Mitochondrial myopathies and the role of the pathologist in the molecular era

Mitochondrial encephalomyopathies are under increasing consideration in the differential diagnosis of diverse metabolic diseases from infancy to late adulthood. This is to be expected considering the vital importance of mitochondria to cellular respiration in all eukaryotes. the vulnerability of the mitochondrial genome to injury, and the expanding appreciation of the role of mitochondria as a common denominator in cell death in ischemia/anoxia, sepsis, and neurodegenerative diseases. Primary disease of the mitochondrial respiratory chain is estimated to occur with an incidence of between 6 and 16/100,000 individuals. Virtually all tissues have been shown to be involved in diverse mitochondriopathies, but none is more appropriate for diagnosis in most cases than skeletal muscle. The conventional histological and ultrastructural diagnosis of mitochondrial disease in muscle has been increasingly supplanted by the biochemical assessment of respiratory chain enzyme deficiencies and definitive genetic diagnosis. The use of such techniques has afforded a greater understanding for the relative lack of specificity of both light and electron microscopic observations. A review of the current situation by placing muscle pathology in the context of biochemical and genetic diagnosis serves as a paradigm for the role of the pathologist in the molecular era.     

Skeletal muscle mitochondrial defects in nonspecific neurologic disorders.

A group of 25 children (5 months to 20 years of age) presenting with intractable seizures, developmental delay, and severe hypotonia, who did not fall into the known categories of mitochondrial encephalomyopathies, underwent muscle biopsy for evaluation of mitochondrial function and were compared with age-matched control subjects. Biopsied skeletal muscle was analyzed for six mitochondrial enzyme-specific activities, mitochondrial DNA point mutations and deletions, and mitochondrial DNA levels. The data reveal a high incidence of specific mitochondrial enzyme activity defects. Reduced activity levels were evident in complex I (11 patients), III (24 patients), IV (nine patients), and V (10 patients). Two patients also exhibited pronounced reduction in mitochondrial DNA levels (80% reduction compared with control subjects). Two patients manifested increased levels of 5-kb and 7.4-kb mitochondrial DNA deletions. Pathogenic mutations previously described in association with mitochondrial encephalomyopathies were not evident. The data suggest that mitochondrial dysfunction, including extensive defects in specific enzyme activities, may be frequently present in children with seizures, developmental delay, and hypotonia that do not fall within the known mitochondrial encephalomyopathies. These mitochondrial deficiencies can be primarily ascertained by biochemical analysis and are rarely accompanied by mitochondrial ultrastructural changes. The molecular basis of these defects, their role in these disorders, and potential treatment warrant further study.     

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.     

Immunolabelling of mitochondrial superoxide dismutase and of Hsp60 in muscles harbouring a respiratory chain deficiency

In mitochondrial encephalomyopathies, impairment of the electron transfer chain may lead to overproduction of reduced oxygen species because oxygen consumption is decreased. Whether heat shock proteins (Hsp) are induced or not in mitochondria against oxidative stress is questionable. Muscle ragged-red fibres are the histological hallmark of most respiratory chain deficiencies in humans. They exhibit abnormal mitochondria which accumulate mainly under their sarcolemma. Within these fibres, immunolabelling demonstrated strong expression of mitochondrial manganese-dependent superoxide dismutase and a lack of expression of mitochondrial Hsp60 within the subsarcolemmal spaces. In contrast, Hsp60 was overexpressed within the intermyofibrillar mitochondria. These findings suggest enhanced generation and dismutation of superoxide anions and that processing and integration of imported precursor proteins is impaired within the subsarcolemmal mitochondrial aggregates of ragged-red fibres, whereas protein import and assembly may still be efficient in the intermyofibrillar mitochondria of these fibres.     

