Your search keyword '"Rosa, Hannah S."' showing total 4 results

1. Pathological mechanisms underlying single large‐scale mitochondrial DNA deletions

Author

Rocha, Mariana C., Rosa, Hannah S., Grady, John P., Blakely, Emma L., He, Langping, Romain, Nadine, Haller, Ronald G., Newman, Jane, McFarland, Robert, Ng, Yi Shiau, Gorman, Grainne S., Schaefer, Andrew M., Tuppen, Helen A., Taylor, Robert W., and Turnbull, Doug M.

Subjects

Adult, Male, Electron Transport Complex I, Mitochondrial Diseases, Biopsy, Muscle Fibers, Skeletal, Gene Dosage, Middle Aged, DNA, Mitochondrial, Oxidative Phosphorylation, Cohort Studies, Electron Transport Complex IV, Young Adult, Humans, Female, Muscle, Skeletal, Research Articles, Gene Deletion, Research Article, Aged, Sequence Deletion

Abstract

Objective Single, large‐scale deletions in mitochondrial DNA (mtDNA) are a common cause of mitochondrial disease. This study aimed to investigate the relationship between the genetic defect and molecular phenotype to improve understanding of pathogenic mechanisms associated with single, large‐scale mtDNA deletions in skeletal muscle. Methods We investigated 23 muscle biopsies taken from adult patients (6 males/17 females with a mean age of 43 years) with characterized single, large‐scale mtDNA deletions. Mitochondrial respiratory chain deficiency in skeletal muscle biopsies was quantified by immunoreactivity levels for complex I and complex IV proteins. Single muscle fibers with varying degrees of deficiency were selected from 6 patient biopsies for determination of mtDNA deletion level and copy number by quantitative polymerase chain reaction. Results We have defined 3 “classes” of single, large‐scale deletion with distinct patterns of mitochondrial deficiency, determined by the size and location of the deletion. Single fiber analyses showed that fibers with greater respiratory chain deficiency harbored higher levels of mtDNA deletion with an increase in total mtDNA copy number. For the first time, we have demonstrated that threshold levels for complex I and complex IV deficiency differ based on deletion class. Interpretation Combining genetic and immunofluorescent assays, we conclude that thresholds for complex I and complex IV deficiency are modulated by the deletion of complex‐specific protein‐encoding genes. Furthermore, removal of mt‐tRNA genes impacts specific complexes only at high deletion levels, when complex‐specific protein‐encoding genes remain. These novel findings provide valuable insight into the pathogenic mechanisms associated with these mutations. Ann Neurol 2018;83:115–130

Published

2018

2. Dysferlin mutations and mitochondrial dysfunction

Author

Vincent, Amy E., Rosa, Hannah S., Alston, Charlotte L., Grady, John P., Rygiel, Karolina A., Rocha, Mariana C., Barresi, Rita, Taylor, Robert W., and Turnbull, Doug M.

Subjects

Adult, Male, Adolescent, Immunofluorescence, Clinical Neurology, Fluorescent Antibody Technique, Laser Capture Microdissection, DNA, Mitochondrial, Polymerase Chain Reaction, Article, Young Adult, Humans, Genetics(clinical), Pediatrics, Perinatology, and Child Health, Histochemistry, Muscle, Skeletal, Dysferlin, Middle Aged, Mitochondria, Mitochondria, Muscle, Distal Myopathies, Muscular Atrophy, Neurology, Muscular Dystrophies, Limb-Girdle, Mutation, Female, Cytochrome c oxidase deficiency, LGMD2B

