Abstract
Mitochondria play essential roles in numerous metabolic pathways including the synthesis of adenosine triphosphate through oxidative phosphorylation. Clinically, mitochondrial diseases occur when there is mitochondrial dysfunction – manifesting at any age and affecting any organ system; tissues with high energy requirements, such as muscle and the brain, are often affected. The clinical heterogeneity is parallel to the degree of genetic heterogeneity associated with mitochondrial dysfunction. Around 10% of human genes are predicted to have a mitochondrial function, and defects in over 300 genes are reported to cause mitochondrial disease. Some involve the mitochondrial genome (mtDNA), but the vast majority occur within the nuclear genome. Except for a few specific genetic defects, there remains no cure for mitochondrial diseases, which means that a genetic diagnosis is imperative for genetic counselling and the provision of reproductive options for at‐risk families. Next‐generation sequencing strategies, particularly exome and whole‐genome sequencing, have revolutionised mitochondrial diagnostics such that the traditional muscle biopsy has largely been replaced with a minimally‐invasive blood sample for an unbiased approach to genetic diagnosis. Where these genomic approaches have not identified a causative defect, or where there is insufficient support for pathogenicity, additional functional investigations are required. The application of supplementary ‘omics’ technologies, including transcriptomics, proteomics, and metabolomics, has the potential to greatly improve diagnostic strategies. This review aims to demonstrate that whilst a molecular diagnosis can be achieved for many cases through next‐generation sequencing of blood DNA, the use of patient tissues and an integrated, multidisciplinary multi‐omics approach is pivotal for the diagnosis of more challenging cases. Moreover, the analysis of clinically relevant tissues from affected individuals remains crucial for understanding the molecular mechanisms underlying mitochondrial pathology. © 2021 The Authors. The Journal of Pathology published by John Wiley & Sons, Ltd. on behalf of The Pathological Society of Great Britain and Ireland.
Highlights
Mitochondria are dynamic, intracellular organelles that mediate several key cellular functions, including apoptosis and calcium signalling, but importantly provide the primary source of cellular energy in the form of adenosine triphosphate (ATP) through oxidative phosphorylation (OXPHOS) [1]
The overwhelming majority of mitochondrial proteins are encoded within the nuclear genome, 13 polypeptides – and the 22 mt-tRNA and 2 mt-rRNAs genes required for their translation – are encoded by mtDNA
Mitochondrial disease can manifest at any point in life, with clinical symptoms ranging from isolated symptoms, such as diabetes or exercise intolerance, to multi-system involvement, such as Leigh syndrome [3]; MELAS syndrome [4]; Alpers syndrome, where the brain and liver are simultaneously affected [5]; or Pearson syndrome, characterised by sideroblastic anaemia and pancreatic dysfunction [6]
Summary
Mitochondria are dynamic, intracellular organelles that mediate several key cellular functions, including apoptosis and calcium signalling, but importantly provide the primary source of cellular energy in the form of adenosine triphosphate (ATP) through oxidative phosphorylation (OXPHOS) [1]. Mitochondrial disease can manifest at any point in life, with clinical symptoms ranging from isolated symptoms, such as diabetes or exercise intolerance, to multi-system involvement, such as Leigh syndrome (characterised by symmetrical lesions affecting the basal ganglia, thalamus, and brainstem, and associated with developmental regression) [3]; MELAS syndrome (the acronym derived from the hallmark features – Mitochondrial Encephalopathy, Lactic Acidosis and Stroke-like episodes) [4]; Alpers syndrome, where the brain and liver are simultaneously affected [5]; or Pearson syndrome, characterised by sideroblastic anaemia and pancreatic dysfunction [6] This clinical heterogeneity often makes the diagnosis of mitochondrial disease challenging and is further compounded by the vast genetic heterogeneity
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