Activation of mitochondrial ATPase as evidence of loosely coupled oxidative phosphorylation in various skeletal muscle disorders. A histochemical fine-structural study

Combined histochemical and biochemical studies have shown, that the histochemical activity of mitochondrial Mg2+-activated ATPase closely correlates with the coupling state of oxidative phosphorylation (Meijer and Vloedman 1980). Using this histochemical method 646 unselected skeletal muscle biopsies have been investigated. Activation of the enzyme, i.e. loosely coupled mitochondria were present either focally or diffusely expressed in 28% of the biopsies irrespective of the underlying disorder. Most often it was found in mitochondrial myopathies and in progressive muscular dystrophy type Duchenne; in a lesser degree it was also present in neurogenic atrophy and in various other disorders. Ninety two percent of all cases with loose coupling showed mitochondrial proliferations. On the other hand in 20% of all cases with mitochondrial proliferations including 19 cases of diffuse mitochondrial myopathy and 3 of progressive external ophthalmoplegia no activation of the enzyme was found. The results show that loose coupling is closely but not absolutely associated with mitochondrial proliferation, it is present in mitochondrial myopathies but also in various other muscular disorders with different pathogenesis.     

Stem cell-derived mitochondria transplantation: A promising therapy for mitochondrial encephalomyopathy

Mitochondrial encephalomyopathies are disorders caused by mitochondrial and nuclear DNA mutations which affect the nervous and muscular systems. Current therapies for mitochondrial encephalomyopathies are inadequate and mostly palliative. However, stem cell-derived mitochondria transplantation has been demonstrated to play an key part in metabolic rescue, which offers great promise for mitochondrial encephalomyopathies. Here, we summarize the present status of stem cell therapy for mitochondrial encephalomyopathy and discuss mitochondrial transfer routes and the protection mechanisms of stem cells. We also identify and summarize future perspectives and challenges for the treatment of these intractable disorders based on the concept of mitochondrial transfer from stem cells.     

Mitochondrial encephalomyopathy and partial cytochrome c oxidase deficiency

A 52-year-old man had slowly progressive weakness and wasting of limb-muscles, sensorineural hearing loss, and complex partial seizures. CT showed cerebral atrophy, but he was not demented. Muscle biopsy showed ragged-red fibers and decreased histochemical stain for cytochrome c oxidase. Biochemical studies showed decreased cytochrome c oxidase activity in crude muscle extracts and in isolated mitochondria (44 and 30% of normal), while other mitochondrial enzymes were normal. A comparable decrease of immunologically reactive enzyme protein was shown by immunotitration with antibodies against human heart cytochrome c oxidase. Partial defects of cytochrome c oxidase may cause adult-onset, slowly progressive mitochondrial encephalomyopathies.     

线粒体脑肌病的血管神经病变机制

目的 探讨血管病变和组织缺血在线粒体脑肌病发病机制中的作用。方法 采用CT灌注成像技术对发病期线粒体脑肌病的脑组织灌注状况进行评估,通过病理学方法观察肌肉组织血管的线粒体结构改变。结果 7例不同类型的线粒体脑肌病患者发病期主要临床表现为卒中样发作和性发作,病变多累及单侧或双侧的顶颞枕叶。病变区域脑血流量和脑血容量降低,对比剂平均通过时间和达峰时间延长。病理学发现：琥珀酸脱氢酶（Succinate Dehydrogenase,SDH）染色血管壁呈不连续或浓重深染色,血管壁平滑肌细胞和内皮细胞线粒体数量显著增多,增大肿胀呈空泡状。结论 线粒体脑肌病是一种系统性血管病,脑组织灌注不足和代谢障碍在发病机制中具有重要的作用。     

Mitochondrial myopathies: morphological and biochemical studies in human muscle cultures