Abstract

Highlights • Complex I deficiency is higher in patients with DYSF mutations than controls. • Complex IV deficiency is higher in patients with DYSF mutations than controls. • DYSF mutations may alter Ca++ buffering causing respiratory chain deficiency. • No evidence of mitochondrial DNA deletions detected in dysferlin patients., Dysferlinopathies are caused by mutations in the DYSF gene and patients may present with proximal or distal myopathy. Dysferlin is responsible for membrane resealing, and mutations may result in a defect in membrane repair following mechanical or chemical stress, causing an influx of Ca2+. Since mitochondria are involved in Ca2+ buffering, we hypothesised that mitochondrial defects may be present in skeletal muscle biopsies from patients with mutations in this gene. The aim was to characterise mitochondrial defects in muscle from patients with dysferlinopathies. Here, we analysed skeletal muscle biopsies for eight patients by quadruple immunofluorescent assay to assess oxidative phosphorylation protein abundance. Long-range PCR in single muscle fibres was used to look for presence of clonally expanded large-scale mitochondrial DNA rearrangements in patients' skeletal muscle (n = 3). Immunofluorescence demonstrated that the percentage of complex I- and complex IV-deficient fibres was higher in patients with DYSF mutations than in age-matched controls. No clonally expanded mtDNA deletions were detected using long-range PCR in any of the analysed muscle fibres. We conclude that complex I and complex IV deficiency is higher in patients than age matched controls but patients do not have rearrangements of the mtDNA. We hypothesise that respiratory chain deficiency may be the results of an increased cytosolic Ca2+ concentration (due to a membrane resealing defect) causing mitochondrial aberrations.

Published

2016

3. Sub-cellular origin of mtDNA deletions in human skeletal muscle

Author

Vincent, Amy E., Rosa, Hannah S., Pabis, Kamil, Lawless, Conor, Chen, Chun, Grunewald, Anne, Rygiel, Karolina A., Rocha, Mariana C., Reeve, Amy K., Falkous, Gavin, Perissi, Vanessa, White, Kathryn, Davey, Tracey, Petrof, Basil J., Sayer, Avan Aihie, Cooper, Cyrus, Deehan, David, Taylor, Robert W., Turnbull, Douglass M., and Picard, Martin

Published

2018

4. Subcellular origin of mitochondrial DNA deletions in human skeletal muscle

Author

Vincent, Amy E., Rosa, Hannah S., Pabis, Kamil, Lawless, Conor, Chen, Chun, Anne Grünewald, Rygiel, Karolina A., Rocha, Mariana C., Reeve, Amy K., Falkous, Gavin, Perissi, Valentina, White, Kathryn, Davy, Tracey, Petrof, Basil J., Sayer, Avan A., Cooper, Cyrus, Deehan, David, Taylor, Robert W., Turnbull, Doug M., and Picard, Martin

Subjects

Aging, muscle, Muscle Fibers, Skeletal, mitochondrial DNA, respiratory chain deficiency, Biochemistry, biophysics & molecular biology [F05] [Life sciences], DNA, Mitochondrial, mitochondria, Humans, Biochimie, biophysique & biologie moléculaire [F05] [Sciences du vivant], Muscle, Skeletal, Gene Deletion, Research Articles, Subcellular Fractions, Research Article

Abstract

Objective In patients with mitochondrial DNA (mtDNA) maintenance disorders and with aging, mtDNA deletions sporadically form and clonally expand within individual muscle fibers, causing respiratory chain deficiency. This study aimed to identify the sub‐cellular origin and potential mechanisms underlying this process. Methods Serial skeletal muscle cryosections from patients with multiple mtDNA deletions were subjected to subcellular immunofluorescent, histochemical, and genetic analysis. Results We report respiratory chain–deficient perinuclear foci containing mtDNA deletions, which show local elevations of both mitochondrial mass and mtDNA copy number. These subcellular foci of respiratory chain deficiency are associated with a local increase in mitochondrial biogenesis and unfolded protein response signaling pathways. We also find that the commonly reported segmental pattern of mitochondrial deficiency is consistent with the three‐dimensional organization of the human skeletal muscle mitochondrial network. Interpretation We propose that mtDNA deletions first exceed the biochemical threshold causing biochemical deficiency in focal regions adjacent to the myonuclei, and induce mitochondrial biogenesis before spreading across the muscle fiber. These subcellular resolution data provide new insights into the possible origin of mitochondrial respiratory chain deficiency in mitochondrial myopathy. Ann Neurol 2018;84:289–301

Published

2018