Your search keyword '"Moraes, Carlos T."' showing total 43 results

1. Correcting a pathogenic mitochondrial DNA mutation by base editing in mice.

Author

Barrera-Paez, Jose D., Bacman, Sandra R., Balla, Till, Van Booven, Derek, Gannamedi, Durga P., Stewart, James B., Mok, Beverly, Liu, David R., Lombard, David B., Griswold, Anthony J., Nedialkova, Danny D., and Moraes, Carlos T.

Subjects

GENOME editing, MYOCARDIUM, MITOCHONDRIAL DNA, TRANSFER RNA, MITOCHONDRIAL pathology

Abstract

Primary mitochondrial disorders are most often caused by deleterious mutations in the mitochondrial DNA (mtDNA). Here, we used a mitochondrial DddA-derived cytosine base editor (DdCBE) to introduce a compensatory edit in a mouse model that carries the pathological mutation in the mitochondrial transfer RNA (tRNA) alanine (mt-tRNAAla) gene. Because the original m.5024C→T mutation (G→A in the mt-tRNAAla) destabilizes the mt-tRNAAla aminoacyl stem, we designed a compensatory m.5081G→A edit (C→T in the mt-tRNAAla) that could restore the secondary structure of the tRNAAla aminoacyl stem. For this, the DdCBE gene construct was initially tested in an m.5024C→T mutant cell line. The reduced mt-tRNAAla amounts in these cells were increased after editing up to 78% of the mtDNA. Then, DdCBE was packaged in recombinant adeno-associated virus 9 (AAV9) and intravenously administered by retro-orbital injections into mice. Expression of the transduced DdCBE was observed in the heart and skeletal muscle. Total mt-tRNAAla amounts were restored in heart and muscle by the m.5081G→A edit in a dose-dependent manner. Lactate amounts, which were increased in the heart, were also decreased in treated mice. However, the highest dose tested of AAV9-DdCBE also induced severe adverse effects in vivo because of the extensive mtDNA off-target editing that it generated. These results show that although DdCBE is a promising gene therapy tool for mitochondrial disorders, the doses of the therapeutic constructs must be carefully monitored to avoid deleterious off-target editing. Editor's summary: Mitochondrial disorders are inherited and often linked to mitochondrial DNA (mtDNA) mutations. Pathologically mutated mtDNA can cause diverse physiological dysfunction that is limited to palliative care. Barrera-Paez et al. used a mitochondrial DddA-derived cytosine base editor (DdCBE) to correct a mutation in the mtDNA encoding a mitochondrial transfer RNA (tRNA) alanine. The mutation disrupted the aminoacyl stem of the tRNA. Correction with DdCBE restored the structure and amounts of the tRNA in cell culture and in mouse heart and muscle tissue. Mice carrying the mtDNA mutation had low mitochondrial tRNA alanine and increased lactate in heart, and editing with DdCBE reversed these abnormalities. At the highest amounts of editing, DdCBE also induced off-target edits that resulted in severe adverse effects in mice. These data suggest that while DdCBE is a promising therapeutic avenue for mitochondrial gene editing, caution and further study are warranted to avoid damaging off-target effects. —Brandon Berry [ABSTRACT FROM AUTHOR]

Published

2025

2. NEK10 kinase ablation affects mitochondrial morphology, function and protein phosphorylation status.

Author

de Oliveira, Andressa Peres, Navarro, Claudia D. C., Dias, Pedro Rafael F., Arguello, Tania, Walker, Brittni R., Bacman, Sandra R., Sousa, Lizandra Maia, Castilho, Roger F., Consonni, Sílvio R., Moraes, Carlos T., and Kobarg, Jörg

Subjects

LIQUID chromatography-mass spectrometry, MITOCHONDRIAL proteins, PROTEIN-tyrosine kinases, REACTIVE oxygen species, ENDOPLASMIC reticulum, OXYGEN consumption, MITOCHONDRIAL DNA

Abstract

Background: NEK10, a serine/threonine/tyrosine kinase belonging to the NEK (NIMA-related kinases) family, has been associated with diverse cellular processes. However, no specific target pathways have been identified. Our previous work knocking down NEK10 in HeLa cells suggested a functional association with mitochondria, as we observed altered mitochondrial morphology, mitochondrial oxygen consumption, mtDNA integrity, and reactive oxygen species levels. Methods: To better understand this association, we studied human HAP1 cells fully knockout for NEK10 and confirmed that NEK10 has an important role in mitochondrial homeostasis. We performed the study of mitochondrial respiration, mitochondrial morphology, mitochondrial mass, and mtDNA analysis. Additionally, we showed proteome and phosphoproteome data of crude mitochondrial fraction of Parental and NEK10 KO cells using liquid chromatography-mass spectrometry (LC–MS/MS). Results: In the absence of NEK10 several mitochondrial functions were disturbed. Moreover, proteome and phosphoproteome analyses of mitochondrial fractions showed that NEK10 alters the threonine phosphorylation status of several mitochondrial/endoplasmic reticulum components, including HSP60, NDUFB4, and TOM20. These changes impacted the steady-state levels of a larger group of proteins, preferentially involving respiratory complexes and autophagy pathways. Conclusion: We concluded that NEK10 plays a key role in mitochondrial function, possibly by modulating the phosphorylation status of mitochondrial proteins. [ABSTRACT FROM AUTHOR]

Published

2024

3. Rapid Directional Shift of Mitochondrial DNA Heteroplasmy in Animal Tissues by a Mitochondrially Targeted Restriction Endonuclease

Author

Bayona-Bafaluy, Maria Pilar, Blits, Bas, Battersby, Brendan J., Shoubridge, Eric A., Moraes, Carlos T., and Caskey, C. Thomas

Published

2005

4. Mitochondrial DNA heteroplasmy in disease and targeted nuclease‐based therapeutic approaches

Author

Nissanka, Nadee and Moraes, Carlos T

Published

2020

5. Expanding the Functional Human Mitochondrial DNA Database by the Establishment of Primate Xenomitochondrial Cybrids

Author

Kenyon, Lesley and Moraes, Carlos T.

Published

1997

6. mitoTev‐TALE: a monomeric DNA editing enzyme to reduce mutant mitochondrial DNA levels

Author

Pereira, Claudia V, Bacman, Sandra R, Arguello, Tania, Zekonyte, Ugne, Williams, Sion L, Edgell, David R, and Moraes, Carlos T

Published

2018

7. Overexpression of Twinkle-helicase protects cardiomyocytes from genotoxic stress caused by reactive oxygen species

Author

Pohjoismäki, Jaakko L. O., Williams, Siôn L., Boettger, Thomas, Goffart, Steffi, Kim, Johnny, Suomalainen, Anu, Moraes, Carlos T., and Braun, Thomas

Published

2013

8. Cytochrome c Oxidase Deficiency in Neurons Decreases Both Oxidative Stress and Amyloid Formation in a Mouse Model of Alzheimer's Disease

Author

Fukui, Hirokazu, Diaz, Francisca, Garcia, Sofia, and Moraes, Carlos T.

Published

2007

9. A Direct Repeat is a Hotspot for Large-Scale Deletion of Human Mitochondrial DNA

Author

Schon, Eric A., Rizzuto, Rosario, Moraes, Carlos T., Nakase, Hirofumi, Zeviani, Massimo, and DiMauro, Salvatore

Published

1989

10. Mitochondrial genome engineering coming-of-age.

Author

Barrera-Paez, Jose Domingo and Moraes, Carlos T.