The mitochondrial myopathies are a heterogeneous group of disorders presumed to be caused by primary mitochondrial dysfunction with impairment of energy provision from oxidative metabolism. An increasing number of specific functional mitochondrial deficiencies have been documented and recently new strategies are beginning to analyze molecular and genetic mechanisms. Nevertheless these specific disorders have not been studied extensively in human muscle cultures. The objectives of our study were to reproduce morphological and biochemical changes in cultured myotubes of three Kearns-Sayre syndrome (KSS) patients to evidentiate a different mitochondrial susceptibility to 2-4 dinitrophenol (DNP) into normal and KSS muscle cultures, and to investigate the protective effect of ubidecarenone (Q10) on KSS myotubes exposed to DNP. In KSS cultures as compared to normal ones no abnormalities in growth pattern and differentiation were observed. KSS myotubes DNP exposed showed some abnormally large mitochondria with parallel-packed cristae and decrement in all mitochondrial enzymes activity ranging from 20 to 40%. In normal myotubes DNP exposed and in patient cultures DNP-Q10 treated a normal mitochondrial morphology and a recovery of enzymatic activity was found. In Complex I deficiency patient cultured myotubes cytochemical, immunocytochemical, ultrastructural and biochemical studies were performed and no abnormalities were found. Negative tissue culture findings could be explained by the fact that the defect cannot be reproduced in aneural cultures, and that there could be a gradual selection of cells containing a preponderance of wild type mitochondria over those that contain mutant mitochondria.     

Current and future aspects of mitochondrial diseases]

Though mitochondria have been a major source of energy production in eukaryotae since 15-20 billion years previously, existence of disorders due to primary abnormalities of their DNA has not been known until very recent years. In 1962, Luft et al reported the first case of such myopathy, and another case reported in 1967 by Shy et al was also the first case of generalized disorder with mitochondrial abnormalities. Since then, many case reports have followed including MELAS and other encephalomyopathies. Finally, in 1989, deletion of mitochondria DNA was found by Folt et al. Today, these disorders were able to be classified as follows: 1) LHON and A1555G type deafness as strictly limited non-syndromic type, 2) encephalomyopathies and their incomplete forms due to common and other deletions of mitochondria DNA, 3) encephalomyopathies and their incomplete forms including MIDD, diabetes mellituis, cardiomyopathy, deafness due to point mutations of mitochondria DNA related MELAS and others, 4) Neurodegenerative types including Parkinson's disease, Alzheimer's disease, cerebellar degeneration, and amyotrophic lateral sclerosis, or neurologic disorders mimic to such diseases, 5) Mitochondrial involvement not due to primary abnormalities of mitochondria DNA. Possible mechanisms were discussed, but sufficient knowledge is lacking so far to clarify pathophysiology of these disorders and the role of deleterious DNA in aging. Possible effective therapeutic strategies were also discussed, but further development of research works on these disorders in the 21st century are needed to answer these questions.     

Endothelial ultrastructural alterations of intramuscular capillaries in infantile mitochondrial cytopathies: “Mitochondrial angiopathy”

Electron microscopy (EM) is a reliable method for diagnosing mitochondrial diseases in striated muscle biopsy in infancy. Ultrastructural alterations in mitochondria of myofibers are well documented, but there are few studies of endothelial involvement in intramuscular capillaries. Quadriceps femoris biopsies of five representative infants and toddlers, ages neonate to 3.5 years, were performed because of clinical and laboratory data consistent with mitochondrial disease without mitochondrial DNA (mtDNA) mutations and likely with nuclear DNA mutations. Pathological studies included histochemistry, EM, respiratory chain enzymatic assay and mtDNA sequencing and deletion/duplication analysis. EM demonstrated frequent and severe alterations of mitochondria in capillary endothelium. The most constant changes included: either too few or fragmented cristae; stacked and whorled cristae; paracrystallin structures that often were large and spheroid with stress fractures; closely apposed membranes of granular endoplasmic reticulum surrounding mitochondria with loss of the normal intervening layer of cytoplasm; long narrow, thin looped microvilli extending into the lumen; and thick microvilli containing large, abnormal mitochondria. We conclude that mitochondrial cytopathies in early life exhibit more severe ultrastructural alterations in the endothelium than in myofibers and that paracrystallin body structure differs, perhaps due to less rigid surrounding structures. This distribution may explain the frequent lack of prominent histochemical and biochemical abnormalities in muscle biopsies of young patients. Endothelial changes do not distinguish the genetic defects. Vascular involvement in brain contributes to cerebral lesions and neuronal death by impairment of molecular and nutrient transport and ischemia; endothelium in muscle may reflect similar changes.     

