A Brief History of Mitochondrial Pathologies.

The history of "mitochondrial pathologies", namely genetic pathologies affecting mitochondrial metabolism because of mutations in nuclear DNA-encoded genes for proteins active inside mitochondria or mutations in mitochondrial DNA-encoded genes, began in 1988. In that year, two different groups of researchers discovered, respectively, large-scale single deletions of mitochondrial DNA (mtDNA) in muscle biopsies from patients with "mitochondrial myopathies" and a point mutation in the mtDNA gene for subunit 4 of NADH dehydrogenase (MTND4), associated with maternally inherited Leber's hereditary optic neuropathy (LHON). Henceforth, a novel conceptual "mitochondrial genetics", separate from mendelian genetics, arose, based on three features of mtDNA: (1) polyplasmy; (2) maternal inheritance; and (3) mitotic segregation. Diagnosis of mtDNA-related diseases became possible through genetic analysis and experimental approaches involving histochemical staining of muscle or brain sections, single-fiber polymerase chain reaction (PCR) of mtDNA, and the creation of patient-derived "cybrid" (cytoplasmic hybrid) immortal fibroblast cell lines. The availability of the above-mentioned techniques along with the novel sensitivity of clinicians to such disorders led to the characterization of a constantly growing number of pathologies. Here is traced a brief historical perspective on the discovery of autonomous pathogenic mtDNA mutations and on the related mendelian pathology altering mtDNA integrity.

Charles Darwin and the Dentists.

Charles Darwin suffered relapsing, debilitating illness for most of his adult life with many symptoms. His most prominent complaints were episodic nausea, retching and vomiting. As is common in patients with repeated vomiting he developed dental problems, problems that may be dated back to his voyage on the Beagle and his vomiting due to persistent seasickness. Dental problems continued after the voyage and he was one of the first patients to have extractions under chloroform. Watching a dental procedure caused Darwin great distress, much as surgical and obstetric procedures had previously caused him distress with onset of symptoms. Darwin's dental experiences are consistent with the proposed diagnosis of his lifetime illness- patients with similar illnesses today have much the same dental problems. Dentists also helped Darwin with his researches and collection of specimens. In Darwin's day, dentists, like country clergymen, had time to follow other interests. Dentists contributed to Darwin's dental health, to the dental health of his family and to Darwin's work and biological studies. Dentists, in their own right, were also prominent in developing our biological understanding.

Mitochondrial Toxicity.

Recent decades have seen a rapid increase in reported toxic effects of drugs and pollutants on mitochondria. Researchers have also documented many genetic differences leading to mitochondrial diseases, currently reported to affect ∼1 person in 4,300, creating a large number of potential gene-environment interactions in mitochondrial toxicity. We briefly review this history, and then highlight cutting-edge areas of mitochondrial research including the role of mitochondrial reactive oxygen species in signaling; increased understanding of fundamental biological processes involved in mitochondrial homeostasis (DNA maintenance and mutagenesis, mitochondrial stress response pathways, fusion and fission, autophagy and biogenesis, and exocytosis); systemic effects resulting from mitochondrial stresses in specific cell types; mitochondrial involvement in immune function; the growing evidence of long-term effects of mitochondrial toxicity; mitochondrial-epigenetic cross-talk; and newer approaches to test chemicals for mitochondrial toxicity. We also discuss the potential importance of hormetic effects of mitochondrial stressors. Finally, we comment on future areas of research we consider critical for mitochondrial toxicology, including increased integration of clinical, experimental laboratory, and epidemiological (human and wildlife) studies; improved understanding of biomarkers in the human population; and incorporation of other factors that affect mitochondria, such as diet, exercise, age, and nonchemical stressors.

Charles Darwin's mitochondria.

Charles Darwin's long-term illness has been the subject of much speculation. His numerous symptoms have led to conclusions that his illness was essentially psychogenic in nature. These diagnoses have never been fully convincing, however, particularly in regard to the proposed underlying psychological background causes of the illness. Similarly, two proposed somatic causes of illness, Chagas disease and arsenic poisoning, lack credibility and appear inconsistent with the lifetime history of the illness. Other physical explanations are simply too incomplete to explain the range of symptoms. Here, a very different sort of explanation will be offered. We now know that mitochondrial mutations producing impaired mitochondrial function may result in a wide range of differing symptoms, including symptoms thought to be primarily psychological. Examination of Darwin's maternal family history supports the contention that his illness was mitochondrial in nature; his mother and one maternal uncle had strange illnesses and the youngest maternal sibling died of an infirmity with symptoms characteristic of mitochondrial encephalomyopathy, lactic acidosis, and stroke-like episodes (MELAS syndrome), a condition rooted in mitochondrial dysfunction. Darwin's own symptoms are described here and are in accord with the hypothesis that he had the mtDNA mutation commonly associated with the MELAS syndrome.

A history of mitochondrial diseases.