Subjects

*MITOCHONDRIAL DNA, *CYTIDINE deaminase, *NUCLEIC acids, *MITOCHONDRIAL pathology, *DEOXYADENOSINE, *GENETIC code

Abstract

The mitochondrial genome has been difficult to manipulate because it is shielded by the organelle double membranes, preventing efficient nucleic acid entry. Moreover, mitochondrial DNA (mtDNA) recombination is not a robust system in most species. This limitation has forced investigators to rely on naturally occurring alterations to study both mitochondrial function and pathobiology. Because most pathogenic mtDNA mutations are heteroplasmic, the development of specific nucleases has allowed us to selectively eliminate mutant species. Several 'protein only' gene-editing platforms have been successfully used for this purpose. More recently, a DNA double-strand cytidine deaminase has been identified and adapted to edit mtDNA. This enzyme was also used as a component to adapt a DNA single-strand deoxyadenosine deaminase to mtDNA editing. These are major advances in our ability to precisely alter the mtDNA in animal cells. Approximately 1000–10 000 copies of the mitochondrial DNA (mtDNA) can be found per cell. Molecules may carry deleterious mutations that will result in a mitochondrial disorder if there are not enough wild-type copies to compensate for the defect. There are no efficient methods to directly modify the mtDNA in vivo. However, proteins can be delivered to mitochondria by expressing genes coding for a mitochondrial target sequence in the nucleus. It is possible to introduce specific mitochondrion-targeted nucleases in the mitochondrial matrix to produce double-strand breaks and degrade the pathological molecules. Different strategies have been developed and validated in vivo. We are now able to express a mitochondrion-targeted base editor to directly modify the mtDNA in vivo. [ABSTRACT FROM AUTHOR]

Published

2022

11. Mitochondrial targeted meganuclease as a platform to eliminate mutant mtDNA in vivo.

Author

Zekonyte, Ugne, Bacman, Sandra R., Smith, Jeff, Shoop, Wendy, Pereira, Claudia V., Tomberlin, Ginger, Stewart, James, Jantz, Derek, and Moraes, Carlos T.

Subjects

DEOXYRIBOZYMES, MITOCHONDRIAL DNA, DNA restriction enzymes, GENOME editing, BASE pairs, MITOCHONDRIA, MITOCHONDRIAL DNA abnormalities, GENE therapy

Abstract

Diseases caused by heteroplasmic mitochondrial DNA mutations have no effective treatment or cure. In recent years, DNA editing enzymes were tested as tools to eliminate mutant mtDNA in heteroplasmic cells and tissues. Mitochondrial-targeted restriction endonucleases, ZFNs, and TALENs have been successful in shifting mtDNA heteroplasmy, but they all have drawbacks as gene therapy reagents, including: large size, heterodimeric nature, inability to distinguish single base changes, or low flexibility and effectiveness. Here we report the adaptation of a gene editing platform based on the I-CreI meganuclease known as ARCUS®. These mitochondrial-targeted meganucleases (mitoARCUS) have a relatively small size, are monomeric, and can recognize sequences differing by as little as one base pair. We show the development of a mitoARCUS specific for the mouse m.5024C>T mutation in the mt-tRNAAla gene and its delivery to mice intravenously using AAV9 as a vector. Liver and skeletal muscle show robust elimination of mutant mtDNA with concomitant restoration of mt-tRNAAla levels. We conclude that mitoARCUS is a potential powerful tool for the elimination of mutant mtDNA. Heteroplasmic mitochondrial DNA mutations lack effective treatments. Here the authors adapt I-CreI meganuclease to target the mitochondria and specifically-eliminate mtDNA with a m.5024C>T mutation in the mttRNA Ala gene. [ABSTRACT FROM AUTHOR]

Published

2021

12. ATAD3 controls mitochondrial cristae structure in mouse muscle, influencing mtDNA replication and cholesterol levels.

Author

Peralta, Susana, Williams, Sion L., Diaz, Francisca, Garcia, Sofia, Moraes, Carlos T., Goffart, Steffi, Pohjoismäki, Jaakko, Nissanka, Nadee, and Area-Gomez, Estela

Subjects

MITOCHONDRIAL DNA, CHOLESTEROL, SKELETAL muscle, GENETIC mutation, MORPHOLOGY, METABOLISM

Abstract

Mutations in the mitochondrial inner membrane ATPase ATAD3A result in neurological syndromes in humans. In mice, the ubiquitous disruption of Atad3 (also known as Atad3a) was embryonic lethal, but a skeletal muscle-specific conditional knockout (KO) was viable. At birth, ATAD3 muscle KO mice had normal weight, but from 2 months onwards they showed progressive motor-impaired coordination and weakness. Loss of ATAD3 caused early and severe mitochondrial structural abnormalities, mitochondrial proliferation and muscle atrophy. There was dramatic reduction in mitochondrial cristae junctions and overall cristae morphology. The lack of mitochondrial cristae was accompanied by a reduction in high molecular weight mitochondrial contact site and cristae organizing system (MICOS) complexes, and to a lesser extent in OPA1. Moreover, muscles lacking ATAD3 showed altered cholesterol metabolism, accumulation of mitochondrial DNA (mtDNA) replication intermediates, progressive mt DNA depletion and deletions. Unexpectedly, decreases in the levels of some OXPHOS components occurred after cristae destabilization, indicating that ATAD3 is not crucial for mitochondrial translation, as previously suggested. Our results show a critical early role of ATAD3 in regulating mitochondrial inner membrane structure, leading to secondary defects in mtDNA replication and complex V and cholesterol levels in postmitotic tissue. [ABSTRACT FROM AUTHOR]

Published

2018

13. The mitochondrial DNA polymerase gamma degrades linear DNA fragments precluding the formation of deletions.

Author

Nissanka, Nadee, Bacman, Sandra R., Plastini, Melanie J., and Moraes, Carlos T.

Subjects

MITOCHONDRIAL DNA, EXONUCLEASES, DNA polymerases, DOUBLE-strand DNA breaks, DNA

Abstract

Double-strand breaks in the mitochondrial DNA (mtDNA) result in the formation of linear fragments that are rapidly degraded. However, the identity of the nuclease(s) performing this function is not known. We found that the exonuclease function of the mtDNA polymerase gamma (POLG) is required for this rapid degradation of mtDNA fragments. POLG is recruited to linearized DNA fragments in an origin of replication-independent manner. Moreover, in the absence of POLG exonuclease activity, the prolonged existence of mtDNA linear fragments leads to increased levels of mtDNA deletions, which have been previously identified in the mutator mouse, patients with POLG mutations and normal aging. [ABSTRACT FROM AUTHOR]

Published

2018

14. Overexpression of PGC‐1α in aging muscle enhances a subset of young‐like molecular patterns.

Author

Garcia, Sofia, Nissanka, Nadee, Mareco, Edson A., Rossi, Susana, Peralta, Susana, Diaz, Francisca, Rotundo, Richard L., Carvalho, Robson F., and Moraes, Carlos T.