Neuron-specific mitochondrial degeneration induced by hyperammonemia and octanoic acidemia

The neuropathological consequences of acute exposure to the neurotoxicants ammonia and octanoic acid were investigated with the isolated, perfused canine brain preparation. After 1 h of combined hyperammonemia and octanoic acidemia, ultrastructural changes were apparent in all brain regions examined. The cell bodies of neurons were the primary sites of these alterations. Neuronal mitochondria were distended, and the lamellae of the mitochondrial cristae were separated. In some cases the lamellae had completely dispersed, leaving only matrix remnants. Mitochondria of adjacent astrocytes appeared normal. Thus, a characteristic population of brain mitochondria is selectively vulnerable to a combination of hyperammonemia and octanoic acidemia and may be related to the biochemical mechanisms underlying encephalopathies of hepatic origin.     

Does the patient have a mitochondrial encephalomyopathy?

The ubiquitous nature of mitochondria, the dual genetic control of the respiratory chain, and the peculiar rules of mitochondrial genetics contribute to explain the extraordinary clinical heterogeneity of disorders associated with defects of oxidative phosphorylation (mitochondrial encephalomyopathies). To provide a practical approach to the diagnostic challenge posed by these conditions, we critically review the following criteria: (1) clinical presentation; (2) family history; (3) laboratory data; (4) neuroradiologic patterns; (5) standardized exercise testing; (6) muscle morphology; (7) muscle biochemistry; and (8) molecular genetic screening. Judicious sequential application of these tools should provide help in recognizing patients with mitochondrial disease and define the biochemical and molecular basis of the disorder for each patient. This knowledge is indispensable for accurate genetic counseling and prenatal diagnosis and is a prerequisite for the development of rational therapies, which are still woefully inadequate.     

Pathology of mitochondrial encephalomyopathies

Muscle biopsy provides the best tissue to confirm a mitochondrial cytopathy. Histochemical features often correlate with specific syndromes and facilitate the selection of biochemical and genetic studies. Ragged-red fibres nearly always indicate a combination defect of respiratory complexes I and IV. Increased punctate lipid within myofibers is a regular feature of Kearns-Sayre and PEO, but not of MELAS and MERRF. Total deficiency of succinate dehydrogenase indicates a severe defect in Complex II; total absence of cytochrome-c-oxidase activity in all myofibres correlates with a severe deficiency of Complex IV or of coenzyme-Q10. The selective loss of cytochrome-c-oxidase activity in scattered myofibers, particularly if accompanied by strong succinate dehydrogenase staining in these same fibres, is good evidence of mitochondrial cytopathy and often of a significant mtDNA mutation, though not specific for Complex IV disorders. Glycogen may be excessive in ragged-red zones. Ultrastructure provides morphological evidence of mitochondrial cytopathy, in axons and endothelial cells as well as myocytes. Abnormal axonal mitochondria may contribute to neurogenic atrophy of muscle, a secondary chronic feature. Quantitative determinations of respiratory chain enzyme complexes, with citrate synthase as an internal control, confirm the histochemical impressions or may be the only evidence of mitochondrial disease. Biological and technical artifacts may yield falsely low enzymatic activities. Genetic studies screen common point mutations in mtDNA. The brain exhibits characteristic histopathological alterations in mitochondrial diseases. Skin biopsy is useful for mitochondrial ultrastructure in smooth erector pili muscles and axons; skin fibroblasts may be grown in culture. Mitochondrial alterations occur in many nonmitochondrial diseases and also may be induced by drugs and toxins.     

