Your search keyword '"Vincent, Amy E."' showing total 3 results

1. Automated quantitative high-throughput multiplex immunofluorescence pipeline to evaluate OXPHOS defects in formalin-fixed human prostate tissue.

Author

Sachdeva, Ashwin, Hart, Claire A., Carey, Christopher D., Vincent, Amy E., Greaves, Laura C., Heer, Rakesh, Oliveira, Pedro, Brown, Michael D., Clarke, Noel W., and Turnbull, Doug M.

Subjects

OXIDATIVE phosphorylation, PROSTATE, IMMUNOFLUORESCENCE, MULTISPECTRAL imaging, ELECTRON transport, IMAGE analysis, CELL metabolism

Abstract

Advances in multiplex immunofluorescence (mIF) and digital image analysis has enabled simultaneous assessment of protein defects in electron transport chain components. However, current manual methodology is time consuming and labour intensive. Therefore, we developed an automated high-throughput mIF workflow for quantitative single-cell level assessment of formalin fixed paraffin embedded tissue (FFPE), leveraging tyramide signal amplification on a Ventana Ultra platform coupled with automated multispectral imaging on a Vectra 3 platform. Utilising this protocol, we assessed the mitochondrial oxidative phosphorylation (OXPHOS) protein alterations in a cohort of benign and malignant prostate samples. Mitochondrial OXPHOS plays a critical role in cell metabolism, and OXPHOS perturbation is implicated in carcinogenesis. Marked inter-patient, intra-patient and spatial cellular heterogeneity in OXPHOS protein abundance was observed. We noted frequent Complex IV loss in benign prostate tissue and Complex I loss in age matched prostate cancer tissues. Malignant regions within prostate cancer samples more frequently contained cells with low Complex I & IV and high mitochondrial mass in comparison to benign–adjacent regions. This methodology can now be applied more widely to study the frequency and distribution of OXPHOS alterations in formalin-fixed tissues, and their impact on long-term clinical outcomes. [ABSTRACT FROM AUTHOR]

Published

2022

2. Mitochondrial dysfunction in myofibrillar myopathy

Author

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

Subjects

Neurology, Immunofluorescence, Clinical Neurology, Myofibrillar myopathy, Genetics(clinical), Pediatrics, Perinatology, and Child Health, Histochemistry, Cytochrome c oxidase deficiency, Mitochondrial DNA deletion, Mitochondria

Abstract

Myofibrillar myopathies (MFM) are characterised by focal myofibrillar destruction and accumulation of myofibrillar elements as protein aggregates. They are caused by mutations in the DES, MYOT, CRYAB, FLNC, BAG3, DNAJB6 and ZASP genes as well as other as yet unidentified genes. Previous studies have reported changes in mitochondrial morphology and cellular positioning, as well as clonally-expanded, large-scale mitochondrial DNA (mtDNA) deletions and focal respiratory chain deficiency in muscle of MFM patients. Here we examine skeletal muscle from patients with desmin (n = 6), ZASP (n = 1) and myotilin (n = 2) mutations and MFM protein aggregates, to understand how mitochondrial dysfunction may contribute to the underlying mechanisms causing disease pathology. We have used a validated quantitative immunofluorescent assay to study respiratory chain protein levels, together with oxidative enzyme histochemistry and single cell mitochondrial DNA analysis, to examine mitochondrial changes. Results demonstrate a small number of clonally-expanded mitochondrial DNA deletions, which we conclude are due to both ageing and disease pathology. Further to this we report higher levels of respiratory chain complex I and IV deficiency compared to age matched controls, although overall levels of respiratory deficient muscle fibres in patient biopsies are low. More strikingly, a significantly higher percentage of myofibrillar myopathy patient muscle fibres have a low mitochondrial mass compared to controls. We concluded this is mechanistically unrelated to desmin and myotilin protein aggregates; however, correlation between mitochondrial mass and muscle fibre area is found. We suggest this may be due to reduced mitochondrial biogenesis in combination with muscle fibre hypertrophy.

Published

2016

3. 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