Subjects

GENETIC overexpression, MITOCHONDRIAL DNA, MUSCLE aging, MITOCHONDRIA formation, TRANSCRIPTION factors

Abstract

Summary: PGC‐1α is a transcriptional co‐activator known as the master regulator of mitochondrial biogenesis. Its control of metabolism has been suggested to exert critical influence in the aging process. We have aged mice overexpressing PGC‐1α in skeletal muscle to determine whether the transcriptional changes reflected a pattern of expression observed in younger muscle. Analyses of muscle proteins showed that Pax7 and several autophagy markers were increased. In general, the steady‐state levels of several muscle proteins resembled that of muscle from young mice. Age‐related mtDNA deletion levels were not increased by the PGC‐1α‐associated increase in mitochondrial biogenesis. Accordingly, age‐related changes in the neuromuscular junction were minimized by PGC‐1α overexpression. RNA‐Seq showed that several genes overexpressed in the aged PGC‐1α transgenic are expressed at higher levels in young when compared to aged skeletal muscle. As expected, there was increased expression of genes associated with energy metabolism but also of pathways associated with muscle integrity and regeneration. We also found that PGC‐1α overexpression had a mild but significant effect on longevity. Taken together, overexpression of PGC‐1α in aged muscle led to molecular changes that resemble the patterns observed in skeletal muscle from younger mice. [ABSTRACT FROM AUTHOR]

Published

2018

15. Mitochondrial DNA damage and reactive oxygen species in neurodegenerative disease.

Author

Nissanka, Nadee and Moraes, Carlos T.

Subjects

*MITOCHONDRIAL DNA, *DNA damage, *REACTIVE oxygen species, *NEURODEGENERATION, *OXIDATIVE phosphorylation

Abstract

Mitochondria are essential organelles within the cell where most ATP is produced through oxidative phosphorylation (OXPHOS). A subset of the genes needed for this process are encoded by the mitochondrial DNA (mtDNA). One consequence of OXPHOS is the production of mitochondrial reactive oxygen species (ROS), whose role in mediating cellular damage, particularly in damaging mtDNA during ageing, has been controversial. There are subsets of neurons that appear to be more sensitive to ROS‐induced damage, and mitochondrial dysfunction has been associated with several neurodegenerative disorders. In this review, we will discuss the current knowledge in the field of mtDNA and neurodegeneration, the debate about ROS as a pathological or beneficial contributor to neuronal function, bona fide mtDNA diseases, and insights from mouse models of mtDNA defects affecting the central nervous system. [ABSTRACT FROM AUTHOR]

Published

2018

16. Mitochondrial Genome Engineering: The Revolution May Not Be CRISPR-Ized.

Author

Gammage, Payam A., Moraes, Carlos T., and Minczuk, Michal

Subjects

*MITOCHONDRIAL DNA, *CRISPRS, *ORGANELLES, *NUCLEIC acids, *GENETIC engineering

Abstract

In recent years mitochondrial DNA (mtDNA) has transitioned to greater prominence across diverse areas of biology and medicine. The recognition of mitochondria as a major biochemical hub, contributions of mitochondrial dysfunction to various diseases, and several high-profile attempts to prevent hereditary mtDNA disease through mitochondrial replacement therapy have roused interest in the organellar genome. Subsequently, attempts to manipulate mtDNA have been galvanized, although with few robust advances and much controversy. Re-engineered protein-only nucleases such as mtZFN and mitoTALEN function effectively in mammalian mitochondria, although efficient delivery of nucleic acids into the organelle remains elusive. Such an achievement, in concert with a mitochondria-adapted CRISPR/Cas9 platform, could prompt a revolution in mitochondrial genome engineering and biological understanding. However, the existence of an endogenous mechanism for nucleic acid import into mammalian mitochondria, a prerequisite for mitochondrial CRISPR/Cas9 gene editing, remains controversial. [ABSTRACT FROM AUTHOR]

Published

2018

17. Lack of Parkin Anticipates the Phenotype and Affects Mitochondrial Morphology and mtDNA Levels in a Mouse Model of Parkinson's Disease.

Author

Pinto, Milena, Moraes, Carlos T., and Nissanka, Nadee

Subjects

*DELETION mutation, *DOUBLE-strand DNA breaks, *MITOCHONDRIA, *MITOCHONDRIAL DNA, *PARKINSON'S disease

Abstract

PARK2 is the most common gene mutated in monogenic recessive familial cases of Parkinson's disease (PD). Pathogenic mutations cause a loss of function of the encoded protein Parkin. ParkinKO mice, however, poorly represent human PD symptoms as they only exhibit mild motor phenotypes, minor dopamine metabolism abnormalities, and no signs of dopaminergic neurodegeneration. Parkin has been shown to participate in mitochondrial turnover, by targeting damaged mitochondria with low membrane potential to mitophagy. We studied the role of Parkin on mitochondrial quality control in vivo by knocking out Parkin in the PD-mito-Pstl mouse (males), where the mitochondrial DNA (mtDNA) undergoes double-strand breaks only in dopaminergic neurons. The lack of Parkin promoted earlier onset of dopaminergic neurodegeneration and motor defects in the PD-mito-PstI mice, but it did not worsen the pathology. The lack of Parkin affected mitochondrial morphology in dopaminergic axons and was associated with an increase in mtDNA levels (mutant and wild type). Unexpectedly, it did not cause a parallel increase in mitochondrial mass or mitophagy. Our results suggest that Parkin affects mtDNA levels in a mitophagy-independent manner. [ABSTRACT FROM AUTHOR]

Published

2018

18. Mitochondrial DNA Double-Strand Breaks in Oligodendrocytes Cause Demyelination, Axonal Injury, and CNS Inflammation.

Author

Madsen, Pernille M., Pinto, Milena, Patel, Shreyans, McCarthy, Stephanie, Han Gao, Taherian, Mehran, Karmally, Shaffiat, Pereira, Claudia V., Dvoriantchikova, Galina, Ivanov, Dmitry, Tanaka, Kenji F., Moraes, Carlos T., and Brambilla, Roberta

Subjects

MITOCHONDRIAL DNA, DOUBLE-strand DNA breaks, OLIGODENDROGLIA, DEMYELINATION, PATHOLOGICAL physiology, NEURODEGENERATION, MULTIPLE sclerosis

Abstract

Mitochondrial dysfunction has been implicated in the pathophysiology of neurodegenerative disorders, including multiple sclerosis (MS). To date, the investigation of mitochondrial dysfunction in MS has focused exclusively on neurons, with no studies exploring whether dysregulation of mitochondrial bioenergetics and/or genetics in oligodendrocytes might be associated with the etiopathogenesis of MS and other demyelinating syndromes. To address this question, we established a mouse model where mitochondrial DNA (mtDNA) double-strand breaks (DSBs) were specifically induced in myelinating oligodendrocytes (PLPtmtPstl mice) by expressing a mitochondrialtargeted endonuclease, mtPstl, starting at 3 weeks of age. In both female and male mice, DSBs of oligodendroglial mtDNA caused impairment of locomotor function, chronic demyelination, glial activation, and axonal degeneration, which became more severe with time of induction. In addition, after short transient induction of mtDNA DSBs, PLP:mtPstI mice showed an exacerbated response to experimental autoimmune encephalomyelitis. Together, our data demonstrate that mtDNA damage can cause primary oligodendropathy, which in turn triggers demyelination, proving PLPantPstI mice to be a useful tool to study the pathological consequences of mitochondrial dysfunction in oligodendrocytes. I n addition, the demyelination and axonal loss displayed by PLPimtPstI mice recapitulate some of the key features of chronic demyelinating syndromes, including progressive MS forms, which are not accurately reproduced in the models currently available. For this reason, the PLP: mtPstl mouse represents a unique and much needed platform for testing remyelinating therapies. [ABSTRACT FROM AUTHOR]

Published

2017

19. Mitochondrial genome engineering coming-of-age: (Trends in Genetics, 38:869–880, 2022).

Author

Barrera-Paez, Jose Domingo and Moraes, Carlos T.

