Restoration of mitochondrial function through activation of hypomodified tRNAs with pathogenic mutations associated with mitochondrial diseases.

Mutations in mitochondrial (mt-)tRNAs frequently cause mitochondrial dysfunction. Mitochondrial myopathy, encephalopathy, lactic acidosis, and stroke-like episodes (MELAS), and myoclonus epilepsy associated with ragged red fibers (MERRF) are major clinical subgroups of mitochondrial diseases caused by pathogenic point mutations in tRNA genes encoded in mtDNA. We previously reported a severe reduction in the frequency of 5-taurinomethyluridine (τm5U) and its 2-thiouridine derivative (τm5s2U) in the anticodons of mutant mt-tRNAs isolated from the cells of patients with MELAS and MERRF, respectively. The hypomodified tRNAs fail to decode cognate codons efficiently, resulting in defective translation of respiratory chain proteins in mitochondria. To restore the mitochondrial activity of MELAS patient cells, we overexpressed MTO1, a τm5U-modifying enzyme, in patient-derived myoblasts. We used a newly developed primer extension method and showed that MTO1 overexpression almost completely restored the τm5U modification of the MELAS mutant mt-tRNALeu(UUR). An increase in mitochondrial protein synthesis and oxygen consumption rate suggested that the mitochondrial function of MELAS patient cells can be activated by restoring the τm5U of the mutant tRNA. In addition, we confirmed that MTO1 expression restored the τm5s2U of the mutant mt-tRNALys in MERRF patient cells. These findings pave the way for epitranscriptomic therapies for mitochondrial diseases.

Self-initiated lifestyle interventions lead to potential insight into an effective, alternative, non-surgical therapy for mitochondrial disease associated multiple symmetric lipomatosis.

BACKGROUND: A 56-year-old female, diagnosed as a carrier of the mitochondrial DNA mutation (MTTK c.8344A > G) associated with the MERRF (myoclonic epilepsy with ragged red fibers) syndrome, presented with a relatively uncommon but well-known phenotypic manifestation: severe multiple symmetric lipomatosis (MSL). After surgical resection of three kilograms of upper mid-back lipomatous tissue, the patient experienced a significant decline in her functional capacity and quality of life, which ultimately resulted in her placement on long-term disability. METHODS: Dissatisfied with the available treatment options centered on additional resection surgeries, given the high probability of lipoma regrowth, the patient independently researched and applied alternative therapies that centred on a carbohydrate-restricted diet and a supervised exercise program. RESULTS: The cumulative effect of her lifestyle interventions resulted in the reversal of her MSL and her previously low quality of life. She met all her personal goals by the one-year mark, including reduced size of the residual post-surgical lipomas, markedly enhanced exercise tolerance, and return to work. She continues to maintain her interventions and to experience positive outcomes at the two-year mark. INTERPRETATION: This case report documents the timing and nature of lifestyle interventions in relation to the reversal in growth pattern of her previously expanding and debilitating lipomas. The profound nature of the apparent benefit on lipoma growth demonstrates the intervention's potential as a new feasible non-surgical therapy for mitochondrial-disease-associated MSL, and justifies its systematic study. We also describe how this case has inspired the care team to re-examine its approach to involved patients.

Myoclonus epilepsy in mitochondrial disorders.

Mitochondrial disorders is a group of clinical entities associated with abnormalities of the mitochondrial respiratory chain (MRC), which carries out the oxidative phosphorylation (OXPHOS) of ADP into ATP. As the MRC is the result of genetic complementation between two separate genomes, nuclear and mitochondrial, OXPHOS failure can derive from mutations in either nuclear-encoded, or mitochondrial-encoded, genes. Epilepsy is a relatively common feature of mitochondrial disease, especially in early-onset encephalopathies of infants and children. However, the two most common entities associated with epilepsy include MERRF, for Myoclonic Epilepsy with Ragged Red Fibers, and AHS, or Alpers-Huttenlocher syndrome, also known as hepatopathic poliodystrophy. Whilst MERRF is a maternally inherited condition caused by mtDNA mutations, particularly the 8344A>G substitution in the gene encoding mt-tRNALys, AHS is typically caused by recessive mutations in POLG, encoding the catalytic subunit of polymerase gamma, the only mtDNA polymerase in humans. AHS is the most severe, early-onset, invariably fatal syndrome within a disease spectrum, which also include other epileptogenic entities, all due to POLG mutations and including Spino-cerebellar Ataxia and Epilepsy (SCAE). This review reports the main clinical, neuroimaging, biochemical, and molecular features of epilepsy-related mitochondrial syndrome, particularly MERRF and AHS.

