Dominique Chretien

Biochemical and molecular investigations in respiratory chain deficiencies

This paper describes our present strategy for the investigation of respiratory chain disorders in humans. Because very few of the underlying mutations causing mitochondrial disorders in humans are currently known, biochemical studies constitute a major tool in screening procedures for respiratory chain deficiencies. All biochemical and molecular methods described are scaled-down methods, allowing investigation in both adults and young children. Polarographic studies and/or spectrophotometric studies on whole cells (circulating lymphocytes), isolated mitochondria (skeletal muscle) and tissue homogenates are presented. Advantages and limitations of each approach, as well as useful parameters for the characterization of defects and comparison between various tissues are discussed.

Mutation of RRM2B , encoding p53-controlled ribonucleotide reductase (p53R2), causes severe mitochondrial DNA depletion

Mitochondrial DNA (mtDNA) depletion syndrome (MDS; MIM 251880) is a prevalent cause of oxidative phosphorylation disorders characterized by a reduction in mtDNA copy number. The hitherto recognized disease mechanisms alter either mtDNA replication (POLG (ref. 1)) or the salvage pathway of mitochondrial deoxyribonucleosides 5′-triphosphates (dNTPs) for mtDNA synthesis (DGUOK (ref. 2), TK2 (ref. 3) and SUCLA2 (ref. 4)). A last gene, MPV17 (ref. 5), has no known function. Yet the majority of cases remain unexplained. Studying seven cases of profound mtDNA depletion (1–2% residual mtDNA in muscle) in four unrelated families, we have found nonsense, missense and splice-site mutations and in-frame deletions of the RRM2B gene, encoding the cytosolic p53-inducible ribonucleotide reductase small subunit. Accordingly, severe mtDNA depletion was found in various tissues of the Rrm2b−/− mouse. The mtDNA depletion triggered by p53R2 alterations in both human and mouse implies that p53R2 has a crucial role in dNTP supply for mtDNA synthesis.

Quinone-responsive multiple respiratory-chain dysfunction due to widespread coenzyme Q10 deficiency

BACKGROUND The respiratory-chain deficiencies are a broad group of largely untreatable diseases. Among them, coenzyme Q10 (ubiquinone) deficiency constitutes a subclass that deserves early and accurate diagnosis. METHODS We assessed respiratory-chain function in two siblings with severe encephalomyopathy and renal failure. We used high-performance liquid chromatography analyses, combined with radiolabelling experiments, to quantify cellular coenzyme Q10 content. Clinical follow-up and detailed biochemical investigations of respiratory chain activity were carried out over the 3 years of oral quinone administration. FINDINGS Deficiency of coenzyme Q10-dependent respiratory-chain activities was identified in muscle biopsy, circulating lymphocytes, and cultured skin fibroblasts. Undetectable coenzyme Q10 and results of radiolabelling experiments in cultured fibroblasts supported the diagnosis of widespread coenzyme Q10 deficiency. Stimulation of respiration and fibroblast enzyme activities by exogenous quinones in vitro prompted us to treat the patients with oral ubidecarenone (5 mg/kg daily), which resulted in a substantial improvement of their condition over 3 years of therapy. INTERPRETATION Particular attention should be paid to multiple quinone-responsive respiratory-chain enzyme deficiency because this rare disorder can be successfully treated by oral ubidecarenone.

Clinical aspects of mitochondrial disorders

SummaryMitochondrial disorders have long been regarded as neuromuscular diseases only. In fact, owing to the ubiquitous nature of the oxidative phosphorylation, a broad spectrum of clinical features should be expected in mitochondrial disorders. Here, we present eight puzzling observations which give support to the view that a disorder of oxidative phosphorylation can give rise to any symptom in any organ or tissue with any apparent mode of inheritance. Consequently, we suggest giving consideration to the diagnosis of a mitochondrial disorder when dealing with an unexplained association of symptoms, with an early onset and a rapidly progressive course involving seemingly unrelated organs. Determination of lactate/pyruvate and ketone body molar ratios in plasma can help to select patients at risk for this condition.

Twinkle helicase (PEO1) gene mutation causes mitochondrial DNA depletion

Mitochondrial DNA (mtDNA) depletion syndrome (MDS) is a clinically and genetically heterogeneous group of autosomal recessive diseases characterized by a reduction in mtDNA copy number. Several nuclear genes have been shown to account for these severe oxidative phosphorylation disorders, but the disease‐causing mutations remain largely unknown.

Clinical presentation of mitochondrial disorders in childhood.