Subjects

*MITOCHONDRIAL DNA, *GENETICS, *GENOMES

Published

2023

20. Mitochondrial genome changes and neurodegenerative diseases.

Author

Pinto, Milena and Moraes, Carlos T.

Subjects

*MITOCHONDRIAL DNA, *NEURODEGENERATION, *ORGANELLES, *OXIDATIVE phosphorylation, *GENETIC mutation, *PROTEIN folding

Abstract

Abstract: Mitochondria are essential organelles within the cell where most of the energy production occurs by the oxidative phosphorylation system (OXPHOS). Critical components of the OXPHOS are encoded by the mitochondrial DNA (mtDNA) and therefore, mutations involving this genome can be deleterious to the cell. Post-mitotic tissues, such as muscle and brain, are most sensitive to mtDNA changes, due to their high energy requirements and non-proliferative status. It has been proposed that mtDNA biological features and location make it vulnerable to mutations, which accumulate over time. However, although the role of mtDNA damage has been conclusively connected to neuronal impairment in mitochondrial diseases, its role in age-related neurodegenerative diseases remains speculative. Here we review the pathophysiology of mtDNA mutations leading to neurodegeneration and discuss the insights obtained by studying mouse models of mtDNA dysfunction. This article is part of a Special Issue entitled: Misfolded Proteins, Mitochondrial Dysfunction, and Neurodegenerative Diseases. [Copyright &y& Elsevier]

Published

2014

21. Somatic mtDNA Mutation Spectra in the Aging Human Putamen.

Author

Williams, Siôn L., Mash, Deborah C., Züchner, Stephan, and Moraes, Carlos T.

Subjects

MITOCHONDRIAL DNA, AGING, NUCLEOTIDES, GENETIC mutation, DNA replication

Abstract

The accumulation of heteroplasmic mitochondrial DNA (mtDNA) deletions and single nucleotide variants (SNVs) is a well-accepted facet of the biology of aging, yet comprehensive mutation spectra have not been described. To address this, we have used next generation sequencing of mtDNA-enriched libraries (Mito-Seq) to investigate mtDNA mutation spectra of putamen from young and aged donors. Frequencies of the “common” deletion and other “major arc” deletions were significantly increased in the aged cohort with the fold increase in the frequency of the common deletion exceeding that of major arc deletions. SNVs also increased with age with the highest rate of accumulation in the non-coding control region which contains elements necessary for translation and replication. Examination of predicted amino acid changes revealed a skew towards pathogenic SNVs in the coding region driven by mutation bias. Levels of the pathogenic m.3243A>G tRNA mutation were also found to increase with age. Novel multimeric tandem duplications that resemble murine control region multimers and yeast ρ− mtDNAs, were identified in both young and aged specimens. Clonal ∼50 bp deletions in the control region were found at high frequencies in aged specimens. Our results reveal the complex manner in which the mitochondrial genome alters with age and provides a foundation for studies of other tissues and disease states. [ABSTRACT FROM AUTHOR]

Published

2013

22. Nitric Oxide Synthesis Is Increased in Cybrid Cells with m.3243A>G Mutation.

Author

Gamba, Juliana, Gamba, Luana T., Rodrigues, Gabriela S., Kiyomoto, Beatriz H., Moraes, Carlos T., and Tengan, Celia H.

Subjects

NITRIC oxide synthesis, MITOCHONDRIAL pathology, EUKARYOTIC cells, VASODILATION, ENDOTHELIUM, ARGININE, CELLULAR signal transduction, MITOCHONDRIAL DNA

Abstract

Nitric oxide (NO) is a free radical and a signaling molecule in several pathways, produced by nitric oxide synthase (NOS) from the conversion of L-arginine to citrulline. Supplementation of L-arginine has been used to treat MELAS (mitochondrial encephalopathy with lactic acidosis and stroke like syndrome), a mitochondrial disease caused by the m.3243A>G mutation. Low levels of serum arginine and endothelium dysfunction have been reported in MELAS and this treatment may increase NO in endothelial cells and promote vasodilation, decreasing cerebral ischemia and strokes. Although clinical benefits have been reported, little is known about NO synthesis in MELAS. In this study we found that osteosarcoma derived cybrid cells with high levels of m.3243A>G had increased nitrite, an NO metabolite, and increased intracellular NO, demonstrated by an NO fluorescent probe (DAF-FM). Muscle vessels from patients with the same mutation had increased staining in NADPH diaphorase, suggestive of increased NOS. These results indicate increased production of NO in cells harboring the m.3243A>G, however no nitrated protein was detected by Western blotting. Further studies are necessary to clarify the exact mechanisms of L-arginine effect to determine the appropriate clinical use of this drug therapy. [ABSTRACT FROM AUTHOR]

Published

2013

23. Mitochondrial transcription: Lessons from mouse models.

Author

Peralta, Susana, Wang, Xiao, and Moraes, Carlos T.

Subjects

MITOCHONDRIAL physiology, GENETIC transcription, LABORATORY mice, MITOCHONDRIAL DNA, ADENOSINE triphosphate, TRANSFER RNA

Abstract

Abstract: Mammalian mitochondrial DNA (mtDNA) is a circular double-stranded DNA genome of ~16.5 kilobase pairs (kb) that encodes 13 catalytic proteins of the ATP-producing oxidative phosphorylation system (OXPHOS), and the rRNAs and tRNAs required for the translation of the mtDNA transcripts. All the components needed for transcription and replication of the mtDNA are, therefore, encoded in the nuclear genome, as are the remaining components of the OXPHOS system and the mitochondrial translation machinery. Regulation of mtDNA gene expression is very important for modulating the OXPHOS capacity in response to metabolic requirements and in pathological processes. The combination of in vitro and in vivo studies has allowed the identification of the core machinery required for basal mtDNA transcription in mammals and a few proteins that regulate mtDNA transcription. Specifically, the generation of knockout mouse strains in the last several years, has been key to understanding the basis of mtDNA transcription in vivo. However, it is well accepted that many components of the transcription machinery are still unknown and little is known about mtDNA gene expression regulation under different metabolic requirements or disease processes. In this review we will focus on how the creation of knockout mouse models and the study of their phenotypes have contributed to the understanding of mitochondrial transcription in mammals. This article is part of a Special Issue entitled: Mitochondrial Gene Expression. [Copyright &y& Elsevier]

Published

2012

24. Long-Term Bezafibrate Treatment Improves Skin and Spleen Phenotypes of the mtDNA Mutator Mouse.

Author

Dillon, Lloye M., Hida, Aline, Garcia, Sofia, Prolla, Tomas A., Moraes, Carlos T., and Yidong Bai

Subjects

PEROXISOME proliferator-activated receptors, MITOCHONDRIA, ENERGY metabolism, MITOCHONDRIAL DNA, PREMATURE aging (Medicine), MITOCHONDRIAL pathology