Treatment of human cells derived from MERRF syndrome by peptide-mediated mitochondrial delivery.

BACKGROUND AIMS: The feasibility of delivering mitochondria using the cell-penetrating peptide Pep-1 for the treatment of MERRF (myoclonic epilepsy with ragged red fibers) syndrome, which is caused by point mutations in the transfer RNA genes of mitochondrial DNA, is examined further using cellular models derived from patients with MERRF syndrome. METHODS: Homogenesis of mitochondria (wild-type mitochondria) isolated from normal donor cells with about 83.5% preserved activity were delivered into MERRF fibroblasts by Pep-1 conjugation (Pep-1-Mito). RESULTS: Delivered doses of 52.5 µg and 105 µg Pep-1-Mito had better delivered efficiency and mitochondrial biogenesis after 15 days of treatment. The recovery of mitochondrial function in deficient cells receiving 3 days of treatment with peptide-mediated mitochondrial delivery was comprehensively demonstrated by restoration of oxidative phosphorylation subunits (complex I, III and IV), mitochondrial membrane potential, adenosine triphosphate synthesis and reduction of reactive oxygen species production. The benefits of enhanced mitochondrial regulation depended on the function of foreign mitochondria and not the existence of mitochondrial DNA and can be maintained for at least 21 days with dramatically elongated mitochondrial morphology. In contrast to delivery of wild-type mitochondria, the specific regulation of Pep-1-Mito during MERRF syndrome progression in cells treated with mutant mitochondria was reflected by the opposite performance, with increase in reactive oxygen species production and matrix metalloproteinase activity. CONCLUSIONS: The present study further illustrates the feasibility of mitochondrial intervention therapy using the novel approach of peptide-mediated mitochondrial delivery and the benefit resulting from mitochondria-organelle manipulation.

Neuromuscular and systemic presentations in adults: diagnoses beyond MERRF and MELAS.

Mitochondrial diseases are a diverse group of inherited and acquired disorders that result in inadequate energy production. They can be caused by inheritable genetic mutations, acquired somatic mutations, and exposure to toxins (including some prescription medications). Normal mitochondrial physiology is responsible, in part, for the aging process itself, as free radical production within the mitochondria results in a lifetime burden of oxidative damage to DNA, especially the mitochondrial DNA that, in turn, replicate the mutational burden in future copies of itself, and lipid membranes. Primary mitochondrial diseases are those caused by mutations in genes that encode for mitochondrial structural and enzymatic proteins, and those proteins required for mitochondrial assembly and maintenance. A number of common adult maladies are associated with defective mitochondrial energy production and function, including diabetes, obesity, hyperthyroidism, hypothyroidism, and hyperlipidemia. Mitochondrial dysfunction has been demonstrated in many neurodegenerative disorders, including Alzheimer's disease, Parkinson disease, amyotrophic lateral sclerosis, and some cancers. Polymorphisms in mitochondrial DNA have been linked to disease susceptibility, including death from sepsis and survival after head injury. There is considerable overlap in symptoms caused by primary mitochondrial diseases and those illnesses that affect mitochondrial function, but are not caused by primary mutations, as well as disorders that mimic mitochondrial diseases, but are caused by other identified mutations. Evaluation of these disorders is complex, expensive, and not without false-negative and false-positive results that can mislead the physician. Most of the common heritable mitochondrial disorders have been well-described in the literature, but can be overlooked by many clinicians if they are uneducated about these disorders. In general, the evaluation of the classic mitochondrial disorders has become straightforward if the clinician recognized the phenotype and orders appropriate confirmatory testing. However, the majority of patients referred for a mitochondrial evaluation do not have a clear presentation that allows for rapid identification and testing. This article provides introductory comments on mitochondrial structure, physiology, and genetics, but will focus on the presentation and evaluation of adults with mitochondrial symptoms, but who may not have a primary mitochondrial disease.

[Diagnosis and therapy of mitochondrial diseases]. / Mitochondrialis betegségek diagnosztikája es terápiája.

Mitochondrial diseases are a significant part of neuromuscular diseases. Majority of them is multisystemic disorder. The diagnosis can be established in more and more cases. Beyond the routine neurological examination imaging methods (MRI and MR-spectroscopy) and electrophysiology (EMG, ENG, EEG, evoked potential tests) might be helpful in setting the diagnosis. Raised blood lactate level supports the diagnosis. Muscle biopsy demonstrates mitochondrial abnormalities in the majority of cases. The positivity of genetic tests is low, because the amount of mitochondrial DNA alterations is different in tissues. Therefore other tissue than blood (mainly muscle) is necessary for genetic tests. The other reason is that the respiratory chain is under double -mitochondrial and nuclear - genetic control, and testing the nuclear genes are available only in selected laboratories. The treatment is limited, mainly symptomatic.

