Mitochondrial diseases

Mitochondrial diseases, and particularly mitochondrial myopathies or encephalomyopathies, have drawn increasing attention in the past decade. Initially defined by morphologic changes in muscle ("ragged red fibers" and ultrastructural abnormalities of mitochondria), mitochondrial encephalomyopathies can now be classified according to biochemical defects involving: (1) mitochondrial transport; (2) substrate oxidation; (3) Krebs cycle; (4) respiratory chain; and (5) oxidation-phosphorylation coupling. For each biochemical group of disorders, the authors describe clinical presentations and biochemical findings. These disorders are especially interesting from the genetic point of view because mitochondria have their own DNA (mtDNA), which encodes 13 polypeptides, all of them subunits of respiratory chain complexes. Other mitochondrial proteins are encoded by nuclear DNA, synthesized in the cytoplasm, and imported into the mitochondria by a complex mechanism. Because mtDNA is inherited strictly by maternal, cytoplasmic inheritance, mitochondrial diseases can be transmitted by Mendelian or by non-Mendelian, maternal inheritance, as illustrated by human pathology.     

Mitochondrial diseases and epilepsy

The mitochondrial respiratory chain is the final common pathway for energy production. Defects affecting this pathway can give rise to disease that presents at any age and affects any tissue. However, irrespective of genetic defect, epilepsy is common and there is a significant risk of status epilepticus. This review summarizes our current understanding of the epilepsy that occurs in mitochondrial disease, focusing on three of the most common disorders: mitochondrial myopathy encephalopathy, lactic acidosis and stroke-like episodes (MELAS), myoclonus epilepsy and ragged-red fibers (MERRF), and polymerase gamma (POLG) related disease. In addition, we review the pathogenesis and possible treatment of these disorders.     

Mitochondrial diseases and status epilepticus

This narrative review focuses on the pathophysiology, diagnosis, and management of status epilepticus in the context of primary mitochondrial disease. Epilepsy is common in mitochondrial disease, reported in >20% of adult cases and 40%‐60% of pediatric cohorts. Status epilepticus is less frequently reported and appears to be associated with particular subgroups of mitochondrial disorders, namely defects of the mitochondrial DNA and its maintenance, and disorders of mitochondrial translation and dynamics. Mechanisms underlying mitochondrial status epilepticus are incompletely understood, and may include bioenergetic failure, oxidative stress, immune dysfunction, and impaired mitochondrial dynamics. Treatments tried in mitochondrial status epilepticus include antiepileptic drugs, anesthetic agents, magnesium, high‐dose steroids, immune globulins, vagus nerve stimulation, and surgical procedures, all with variable success. The outcome of mitochondrial status epilepticus is extremely poor, and effective therapeutic options have not been reported. Improved understanding of the mechanisms underpinning mitochondrial status epilepticus is needed in order to develop more effective treatments.     

Mitochondrial diseases: a nosological update

Mitochondrial diseases are disorders caused by impairment of the mitochondrial respiratory chain, characterized by clinical-genetic heterogeneity and frequent multisystemic involvement. It is difficult to establish a precise genotype/phenotype correlation and obtain a definitive nosology. Today's genetic classification distinguishes disorders caused by defects in the mitochondrial genome (sporadic or maternally-inherited) from disorders caused by defects in the nuclear genome (autosomally-inherited). We report an updated classification, briefly review the main clinical syndromes and describe the most recent genetic knowledge.     

Mitochondrial dysfunction in neurodegenerative diseases and the potential countermeasure

Mitochondria not only supply the energy for cell function, but also take part in cell signaling. This review describes the dysfunctions of mitochondria in aging and neurodegenerative diseases, and the signaling pathways leading to mitochondrial biogenesis (including PGC‐1 family proteins, SIRT1, AMPK) and mitophagy (parkin‐Pink1 pathway). Understanding the regulation of these mitochondrial pathways may be beneficial in finding pharmacological approaches or lifestyle changes (caloric restrict or exercise) to modulate mitochondrial biogenesis and/or to activate mitophagy for the removal of damaged mitochondria, thus reducing the onset and/or severity of neurodegenerative diseases.     

Mitochondrial respiratory chain dysfunction in various neuromuscular diseases.

The mitochondrial respiratory chain function and the occurrence of mitochondrial respiratory chain dysfunction were determined in various neuromuscular diseases. The mitochondrial complexes I-V and citrate synthase in the skeletal muscle taken from 75 orthopaedic surgical patients excluding neuromuscular diseases (control subjects) and 26 patients with various neuromuscular diseases (7 patients with Duchenne muscular dystrophy, 3 patients with spinal muscular atrophy, 6 patients with mitochondrial diseases, 7 patients with type II fibre atrophy and 3 patients with neuropathy) were assayed. Of 26 patients, results of analysis of 3 patients (1 Duchenne muscular dystrophy, 1 spinal muscular atrophy and 1 type II fibre atrophy) were excluded because the citrate synthase activities in their muscle homogenate were less than third percentile of the normal controls. As compared to the control subjects by using Student's t-test, all studied groups of patients had significantly lower activities of more than one or two mitochondrial complexes (p<0.05). However, a significantly higher activity of mitochondrial complex I was observed in patients with mitochondrial diseases (p<0.05). These findings will require further study to elucidate the pathogenesis and role of secondary mitochondrial respiratory chain dysfunction in such neuromuscular diseases.     