Abstract

Pharmacological agents, such as bezafibrate, that activate peroxisome proliferator-activated receptors (PPARs) and PPAR γ coactivator-1α (PGC-1α) pathways have been shown to improve mitochondrial function and energy metabolism. The mitochondrial DNA (mtDNA) mutator mouse is a mouse model of aging that harbors a proofreading-deficient mtDNA polymerase γ. These mice develop many features of premature aging including hair loss, anemia, osteoporosis, sarcopenia and decreased lifespan. They also have increased mtDNA mutations and marked mitochondrial dysfunction. We found that mutator mice treated with bezafibrate for 8-months had delayed hair loss and improved skin and spleen aging-like phenotypes. Although we observed an increase in markers of fatty acid oxidation in these tissues, we did not detect a generalized increase in mitochondrial markers. On the other hand, there were no improvements in muscle function or lifespan of the mutator mouse, which we attributed to the rodent-specific hepatomegaly associated with fibrate treatment. These results showed that despite its secondary effects in rodent's liver, bezafibrate was able to improve some of the aging phenotypes in the mutator mouse. Because the associated hepatomegaly is not observed in primates, long-term bezafibrate treatment in humans could have beneficial effects on tissues undergoing chronic bioenergetic-related degeneration. [ABSTRACT FROM AUTHOR]

Published

2012

25. Striatal Dysfunctions Associated with Mitochondrial DNA Damage in Dopaminergic Neurons in a Mouse Model of Parkinson's Disease.

Author

Pickrell, Alicia M., Pinto, Milena, Hida, Aline, and Moraes, Carlos T.

Subjects

MITOCHONDRIAL DNA, DNA damage, DOPAMINERGIC neurons, LABORATORY mice, PARKINSON'S disease, NEURODEGENERATION, HYDROXYLASES, GENE expression, PATHOLOGICAL physiology

Abstract

Parkinson's disease (PD) is one of the most common progressive neurodegenerative disorders, characterized by resting tremor, rigidity, bradykinesia, and postural instability. These symptoms are associated with massive loss of tyrosine hydroxylase-positive neurons in the substantia nigra (SN) causing an estimated 70-80% depletion of dopamine (DA) in the striatum, where their projections are located. Although the etiology of PD is unknown, mitochondrial dysfunctions have been associated with the disease pathophysiology. We used a mouse model expressing a mitochondria-targeted restriction enzyme, PstI or mito-PstI, to damage mitochondrial DNA (mtDNA) in dopaminergic neurons. The expression of mito-PstI induces double-strand breaks in the mtDNA, leading to an oxidative phosphorylation deficiency, mostly due to mtDNA depletion. Taking advantage of a dopamine transporter (DAT) promoter-driven tetracycline transactivator protein (tTA), we expressed mito-PstI exclusively in dopaminergic neurons, creating a novel PD transgenic mouse model (PD-mito-PstI mouse). These mice recapitulate most of the major features of PD: they have a motor phenotype that is reversible with L-DOPA treatment, a progressive neurodegeneration of the SN dopaminergic population, and striatal DA depletion. Our results also showed that behavioral phenotypes in PD-mito-PstI mice were associated with striatal dysfunctions preceding SN loss of tyrosine hydroxylase-positive neurons and that other neurotransmitter systems [noradrenaline (NE) and serotonin (5-HT)] were increased after the disruption of DA neurons, potentially as a compensatory mechanism. This transgenic mouse model provides a novel model to study the role of mitochondrial defects in the axonal projections of the striatum in the pathophysiology of PD. [ABSTRACT FROM AUTHOR]

Published

2011

26. A metabolic shift induced by a PPAR panagonist markedly reduces the effects of pathogenic mitochondrial tRNA mutations.

Author

Wenz, Tina, Wang, Xiao, Marini, Matteo, and Moraes, Carlos T.

Subjects

MITOCHONDRIAL DNA, PATHOGENIC microorganisms, PEROXISOMES, TRANSFER RNA, PHOSPHORYLATION

Abstract

Mutations in mitochondrial DNA-encoded tRNA genes are associated with many human diseases. Activation of peroxisome proliferator-activated receptors (PPARs) by synthetic agonists stimulates oxidative metabolism, induces an increase in mitochondrial mass and partially compensates for oxidative phosphorylation system (OXPHOS) defects caused by single OXPHOS enzyme deficiencies in vitro and in vivo. Here, we analysed whether treatment with the PPAR panagonist bezafibrate in cybrids homoplasmic for different mitochondrial tRNA mutations could ameliorate the OXPHOS defect. We found that bezafibrate treatment increased mitochondrial mass, mitochondrial tRNA steady state levels and enhanced mitochondrial protein synthesis. This improvement resulted in increased OXPHOS activity and finally in enhanced mitochondrial ATP generating capacity. PPAR panagonists are known to increase the expression of PPAR gamma coactivator-1α (PGC-1α), a master regulator of mitochondrial biogenesis. Accordingly, we found that clones of a line harbouring a mutated mitochondrial tRNA gene mutation selected for the ability to grow in a medium selective for OXPHOS function had a 3-fold increase in PGC-1α expression, an increase that was similar to the one observed after bezafibrate treatment. These findings show that increasing mitochondrial mass and thereby boosting residual OXPHOS capacity can be beneficial to an important class of mitochondrial defects reinforcing the potential therapeutic use of approaches stimulating mitochondrial proliferation for mitochondrial disorders. [ABSTRACT FROM AUTHOR]

Published

2011

27. The mtDNA Mutation Spectrum of the Progeroid Polg Mutator Mouse Includes Abundant Control Region Multimers.

Author

Williams, Siôn L., Huang, Jia, Edwards, Yvonne J.K., Ulloa, Rick H., Dillon, Lloye M., Prolla, Tomas A., Vance, Jeffery M., Moraes, Carlos T., and Züchner, Stephan

Subjects

MITOCHONDRIAL DNA, GENETIC mutation, LABORATORY mice, ETIOLOGY of diseases, DNA polymerases, NUCLEOTIDES, BRAIN, HEART

Abstract

Summary: Polg mtDNA mutator mice are important models for investigating the role of acquired mtDNA mutations in aging. Despite extensive study, there remains little consensus on either the etiology of the progeroid phenotype or the mtDNA mutation spectrum induced by disrupted polymerase-γ function. To investigate the latter, we have developed a novel, pragmatic approach we term “Mito-seq,” applying next-generation sequencing to enriched, native mtDNA. Regardless of detection parameters we observed an increase of at least two orders of magnitude in the number of mtDNA single nucleotide variants in Polg mutator mice compared to controls. We found no evidence for the accumulation of canonical mtDNA deletions but multimers of the mtDNA control region were identified in brain and heart. These control region multimers (CRMs) contained heterogeneous breakpoints and formed species that excluded the majority of mtDNA genes. CRMs demonstrate that polymerase-γ 3′-5′ exonuclease activity is required for preserving mtDNA integrity. [ABSTRACT FROM AUTHOR]

Published

2010

28. Activation of the PPAR/PGC-1α Pathway Prevents a Bioenergetic Deficit and Effectively Improves a Mitochondrial Myopathy Phenotype.

Author

Wenz, Tina, Diaz, Francisca, Spiegelman, Bruce M., and Moraes, Carlos T.