Mitochondrial Morphology and Intracellular Calcium Homeostasis in Cytochrome Oxidase-Deficient Human Fibroblasts

Mitochondrial encephalomyopathies arise from mutations in the mitochondrial or nuclear genome and result in defective energy metabolism. Investigation of cellular pathophysiology in these disorders has been limited to nonneuronal explant cultures such as fibroblasts and myoblasts. While investigating mitochondrial structure and function in fibroblasts obtained from control and cytochrome oxidase-deficient (COX) patients, we observed possible abnormalities by vital dye confocal microscopy. Most notable were swelling, reticulation (e.g., intricate fusion of mitochondria), and proliferation of mitochondria. However, a detailed quantitative comparison of mitochondrial morphology in age-, sex-, and passage-matched cultures revealed no significant differences between control and cytochrome oxidase-deficient fibroblasts, nor any differences with passage. In addition, COX fibroblasts exhibited no obvious impairment of intracellular calcium handling, measured by fura-2. These results indicate that cytochrome oxidase deficiency, at the level in these cultures, does not produce structural or ionic concentration alterations in fibroblasts. Future investigation of the pathophysiology of this respiratory chain disorder may require excitable tissue.     

Neurological disorders due to mutations of the mitochondrial genome.

The rapidly expanding list of human diseases due to lesions of mitochondrial DNA includes myopathies, encephalopathies, cardiomyopathies, or various combinations of the latter, leading to multisystem disorders, which can also affect visceral organs. Five maternally inherited diseases, mainly affecting muscle and brain, are due to point mutations of mitochondrial genes encoding either respiratory chain polypeptides or transfer RNAs. On the other hand, three sporadic entities, Chronic Progressive External Ophthalmoplegia, Kearns-Sayre syndrome, and Pearson's pancreas-bone marrow syndrome, are due to single large-scale deletions of mitochondrial DNA. In addition, multiple deletions are the molecular hallmark of familial encephalomyopathies, inherited as either autosomal dominant or autosomal recessive traits. Finally, tissue-specific depletion of mitochondrial DNA was found in an autosomal recessive disease affecting either muscle, liver, kidney, or a combination of the three. Point mutations and slipped mispairing during, or impairment of, mitochondrial replication are likely mechanisms involved in the pathogenesis of these lesions.     

Vascular pathology in chronic progressive external ophthalmoplegia with ragged-red fibers]

Vascular involvement in biopsied muscle specimens from 11 patients with chronic progressive external ophthalmoplegia (CPEO) with ragged-red fibers (RRF) was studied. Almost none of 69 intramuscular arteries examined were strongly stained with succinate dehydrogenase (SDH) except one patient who had 2 SSV (strongly SDH-reactive blood vessels) in his muscle biopsy. Although RRF and focal cytochrome c oxidase (CCO) deficiency in muscle fibers were the common histochemical changes in muscle biopsy specimens from CPEO patients, all mitochondria in both endothelial and smooth muscle cells of the arteries had normal morphology except for the two SSV and all mitochondria in the blood vessels had normal CCO activity by electron cytochemistry. The findings obtained from the present study were quite different from those in mitochondrial myopathy, encephalopathy, lactic acidosis, and stroke-like episodes (MELAS), and myoclonus epilepsy associated with ragged-red fibers (MERRF) in which the striking vascular involvement with SSV is the most common and major abnormality in muscle biopsy specimens. To study vascular involvement in mitochondrial encephalomyopathies is the one of very important clues to understand the pathophysiology of phenotypic expressions in mitochondrial encephalomyopathies.     

线粒体脑肌病的临床与病理

目的探讨线粒体脑肌病的临床与肌肉病理特点。方法对16例肌活检证实的线粒体脑肌病病例的临床表现、肌肉组织化学及超微结构进行分析。结果16例患者破碎红纤维(RRF)的平均比例为5.9%,11例有中央核增多,13例的SDH/CCO双染示12例有蓝纤维,且与RRF的分布一致。超微结构观察有4例找到典型晶格状包涵体。结论SDH/CCO双染有蓝纤维为线粒体肌病的诊断提供了依据,借此可与其他肌病鉴别。