[Gene expression profiling of classic mitochondrial disorders. Its value in finding therapeutic strategies]. / Genexpressionsstudien bei klassischen Mitochondriopathien. Eine Hilfe bei der Suche nach therapeutischen Strategien?

Mitochondria are semiautonomous cell organelles which possess their own genome (mtDNA) but nonetheless depend on the import of nuclear-encoded proteins. In recent years, several mutations of mtDNA have been associated with specific diseases of the muscles and nervous system. In 1993, the A>G point mutation at position 3243 of the mtDNA, until then a prominent genetic marker for mitochondrial encephalomyopathy, lactic acidosis, and stroke-like episodes (MELAS), was detected in patients with progressive external ophthalmoplegia (PEO). Due to the divergent clinical presentations of MELAS and PEO, the presence of potential nuclear secondary mutations or so-called modifier genes had been suspected. Now it is well known that a bidirectional information flow between the mitochondrion and the cell nucleus exists and that nuclear gene expression adapts to the functional status of the mitochondria. However it remains unclear when and how the nucleus responds to changes or mutations of the mtDNA and if there are indeed disease-specific biomarker genes whose expression changes in case of mtDNA aberrations. This review article focuses on the most recent gene expression profiling studies in the field of classic mitochondrial disorders.

Progressive myoclonic epilepsies: a review of genetic and therapeutic aspects.

The progressive myoclonic epilepsies (PMEs) are a group of symptomatic generalised epilepsies caused by rare disorders, most of which have a genetic component, a debilitating course, and a poor outcome. Challenges with PME arise from difficulty with diagnosis, especially in the early stages of the illness, and further problems of management and drug treatment. Recent advances in molecular genetics have helped achieve better understanding of the different disorders that cause PME. We review the PMEs with emphasis on updated genetics, diagnosis, and therapeutic options.

[Diagnosis and therapy of mitochondriopathies]. / Diagnose und Therapie von Mitochondriopathien.

Defects of the mitochondrial energy production cab be expressed in many tissues and may lead to various types of diseases. Since defects can occur on many sites of the oxidative phosphorylation system, molecular diagnosis can be difficult. In typical mitochondrial syndromes, like MELAS- or MERRF-syndrome, diagnosis can be suspected already on clinical grounds. Lactate measured in various body fluids is still the best selective screening parameter. Loading tests, respectively ergometry is only necessary in the milder clinical forms of diseases or possibly in older children. The in vivo lactate determination e.g. In the CNS by 1H NMR spectroscopy can be helpful in evaluating prognosis. The diagnosis of a mitochondriopathy is usually confirmed enzymatically by tissue biopsies; skeletal muscle is still the tissue of the first choice because some enzyme deficiencies are not sufficiently expressed in cultured fibroblasts. If possible, intact mitochondria should be investigated polarografically along with histology and histochemistry. Finally several parts of the respiratory chain and pyruvate dehydrogenase complex are analyzed by single enzyme measurement. Also combined deficiencies have been described. Polypeptide subunits of respiratory chain complexes can be investigated by means of immunoblotting. The investigations of the mitochondrial DNA from the end of the diagnostic scale. The application of various new therapeutic agents, such as antioxidants, radical scavangers and cofactors have not come to any persuasive clinical result. But there is a number of reports about some successful treatment with coenzyme Q10, vitamin K3, vitamin C, riboflavin, thiamine, dichloroacetate and in PDHC -deficiency with ketogenic diet. Mitochondrial gene therapy appears only theoretical and speculative. Because of the enormous heterogeneity even on the DNA-level genetic counselling is reserved for some cases with exact molecular diagnosis.

[Therapy of metabolic myopathies]. / Therapie metabolischer Myopathien.

Metabolic myopathies are subdivided into disturbances of anaerobic cytoplasmic and aerobic mitochondrial metabolism. With the exception of carnitine deficiency these myopathies are based on enzymopathies. Since gene therapy is not yet available no causal therapy is possible. This paper discusses possibilities for symptomatic therapy. Good results are found with carnitine substitution. Enzymopathies can be improved by using other metabolic pathways or by addition of co-factors of the impaired pathways. This leads to a reduction of myalgia, cramps, and endurance exercise intolerance.