Mitochondrial Dysfunction and Biogenesis in Neurodegenerative diseases: Pathogenesis and Treatment

Neurodegenerative diseases are a heterogeneous group of disorders that are incurable and characterized by the progressive degeneration of the function and structure of the central nervous system (CNS) for reasons that are not yet understood. Neurodegeneration is the umbrella term for the progressive death of nerve cells and loss of brain tissue. Because of their high energy requirements, neurons are especially vulnerable to injury and death from dysfunctional mitochondria. Widespread damage to mitochondria causes cells to die because they can no longer produce enough energy. Several lines of pathological and physiological evidence reveal that impaired mitochondrial function and dynamics play crucial roles in aging and pathogenesis of neurodegenerative diseases. As mitochondria are the major intracellular organelles that regulate both cell survival and death, they are highly considered as a potential target for pharmacological‐based therapies. The purpose of this review was to present the current status of our knowledge and understanding of the involvement of mitochondrial dysfunction in pathogenesis of neurodegenerative diseases including Alzheimer's disease (AD), Parkinson's disease (PD), Huntington's disease (HD), and amyotrophic lateral sclerosis (ALS) and the importance of mitochondrial biogenesis as a potential novel therapeutic target for their treatment. Likewise, we highlight a concise overview of the key roles of mitochondrial electron transport chain (ETC.) complexes as well as mitochondrial biogenesis regulators regarding those diseases.     

Mitochondrial DNA A4336G mutation in Alzheimer's and Parkinson's diseases

OBJECTIVES: To determine whether the mitochondrial DNA (mtDNA) A4336G mutation represents a risk factor for Spanish patients with both Alzheimer's disease (AD) and Parkinson's disease (PD). MATERIAL AND METHODS: One hundred and sixty-one AD and 106 PD unrelated patients were included in the study. Seventy-eight age-matched and 144 randomly chosen healthy subjects served as controls. The frequency of the A4336G mutation in these groups was compared using the chi(2) and Fisher's exact tests. p < 0.05 was established as a statistically significant differential value. RESULTS: The mtDNA A4336G mutation was present in 1/161 of AD patients (0.6%), in 3/106 of PD patients (2.8%), in 1/78 of age-matched controls (1.3%) and in 2/144 of the randomly chosen controls (1.4%). These differences were not statistically significant. CONCLUSION: Our results do not support the hypothesis that this mutation represents a risk factor for either AD or PD patients, at least in the case of this Spanish sample.     

Mitochondrial diseases in childhood: a clinical approach to investigation and management

Mitochondrial diseases are a common cause of inherited neurological disorders in children. Although dysfunction of the central nervous system is prominent, multisystem involvement also occurs. Diagnosis relies on characteristic clinical features, an understanding of mitochondrial genetics, and a logical, informed approach to investigations. There is a significant body of recent literature on advances in mitochondrial genetics and the investigation of mitochondrial diseases. However, to our knowledge there remains a paucity of published information on the management of these disorders. Management of the complex constellation of neurological and multisystem clinical features is challenging, and is reliant on a multidisciplinary approach. The care of the child and family is dependent on clear communication between health professionals from primary, secondary, and tertiary care as well as specialist input from quaternary services. The aim of this review is to provide paediatric neurologists, paediatricians, and allied health professionals with a structured approach to the diagnosis and management of children with suspected or confirmed mitochondrial disease.     

Structural studies of parkin and sacsin: Mitochondrial dynamics in neurodegenerative diseases

Neurodegenerative diseases are prevalent, chronic diseases emanating from the dysfunction or death of neurons. The disrupted mitochondrial dynamics observed in a large number of neurodegenerative diseases suggests a common etiology with the possibility of therapies targeting multiple diseases. This review highlights the contributions of structural studies of disease‐related proteins to the understanding of neurodegenerative disease pathogenesis and especially the cellular events leading to disruptions in mitochondrial dynamics and function. The examples used are parkin and sacsin, two proteins linked respectively to autosomal‐recessive early‐onset PD and autosomal‐recessive spastic ataxia of Charlevoix‐Saguenay. Structural studies of parkin and sacsin explain the pathogenicity of a large number of disease‐associated mutations and reveal insights into their cellular functions related to mitochondrial dynamics. © 2015 International Parkinson and Movement Disorder Society     

Mitochondrial encephalomyopathy with autosomal dominant inheritance: A clinical and genetic entity of mitochondrial diseases