Subjects

MITOCHONDRIAL DNA, MITOCHONDRIA, MUSCLE diseases, MYALGIA

Abstract

Summary: Neuromuscular disorders with defects in the mitochondrial ATP-generating system affect a large number of children and adults worldwide, but remain without treatment. We used a mouse model of mitochondrial myopathy, caused by a cytochrome c oxidase deficiency, to evaluate the effect of induced mitochondrial biogenesis on the course of the disease. Mitochondrial biogenesis was induced either by transgenic expression of peroxisome proliferator-activated receptor γ (PPARγ) coactivator α (PGC-1α) in skeletal muscle or by administration of bezafibrate, a PPAR panagonist. Both strategies successfully stimulated residual respiratory capacity in muscle tissue. Mitochondrial proliferation resulted in an enhanced OXPHOS capacity per muscle mass. As a consequence, ATP levels were conserved resulting in a delayed onset of the myopathy and a markedly prolonged life span. Thus, induction of mitochondrial biogenesis through pharmacological or metabolic modulation of the PPAR/PGC-1α pathway promises to be an effective therapeutic approach for mitochondrial disorders. [Copyright &y& Elsevier]

Published

2008

29. Transcriptional co-expression and co-regulation of genes coding for components of the oxidative phosphorylation system.

Author

van Waveren, Corina and Moraes, Carlos T.

Subjects

*GENETIC transcription, *GENETIC regulation, *GENETIC code, *PHOSPHORYLATION, *MITOCHONDRIAL DNA

Abstract

Background: The mitochondrial oxidative phosphorylation (OXPHOS) is critical for energy (ATP) production in eukaryotic cells. It was previously shown that genes coding for mitochondrial proteins involved in energy production co-express at the RNA level. Because the OXPHOS enzymes are multimeric complexes, we tested the hypothesis that genes coding for components of specific complexes are also co-regulated at the transcriptional level, and share common regulatory elements in their promoters. Results: We observed for the first time that, not only OXPHOS genes as a group co-express, but there is a co-expression of genes within each of the five OXPHOS enzyme complexes, showing a higher degree of complexity in gene co-regulation. In silico analysis of homologous promoter sequences in mammals identified the likely core promoter elements for most genes encoding OXPHOS subunits/assembly factors. The results included a significant abundance of previously identified sites (e.g. NRF1, NRF2, ERRA and YY1), as well as several sites that had not been previously detected. Although we identified patterns that correlated to OXPHOS gene expression, we did not detect an OXPHOS complex-specific arrangement of transcription factor binding sites within the core promoter that could explain the tight co-expression of these functionally related genes. Conclusion: This study mapped the core promoters of most OXPHOS related genes and provided an example of gene expression regulation based on the final protein arrangement within a linear metabolic pathway. [ABSTRACT FROM AUTHOR]

Published

2008

30. Specific elimination of mutant mitochondrial genomes in patient-derived cells by mitoTALENs.

Author

Bacman, Sandra R, Williams, Siôn L, Pinto, Milena, Peralta, Susana, and Moraes, Carlos T

Subjects

MITOCHONDRIAL pathology, MITOCHONDRIAL DNA, GENE expression, XENOGRAFTS, GENETIC mutation

Abstract

Mitochondrial diseases are commonly caused by mutated mitochondrial DNA (mtDNA), which in most cases coexists with wild-type mtDNA, resulting in mtDNA heteroplasmy. We have engineered transcription activator-like effector nucleases (TALENs) to localize to mitochondria and cleave different classes of pathogenic mtDNA mutations. Mitochondria-targeted TALEN (mitoTALEN) expression led to permanent reductions in deletion or point-mutant mtDNA in patient-derived cells, raising the possibility that these mitochondrial nucleases can be therapeutic for some mitochondrial diseases. [ABSTRACT FROM AUTHOR]

Published

2013

31. Adrenoleukodystrophy and the mitochondrial connection: clues for supplementing Lorenzo’s oil.

Author

Moraes, Carlos T.

Subjects

*ADRENOLEUKODYSTROPHY, *MITOCHONDRIAL DNA, *NEUROLOGY, *NEUROLOGICAL disorders, *FATTY acid oxidation, *BIOACCUMULATION

Published

2013

32. L-Arginine Reduces Nitro-Oxidative Stress in Cultured Cells with Mitochondrial Deficiency.

Author

Barros, Camila D. S., Livramento, Jomênica B., Mouro, Margaret G., Higa, Elisa Mieko Suemitsu, Moraes, Carlos T., Tengan, Celia Harumi, Iacone, Roberto, and Valerio, Alessandra

Abstract

L-Arginine (L-ARG) supplementation has been suggested as a therapeutic option in several diseases, including Mitochondrial Encephalomyopathy, Lactic Acidosis, and Stroke-like syndrome (MELAS), arguably the most common mitochondrial disease. It is suggested that L-ARG, a nitric oxide (NO) precursor, can restore NO levels in blood vessels, improving cerebral blood flow. However, NO also participates in mitochondrial processes, such as mitochondrial biogenesis, the regulation of the respiratory chain, and oxidative stress. This study investigated the effects of L-ARG on mitochondrial function, nitric oxide synthesis, and nitro-oxidative stress in cell lines harboring the MELAS mitochondrial DNA (mtDNA) mutation (m.3243A>G). We evaluated mitochondrial enzyme activity, mitochondrial mass, NO concentration, and nitro-oxidative stress. Our results showed that m.3243A>G cells had increased NO levels and protein nitration at basal conditions. Treatment with L-ARG did not affect the mitochondrial function and mass but reduced the intracellular NO concentration and nitrated proteins in m.3243A>G cells. The same treatment led to opposite effects in control cells. In conclusion, we showed that the main effect of L-ARG was on protein nitration. Lowering protein nitration is probably involved in the mechanism related to L-ARG supplementation benefits in MELAS patients. [ABSTRACT FROM AUTHOR]

Published

2021

33. Absence of both MGME1 and POLG EXO abolishes mtDNA whereas absence of either creates unique mtDNA duplications.

Author

Gonzalez, Christian D., Nissanka, Nadee, Van Booven, Derek, Griswold, Anthony J., and Moraes, Carlos T.

Subjects

*MITOCHONDRIAL DNA, *DOUBLE-strand DNA breaks, *NUCLEOTIDE sequencing

Abstract

Both POLG and MGME1 are needed for mitochondrial DNA (mtDNA) maintenance in animal cells. POLG, the primary replicative polymerase of the mitochondria, has an exonuclease activity (3'→5') that corrects for the misincorporation of bases. MGME1 serves as an exonuclease (5'→3'), producing ligatable DNA ends. Although both have a critical role in mtDNA replication and elimination of linear fragments, these mechanisms are still not fully understood. Using digital PCR to evaluate and compare mtDNA integrity, we show that Mgme1 knock out (Mgme1 KK) tissue mtDNA is more fragmented than POLG exonuclease--deficient "Mutator" (Polg MM) or WT tissue. In addition, next generation sequencing of mutant hearts showed abundant duplications in/nearby the D-loop region and unique 100 bp duplications evenly spaced throughout the genome only in Mgme1 KK hearts. However, despite these unique mtDNA features at steady-state, we observed a similar delay in the degradation of mtDNA after an induced double strand DNA break in both Mgme1 KK and Polg MM models. Lastly, we characterized double mutant (Polg MM/Mgme1 KK) cells and show that mtDNA cannot be maintained without at least one of these enzymatic activities. We propose a model for the generation of these genomic abnormalities which suggests a role for MGME1 outside of nascent mtDNA end ligation. Our results highlight the role of MGME1 in and outside of the D-loop region during replication, support the involvement of MGME1 in dsDNA degradation, and demonstrate that POLG EXO and MGME1 can partially compensate for each other in maintaining mtDNA. [ABSTRACT FROM AUTHOR]

Published

2024

34. Mechanisms of Mitochondrial DNA Deletion Formation.

Author

Nissanka, Nadee, Minczuk, Michal, and Moraes, Carlos T.

