial diseases are relatively normal in early life, develop symptoms during childhood, mid-life, or old age depending on the severity of the maternally-inherited mtDNA mutation; and then undergo a progressive decline. These novel features of mtDNA disease are proposed to be the product of the high dependence of the target organs on mitochondrial bioenergetics, and the cumulative oxidative phosphorylation (OXPHOS) defect caused by the inherited mtDNA mutation together with the age-related accumulation mtDNA mutations in post-mitotic tissues.

Mitochondrial DNA Diversity in Indigenous Populations of the Southern Extent of Siberia, and the Origins of Native American Haplogroups

In search of the ancestors of Native American mitochondrial DNA (mtDNA) haplogroups, we analyzed the mtDNA of 531 individuals from nine indigenous populations in Siberia. All mtDNAs were subjected to high‐resolution RFLP analysis, sequencing of the control‐region hypervariable segment I (HVS‐I), and surveyed for additional polymorphic markers in the coding region. Furthermore, the mtDNAs selected according to haplogroup/subhaplogroup status were completely sequenced. Phylogenetic analyses of the resulting data, combined with those from previously published Siberian arctic and sub‐arctic populations, revealed that remnants of the ancient Siberian gene pool are still evident in Siberian populations, suggesting that the founding haplotypes of the Native American A‐D branches originated in different parts of Siberia. Thus, lineage A complete sequences revealed in the Mansi of the Lower Ob and the Ket of the Lower Yenisei belong to A1, suggesting that A1 mtDNAs occasionally found in the remnants of hunting‐gathering populations of northwestern and northern Siberia belonged to a common gene pool of the Siberian progenitors of Paleoindians. Moreover, lineage B1, which is the most closely related to the American B2, occurred in the Tubalar and Tuvan inhabiting the territory between the upper reaches of the Ob River in the west, to the Upper Yenisei region in the east. Finally, the sequence variants of haplogroups C and D, which are most similar to Native American C1 and D1, were detected in the Ulchi of the Lower Amur. Overall, our data suggest that the immediate ancestors of the Siberian/Beringian migrants who gave rise to ancient (pre‐Clovis) Paleoindians have a common origin with aboriginal people of the area now designated the Altai‐Sayan Upland, as well as the Lower Amur/Sea of Okhotsk region.

Leber's hereditary optic neuropathy: a model for mitochondrial neurodegenerative diseases.

A number of human diseases have been attributed to defects in oxidative phosphorylation (OXPHOS) resulting from mutations in the mitochondrial DNA (mtDNA). One such disease is Lebers hereditary optic neuropathy (LHON), a neurodegenerative disease of young adults that results in blindness due to atrophy of the optic nerve. The etiology of LHON is genetically heterogeneous and in some cases multifactorial. Eleven mtDNA mutations have been associated with LHON, all of which are missense mutations in the subunit genes for the subunits of the electron transport chain complexes I, III, and IV. Molecular, biochemical, and population genetic studies have categorized these mutations as high risk (class I), low risk (class II), or intermediate risk (class I/II). Glass I mutations appear to be primary genetic causes of LHON, while class II mutations are frequently found associated with class I genotypes and may serve as exacerbating genetic factors. Different LHON pedigrees can harbor different combinations of class I, II, or I/II mtDNA mutations, as shown by the complete sequence analysis of the mtDNAs of four LHON probands. The various mtDNA genotypes included an isolated class I mutation, combined class I + II mutations, and combined class I/II + II mutations. The occurrence of such genotypes supports the hypothesis that LHON may result from the additive effects of various genetic and environmental insults to OXPHOS, each of which increases the probability of blindness.— Brown, M. D., Voljavec, A. S., Lott, M. T., MacDonald, I., Wallace, D. C. Lebers hereditary optic neuropathy: a model for mitochondrial neurodegenerative diseases. FASEB J. 6: 2791‐2799; 1992.

Subacute necrotizing encephalopathy Oxidative phosphorylation defects and the ATPase 6 point mutation

Subacute necrotizing encephalopathy (SNE) or Leighs disease is associated with various defects in oxidative phosphorylation (OXPHOS). However, the relationships between these OXPHOS defects and nuclear DNA or mitochondrial DNA (mtDNA) mutations is still unclear. We evaluated three SNE pedigrees (two singleton cases and a pedigree) biochemically for OXPHOS abnormalities and genetically for four mtDNA point mutations. There was a complex I defect in ail three pedigrees that was associated with a complex III defect in two individuals. An mtDNA mutation in the ATPase, subunit 6 gene (np 8993) was present in one SNE pedigree. This mutation was maternally inherited, heteroplasmic, produced marked clinical and biochemical heterogeneity between pedigree members, and varied along the maternai lineage at levels ranging from 0% to >95% of the total mtDNAs. These mtDNA mutations were not present in the other two pedigrees. These observations emphasize the importance of screening for OXPHOS defects and mtDNA mutations in SNE cases.