We report a Japanese family with chronic progressive external ophthal-moplegia (CPEO) with autosomal dominant inheritance, and review 54 reported CPEO patients in seven families (including the present family) with autosomal dominant inheritance and mtDNA deletions in the skeletal muscle. Mean age at onset in the CPEO was 26 years, which is older than that in published solitary cases. In addition to blepharoptosis and external ophthalmoplegia, proximal muscle atrophy and weakness were found in 62%, hearing loss in 25%, and ataxia in 17% of the patients. Retinal degeneration was not found, and cardiac involvement was very rare. mtDNA deletions in the muscle were multiple and large scale, and all such deletions were located in the non–D-loop region. Autosomal dominant CPEO has unique clinical features which differ from those of solitary CPEO, and is associated with multiple large-scale mtDNA deletions. Thus, autosomal dominant CPEO can be considered a clinical and genetic entity of mitochondrial diseases. © 1995 John Wiley & Sons, Inc.     

The Mitochondrial Genome And Human Mitochondrial Diseases

To date, more than 100 point mutations and several hundreds of structural rearrangements of mitochondrial DNA (mtDNA) are known too be connected with characteristic neuromuscular and other mitochondrial syndromes varying from those causing death at the neonatal stage to diseases with late ages of onset. The immediate cause of mitochondrial disorders is a defective oxidative phosphorylation. Wide phenotypic variation and the heteroplasmy phenomenon, which some authors include in mutation load, are characteristic of human mitochondrial diseases. As the numbers of cases identified and pedigrees described increase, data on the genotype-phenotype interaction and the structure and frequency of pathogenic and conditionally pathogenic mtDNA mutations in human populations are rapidly accumulated. The data on the genetics and epidemiology of mitochondrial diseases are not only important for differential diagnosis and genetic counseling. Since both neutral and mildly pathogenic mutations of mtDNA are progressively accumulated in maternal phyletic lines, molecular analysis of these mutations permits not only reconstruction of the genealogical tree of modern humans, but also estimation of the role that these mutations play in natural selection.     

Mitochondrial dysfunctions in neurodegenerative diseases:role in disease pathogenesis,strategies for analysis and therapeutic prospects

Fundamental organelles that occur in every cell type with the exception of mammal erythrocytes, the mitochondria are required for multiple pivotal processes that include the production of biological energy, the biosynthesis of reactive oxygen species, the control of calcium homeostasis, and the triggering of cell death. The disruption of anyone of these processes has been shown to impact strongly the function of all cells, but especially of neurons. In this review, we discuss the role of the mit...     

Mitochondrial Cytopathies

Mitochondrial cytopathies represent a heterogeneous group of multisystem disorders which preferentially affect the muscle and nervous systems. They are caused either by mutations in the maternally inherited mitochondrial genome, or by nuclear DNA-mutations. Today, approximately 200 different disease causing mutations of mitochondrial DNA (mtDNA) are known, and due to the increased knowledge about nuclear genetics during the last few years, more and more nuclear mutations are being described. Owing to the non-uniform distribution of mitochondria in tissues and the co-existence of mutated and wildtype mtDNA (heteroplasmy) in these organelles, these disorders may present with a huge variety of symptoms, even if the same mutation is involved. Diagnostic investigations should include the measurement of serum and CSF lactate, neuroradiological tests and a muscle biopsy to show the characteristic ragged-red fibres and cytochrome c oxidase deficient cells and also to provide material for genetic analysis. To date, the treatment of these diseases remains supportive and should focus on typical complications such as cardiac dysrhythmia and endocrinopathy. Received: 16 September 2002, Accepted: 30 September 2002 Correspondence to Janet Schmiedel, MD     

Mitochondrial encephalomyopathy

Summary We report the clinical and autopsy findings in a young man of 18 with a chronic progressive disorder comprised of lactic acidosis, mental deterioration, and epileptic seizures which were sometimes accompanied by stroke-like episodes with transient hemiparesis and cortical blindness. He died of congestive heart failure. The autopsy showed lesions of the gray matter of the brain. Both the putamen and parieto-occipital cortex showed loss of neurons and proliferation of macrophages, astrocytes and vessels. There was marked loss of neurons in the inferior olives, and slight reduction of the number of Purkinje cells. Skeletal muscle studies revealed ragged-red fibres and structurally abnormal mitochondria. The heart was enlarged: accumulations of mitochondria occurred in the muscle fibers. The liver exhibited marked fatty degeneration. Biochemical analyses showed normal activities of pyruvate dehydrogenase in thrombocytes, pyruvate carboxylase in lymphocytes, biotinidase in serum as well as succinate dehydrogenase and cytochrome c oxidase. The features of this disorder differ in many respects from cases of mitochondrial encephalomyopathy previously reported and cannot be assigned to any specific disease entity.Supported by grants from the First of May Flower Annual Campaign for Childrens Health and the Swedish Medical Research Council (proj no 07122)