Subjects

*MITOCHONDRIAL DNA, *DOUBLE-strand DNA breaks, *OXIDATIVE phosphorylation, *MITOCHONDRIAL pathology, *DNA replication

Abstract

Mitochondrial DNA (mtDNA) encodes a subset of genes which are essential for oxidative phosphorylation. Deletions in the mtDNA can ablate a number of these genes and result in mitochondrial dysfunction, which is associated with bona fide mitochondrial disorders. Although mtDNA deletions are thought to occur as a result of replication errors or following double-strand breaks, the exact mechanism(s) behind deletion formation have yet to be determined. In this review we discuss the current knowledge about the fate of mtDNA following double-strand breaks, including the molecular players which mediate the degradation of linear mtDNA fragments and possible mechanisms of recircularization. We propose that mtDNA deletions formed from replication errors versus following double-strand breaks can be mediated by separate pathways. Highlights Mitochondrial DNA deletions lead to bona fide mitochondrial disorders but the mechanisms behind their formation is unknown. It has been observed that deletions can form from errors in replication or following double-strand breaks. Analysis of deletion breakpoints reveal breakpoints flanked by either direct repeats or imperfect/micro-homologies, implicating two different mechanisms for deletion formation. Mitochondrial DNA is rapidly degraded following double-strand breaks, and recent studies have identified some of the molecular players which mediate this degradation. [ABSTRACT FROM AUTHOR]

Published

2019

35. Loss of Mcl-1 Protein and Inhibition of Electron Transport Chain Together Induce Anoxic Cell Death.

Author

Brunelle, Joslyn K., Shroff, Emelyn H., Perlman, Harris, Strasser, Andreas, Moraes, Carlos T., Flavell, Richard A., Danial, Nika N., Keith, Brian, Thompson, Craig B., and Chandel, Navdeep S.

Subjects

CELL death, HYPOXEMIA, MITOCHONDRIAL DNA, PROTEINS, CELLS

Abstract

How cells die in the absence of oxygen (anoxia) is not understood. Here we report that cells deficient in Bax and Bak or caspase-9 do not undergo anoxia-induced cell death. However, the caspase-9 null cells do not survive reoxygenation due to the generation of mitochondrial reactive oxygen species. The individual loss of Bim, Bid, Puma, Noxa, Bad, caspase-2, or hypoxia-inducible factor 1ß, which are potential upstream regulators of Bax or Bak, did not prevent anoxia-induced cell death. Anoxia triggered the loss of the Mcl-1 protein upstream of Bax/Bak activation. Cells containing a mitochondrial DNA cytochrome b 4-base-pair deletion ([rho-] cells) and cells depleted of their entire mitochondrial DNA ([rho0] cells) are oxidative phosphorylation incompetent and displayed loss of the Mcl-1 protein under anoxia. [rho0] cells, in contrast to [rho-] cells, did not die under anoxia. However, [rho0] cells did undergo cell death in the presence of the Bad BH3 peptide, an inhibitor of Bcl-XL/Bcl-2 proteins. These results indicate that [rho0] cells survive under anoxia despite the loss of Mcl-1 protein due to residual prosurvival activity of the Bcl-XL/Bcl-2 proteins. Collectively, these results demonstrate that anoxia-induced cell death requires the loss of Mcl-1 protein and inhibition of the electron transport chain to negate Bcl-XL/Bcl-2 proteins. [ABSTRACT FROM AUTHOR]

Published

2007

36. Precise and simultaneous quantification of mitochondrial DNA heteroplasmy and copy number by digital PCR.

Author

Shoop, Wendy K., Gorsuch, Cassandra L., Bacman, Sandra R., and Moraes, Carlos T.

Subjects

*MITOCHONDRIAL DNA, *GENETIC variation, *MITOCHONDRIA

Abstract

Mitochondrial DNA (mtDNA) is present in multiple copies and phenotypic consequences of mtDNA mutations depend on the mutant load surpassing a specific threshold. Additionally, changes in mtDNA copy number can impact mitochondrial ATP production, resulting in disease. Therefore, the precise determination of mtDNA heteroplasmy and copy number is crucial to the study of mitochondrial diseases. However, current methods can be imprecise, and quantifying small changes in either heteroplasmy or copy number is challenging. We developed a new approach to measure mtDNA heteroplasmy using a single digital PCR (dPCR) probe. This method is based on the observation that fluorescent-labeled probes in dPCR exhibit different intensities depending on the presence of a single nucleotide change in the sequence bound by the probe. This finding allowed us to precisely and simultaneously determine mtDNA copy number and heteroplasmy levels using duplex dPCR. We tested this approach in two different models (human and mouse), which proved faster and more internally controlled when compared to other published methods routinely used in the mitochondrial genetics field. We believe this approach could be broadly applicable to the detection and quantification of other mixed genetic variations. [ABSTRACT FROM AUTHOR]

Published

2022

37. Erythromycin as a potential precipitating agent in the onset of Leber's hereditary optic neuropathy

Author

Luca, Corneliu C., Lam, Byron L., and Moraes, Carlos T.

Subjects

*ERYTHROMYCIN, *MITOCHONDRIAL DNA, *OXIDOREDUCTASES, *NEUROPATHY, *OSTEOSARCOMA

Abstract

A 23-years-old male entered a safety clinical trial for cetirizine (a selective histamine H1-receptor antagonist) in combination with the antibiotic erythromycin. Within a few weeks of finishing the trial, the patient reported bilateral vision loss with optic nerve atrophy. Genetic studies showed that he had a mitochondrial DNA (mtDNA) mutation at position 11778 (within the gene for subunit 4 of NADH-coenzyme Q oxidoreductase), commonly associated with Leber''s hereditary optic neuropathy. To test if erythromycin could worsen the mitochondrial respiratory chain defect associated with the 11778 mtDNA mutation, we transferred the patient''s mtDNA to cultured mtDNA-less osteosarcoma cells. Erythromycin inhibited proliferation of the patient''s transmitochondrial cybrids in conditions that required mitochondrial respiration for growth. We confirmed that erythromycin is a potent inhibitor of mitochondrial translation in these cells. Taken together, these results suggest that erythromycin may have hastened a bioenergetics crisis in the optic nerve of this patient. This association underscores the importance of being cautious with the use of drugs that interfere with cellular respiration in individuals with an underlying mitochondrial dysfunction. [Copyright &y& Elsevier]

Published

2004

38. Mitochondrial methionyl N-formylation affects steady-state levels of oxidative phosphorylation complexes and their organization into supercomplexes.

Author

Arguello, Tania, Köhrer, Caroline, RajBhandary, Uttam L., and Moraes, Carlos T.