This articles reviews the development of mitochondrial medicine from the premolecular era (1962-1988), when mitochondrial diseases were defined on the basis of clinical examination, muscle biopsy, and biochemical criteria, through the molecular era, when the full complexity of these disorders became evident. In a chronological order, I have followed the introduction of new pathogenic concepts that have shaped a rational genetic classification of these clinically heterogeneous disorders. Thus, mitochondrial DNA (mtDNA)-related diseases can be divided into two main groups: those that impair mitochondrial protein synthesis in toto, and those that affect specific respiratory chain proteins. Mutations in nuclear DNA can affect components of respiratory chain complexes (direct hits) or assembly proteins (indirect hits), but they can also impair mtDNA integrity (multiple mtDNA mutations), replication (mtDNA depletion), or mtDNA translation. Besides these disorders that affect the respiratory chain directly, defects in other mitochondrial functions may also affect oxidative phosphorylation, including problems in mitochondrial protein import, alterations of the inner mitochondrial membrane lipid composition, and defects of mitochondrial dynamics. The enormous and still ongoing progress in our understanding of mitochondrial medicine was made possible by the intense collaboration of an international cadre of "mitochondriacs." Having published my first paper on a patient with mitochondrial myopathy 37 years ago (DiMauro et al., 1973), I feel qualified to write a history of the mitochondrial diseases, a fascinating, still evolving, and continuously puzzling area of medicine. In each section, I follow a chronological order of the salient discoveries and I show only the portraits of distinguished deceased mitochondriacs and those whose names became eponyms of mitochondrial diseases.

Historical perspective on mitochondrial medicine.

In this review, we trace the origins and follow the development of mitochondrial medicine from the premolecular era (1962-1988) based on clinical clues, muscle morphology, and biochemistry into the molecular era that started in 1988 and is still advancing at a brisk pace. We have tried to stress conceptual advances, such as endosymbiosis, uniparental inheritance, intergenomic signaling and its defects, and mitochondrial dynamics. We hope that this historical review also provides an update on mitochondrial medicine, although we fully realize that the speed of progress in this area makes any such endeavor akin to writing on water.

[Giuseppe Attardi: mitochondrial genetic system and its influence in the study of the mitochondrial diseases]. / Giuseppe Attardi: sistema genético mitocondrial y su influencia en las enfermedades neuromusculares mitocondriales.

AIM: To describe the scientific contributions and biography of Giuseppe Attardi (1923-2008), in particular his work on the human mitochondrial genetic system of crucial importance for the discovery and understanding of the mechanisms that produce the mitochondrial diseases. DEVELOPMENT: Giuseppe Attardi was an Italian-born medical doctor that worked with outstanding researchers as James Watson, Francois Jacob, and Renato Dulbecco, all Nobel Prizes of Medicine until 1963 that was promoted to Professor of the California Institute of Technology in Pasadena (USA). In 1967 discovered the human mitochondrial RNA, a little later the mitochondrial ribosomes and proteins encoded in the genome, in 1981 showed the genetic and transcription map of the mitochondrial DNA, and in 1983 described the proteins codified in this genome, all of them components of the oxidative phosphorylation system, metabolic pathway that leads to the synthesis of ATP. Later, he developed a technique, widely used nowadays, to study the mechanism by which the mutations in the mitochondrial DNA altered the cellular function and originated the mitochondrial diseases. In 1999, demonstrated the role of the mitocondrial DNA, and the mutations produced along the life, in aging.

Presentation and diagnosis of mitochondrial disorders in children.

The first disorder of mitochondrial function was described by Luft in 1959. Over the ensuing decades, multiple cases of mitochondrial dysfunction were reported, and the term "mitochondrial disorder" arose to describe any defect in the mitochondrial electron transport chain. The sequence of the mitochondrial genome was elucidated in 1981 by Anderson et al., and during the next 20 years, >200 pathogenic point mutations, deletions, insertions, and rearrangements were described. Most of the original cases were adults, and the diagnosis of a mitochondrial disorder in an adult patient became relatively straightforward. Adults present with well-defined "mitochondrial syndromes" and generally carry mitochondrial DNA mutations that are easily identified. Children with mitochondrial disorders are much harder to define. Children are more likely to have a nuclear DNA mutation, whereas the "classic" syndromic findings tend to be absent. This review describes both the varying presentations of mitochondrial disorders and the common laboratory, imaging, and pathologic findings related to children.

Mitochondrial medicine.

After reviewing the history of mitochondrial diseases, I follow a genetic classification to discuss new developments and old conundrums. In the field of mitochondrial DNA (mtDNA) mutations, I argue that we are not yet scraping the bottom of the barrel because: (i) new mtDNA mutations are still being discovered, especially in protein-coding genes; (ii) the pathogenicity of homoplasmic mutations is being revisited; (iii) some genetic dogmas are chipped but not broken; (iv) mtDNA haplotypes are gaining interest in human pathology; (v) pathogenesis is still largely enigmatic. In the field of nuclear DNA (nDNA) mutations, there has been good progress in our understanding of disorders due to faulty intergenomic communication. Of the genes responsible for multiple deletions and depletion of mtDNA, mutations in POLG have been associated with a great variety of clinical phenotypes in humans and to precocious aging in mice. Novel pathogenetic mechanisms include alterations in the lipid milieu of the inner mitochondrial membrane and mutations in genes controlling mitochondrial motility, fission, and fusion.

Mitochondrial disease: a historical, biochemical, and London perspective.

Roland Luft is credited with describing the first truly mitochondrial disorder in the late 1950s and early 1960s. Cases such as his have proven to be exceptionally rare. Some years later, methods of mitochondrial analysis--enzymatic, polarographic, and spectroscopic, which had been developed primarily by groups in Philadelphia--were applied to the study of mitochondria isolated from skeletal muscle biopsies of patients thought to have defects of oxidative phosphorylation. In the vanguard of these investigations were groups in New York and London. John Clark led the latter group. Application of biochemical studies, more recently supplemented by molecular mtDNA and nuclear DNA studies, have revealed that mitochondrial disorders are among the most common of all metabolic disorders.