SummaryRespiratory-chain deficiencies have long been regarded as neuromuscular diseases. In fact, oxidative phosphorylation, i.e. adenosine triphosphate (ATP) synthesis by the respiratory chain, does not occur only in the neuromuscular system. Indeed, a number of non-neuromuscular organs and tissues are dependent upon mitochondrial energy supply. For this reason, a respiratory-chain deficiency can theoretically give rise to any symptom, in any organ or tissue, at any age and with any mode of inheritance, owing to the twofold genetic origin of respiratory enzymes (nuclear DNA and mitochondrial DNA, mtDNA). In recent years, it has become increasingly clear that genetic defects of oxidative phosphorylation account for a large variety of clinical symptoms in childhood. Among 100 patients with respiratory-chain deficiencies identified in our centre, 56% presented with a non-neuromuscular symptom and 44% were referred for a neuromuscular problem. It appears that the diagnosis of a respiratory-chain deficiency is difficult initially when only one symptom is present. In contrast, this diagnosis is easier to consider when two seemingly unrelated symptoms are observed

Clinical presentations and laboratory investigations in respiratory chain deficiency

Respiratory chain deficiencies have long been regarded as neuromuscular diseases. In fact, oxidative phosphorylation, i.e., ATP synthesis by the respiratory chain not only occurs in the neuromuscular system, indeed, a number of nonneuromuscular organs and tissues are dependent upon mitochondrial energy supply. For this reason, a respiratory chain deficiency can theoretically give rise to any symptom, in any organ or tissue, at any age with any mode of inheritance, due to the twofold genetic origin of respiratory enzymes (nuclear DNA and mitochondrial DNA).

Reference charts for respiratory chain activities in human tissues

This paper presents a collection of quantitative values for respiratory chain activities in human tissues. These were measured in the most widely used tissues in screening procedures for respiratory chain deficiencies. Investigations were mainly carried out using the different standardized micro-methods previously detailed (Rustin et al., Clin Chim Acta, 1994). The potential effect of the age of the patients on both absolute and relative levels of respiratory chain activities in their skeletal muscle tissue was first considered. No evidence for any significant difference between the various age groups in the studied population (ranging from 0 to above 50 years of age) was observed. Moreover, a quite similar picture of the organization of the respiratory chain was suggested independent of the tissue or the cells investigated. In particular, it was found that roughly identical enzyme activity ratios could be measured in all tissues, which allowed study of the differential involvement of organs and tissues in patients potentially affected by a respiratory chain deficiency. Some tissue-specific features were, however, observed, including varying rates of glycerol-3-phosphate dehydrogenase activities and increased succinate dehydrogenase activity in liver. The technical limitations remaining in the investigations of respiratory chain disorders in man are discussed in the conclusion.

Antenatal manifestations of mitochondrial respiratory chain deficiency

OBJECTIVE To review the antenatal manifestations of disorders of oxidative phosphorylation. STUDY DESIGN A total of 300 cases of proven respiratory chain enzyme deficiency were retrospectively reviewed for fetal development, based on course and duration of pregnancy, antenatal ultrasonography and birth weight, length, and head circumference. Particular attention was given to fetal movements, oligo/hydramnios, fetal cardiac rhythm, fetal heart ultrasound, and ultrasonography/echo Doppler signs of brain, facial, trunk, limb, and organ anomalies. RESULTS Retrospective analyses detected low birth weight (<3rd percentile for gestational age) in 22.7% of cases (68/300, P<.000001). Intrauterine growth retardation was either isolated (48/300, 16%) or associated with otherwise unexplained anomalies (20/300, 6.7%, P<.0001). Antenatal anomalies were usually multiple and involved several organs sharing no common function or embryologic origin. They included polyhydramnios (6/20), oligoamnios (2/20), arthrogryposis (1/20), decreased fetal movements (1/20), ventricular septal defects (2/20), hypertrophic cardiomyopathy (4/20), cardiac rhythm anomalies (4/20), hydronephrosis (3/20), vertebral abnormalities, anal atresia, cardiac abnormalities, tracheoesophageal fistula/atresia, renal agenesis and dysplasia, and limb defects (VACTERL) association (2/20), and a complex gastrointestinal malformation (1/20). CONCLUSIONS Although a number of metabolic diseases undergo a symptom-free period, respiratory chain deficiency may have an early antenatal expression, presumably related to the time course of the disease gene expression in the embryofetal period. The mechanism triggering malformations is unknown and may include decreased ATP formation and/or an alteration of apoptotic events controlled by the mitochondria.

INBORN ERRORS OF THE KREBS CYCLE : A GROUP OF UNUSUAL MITOCHONDRIAL DISEASES IN HUMAN

Krebs cycle disorders constitute a group of rare human diseases which present an amazing complexity considering our current knowledge on the Krebs cycle function and biogenesis. Acting as a turntable of cell metabolism, it is ubiquitously distributed in the organism and its enzyme components encoded by supposedly typical house-keeping genes. However, the investigation of patients presenting specific defects of Krebs cycle enzymes, resulting from deleterious mutations of the considered genes, leads to reconsider this simple envision by revealing organ-specific impairments, mostly affecting neuromuscular system. This often leaves aside organs the metabolism of which strongly depends on mitochondrial energy metabolism as well, such as heart, kidney or liver. Additionally, in some patients, a complex pattern of tissue-specific enzyme defect was also observed. The lack of functional additional copies of Krebs cycle genes suggests that the complex expression pattern should be ascribed to tissue-specific regulations of transcriptional and/or translational activities, together with a variable cell adaptability to Krebs cycle functional defects.