Subjects

*MITOCHONDRIAL DNA, *STEADY state conduction, *PHOSPHORYLATION, *COMPLEX compounds, *PROTEIN synthesis

Abstract

N-Formylation of the Met-tRNAMet by the nuclearly encodedmitochondrial methionyl-tRNA formyltransferase (MTFMT) has been found to be a key determinant of protein synthesis initiation in mitochondria. In humans, mutations in the MTFMTgene result in Leigh syndrome, a progressive and severe neurometabolic disorder. However, the absolute requirement of formylation of Met-tRNAMet for protein synthesis in mammalian mitochondria is still debated. Here, we generated a Mtfmt-KO mouse fibroblast cell line and demonstrated that N-formylation of the first methionine via fMet-tRNAMet by MTFMTis not an absolute requirement for initiation of protein synthesis. However, it differentially affected the efficiency of synthesis of mtDNA-coded polypeptides. Lack of methionine N-formylation did not compromise the stability of these individual subunits but had a marked effect on the assembly and stability of the OXPHOS complexes I and IV and on their supercomplexes. In summary, N-formylation is not essential for mitochondrial protein synthesis but is critical for efficient synthesis of several mitochondrially encoded peptides and for OXPHOS complex stability and assembly into supercomplexes. [ABSTRACT FROM AUTHOR]

Published

2018

39. MitoTALEN: A General Approach to Reduce Mutant mtDNA Loads and Restore Oxidative Phosphorylation Function in Mitochondrial Diseases.

Author

Hashimoto, Masami, Bacman, Sandra R, Peralta, Susana, Falk, Marni J, Chomyn, Anne, Chan, David C, Williams, Sion L, and Moraes, Carlos T

Subjects

*MITOCHONDRIAL DNA, *GENETIC disorders, *OXIDATIVE phosphorylation, *NUCLEASES, *EPILEPSY

Abstract

We have designed mitochondrially targeted transcription activator-like effector nucleases or mitoTALENs to cleave specific sequences in the mitochondrial DNA (mtDNA) with the goal of eliminating mtDNA carrying pathogenic point mutations. To test the generality of the approach, we designed mitoTALENs to target two relatively common pathogenic mtDNA point mutations associated with mitochondrial diseases: the m.8344A>G tRNALys gene mutation associated with myoclonic epilepsy with ragged red fibers (MERRF) and the m.13513G>A ND5 mutation associated with MELAS/Leigh syndrome. Transmitochondrial cybrid cells harbouring the respective heteroplasmic mtDNA mutations were transfected with the respective mitoTALEN and analyzed after different time periods. MitoTALENs efficiently reduced the levels of the targeted pathogenic mtDNAs in the respective cell lines. Functional assays showed that cells with heteroplasmic mutant mtDNA were able to recover respiratory capacity and oxidative phosphorylation enzymes activity after transfection with the mitoTALEN. To improve the design in the context of the low complexity of mtDNA, we designed shorter versions of the mitoTALEN specific for the MERRF m.8344A>G mutation. These shorter mitoTALENs also eliminated the mutant mtDNA. These reductions in size will improve our ability to package these large sequences into viral vectors, bringing the use of these genetic tools closer to clinical trials. [ABSTRACT FROM AUTHOR]

Published

2015

40. Mitochondrial DNA damage in a mouse model of Alzheimer's disease decreases amyloid beta plaque formation.

Author

Pinto, Milena, Pickrell, Alicia M., Fukui, Hirokazu, and Moraes, Carlos T.

Subjects

*MITOCHONDRIAL DNA, *DNA damage, *ANIMAL models of Alzheimer's disease, *LABORATORY mice, *DISEASE progression, *OXYGEN in the body, *GENE expression

Abstract

Abstract: Mitochondrial DNA (mtDNA) damage and the generation of reactive oxygen species have been associated with and implicated in the development and progression of Alzheimer's disease. To study how mtDNA damage affects reactive oxygen species and amyloid beta (Aβ) pathology in vivo, we generated an Alzheimer's disease mouse model expressing an inducible mitochondrial-targeted endonuclease (Mito-PstI) in the central nervous system. Mito-PstI cleaves mtDNA causing mostly an mtDNA depletion, which leads to a partial oxidative phosphorylation defect when expressed during a short period in adulthood. We found that a mild mitochondrial dysfunction in adult neurons did not exacerbate Aβ accumulation and decreased plaque pathology. Mito-PstI expression altered the cleavage pathway of amyloid precursor protein without increasing oxidative stress in the brain. These data suggest that mtDNA damage is not a primary cause of Aβ accumulation. [Copyright &y& Elsevier]

Published

2013

41. Limitations of Allotopic Expression of Mitochondrial Genes in Mammalian Cells.

Author

Oca-Cossio, Jose, Kenyon, Lesley, Huiling Hao, Lesley, and Moraes, Carlos T.

Subjects

*MITOCHONDRIA, *MITOCHONDRIAL DNA, *NUCLEOTIDE sequence, *MAMMALS

Abstract

The possibility of expressing mitochondrial DNA-coded genes in the nuclear-cytoplasmic compartment provides an attractive system for genetic treatment of mitochondrial disorders associated with mitochondrial DNA mutations. In theory by recoding mitochondrial genes to adapt them to the universal genetic code and by adding a DNA sequence coding for a mitochondrial-targeting sequence, one could achieve correct localization of the gene product. Such transfer has occurred in nature, and certain species of algae and plants express a number of polypeptides that are commonly coded by mtDNA in the nuclear-cytoplasmic compartment. In the present study, allotopic expression of three different mtDNA-coded polypeptides (ATPase8, apocytochrome b, and ND4) into COS-7 and HeLa cells was analyzed. Among these, only ATPase8 was correctly expressed and localized to mitochondria. The full-length, as well as truncated forms, of apocytochrome b and ND4 decorated the periphery of mitochondria, but also aggregated in fiber-like structures containing tubulin and in some cases also vimentin. The addition of a hydrophilic tail (EGFP) to the C terminus of these polypeptides did not change their localization. Overexpression of molecular chaperones also did not have a significant effect in preventing aggregations. Allotopic expression of apocytochrome b and ND4 induced a loss of mitochondrial membrane potential in transfected cells, which can lead to cell death. Our observations suggest that only a subset of mitochondrial genes can be replaced allotopically. Analyses of the hydrophobic patterns of different polypeptides suggest that hydrophobicity of the N-terminal segment is the main determinant for the importability of peptides into mammalian mitochondria. [ABSTRACT FROM AUTHOR]

Published

2003

42. BCL-2 Improves Oxidative Phosphorylation and Modulates Adenine Nucleotide Translocation in Mitochondria of Cells Harboring Mutant mtDNA.

Author

Manfredi, Giovanni, Kwong, Jennifer Q., Oca-Cossio, Josè A., Woischnik, Markus, Gajewski, Carl D., Martushova, Katherine, D'Aurelio, Marilena, Friedlich, Avi L., and Moraes, Carlos T.

Subjects

*GENE expression, *MITOCHONDRIAL DNA, *PHOSPHORYLATION

Abstract

Studies the effect of BCL-2 and BCL-x[sb L] overexpression on mitochondrial and cytosolic AT pools in human transmitochondrial cybrid lines containing normal and mtDNA, mutated mtDNA causing defective respiratory chains. Finding that BCL-2 improves oxidative phosphorylation and modulates adenine nucleotide translocation in mitochondria of cells harboring mutant mDNA; Ability of BCL-2 to regulate respiratory functions in response to mitochondrial distress.

Published

2003

43. mitoTALENs as DNA editing tools for mitochondrial diseases.

Author

Bacman, Sandra R., Hashimoto, Masami, Peralta, Susana, Falk, Marni J., Chomyn, Anne, Chan, David C., Williams, Sion L., and Moraes, Carlos T.

Subjects

*LEIGH disease, *MITOCHONDRIAL pathology, *MITOCHONDRIAL DNA, *GENOMES, *GENETIC mutation, *PROTEIN expression, *GENETICS

Published

2015