Your search keyword '"Nicholls, Thomas J."' showing total 12 results

1. Separating and Segregating the Human Mitochondrial Genome.

Author

Nicholls, Thomas J. and Gustafsson, Claes M.

Subjects

*HUMAN mitochondrial DNA, *MITOCHONDRIAL DNA, *DNA replication, *GENOMES, *NUCLEOPROTEINS

Abstract

Cells contain thousands of copies of the mitochondrial genome. These genomes are distributed within the tubular mitochondrial network, which is itself spread across the cytosol of the cell. Mitochondrial DNA (mtDNA) replication occurs throughout the cell cycle and ensures that cells maintain a sufficient number of mtDNA copies. At replication termination the genomes must be resolved and segregated within the mitochondrial network. Defects in mtDNA replication and segregation are a cause of human mitochondrial disease associated with failure of cellular energy production. This review focuses upon recent developments on how mitochondrial genomes are physically separated at the end of DNA replication, and how these genomes are subsequently segregated and distributed around the mitochondrial network. Highlights mtDNA is packaged into a nucleoprotein complex called the nucleoid. Most nucleoids consist of a single mtDNA molecule, compacted with the packaging factor TFAM. mtDNA is replicated from two major origins using a set of nucleus-encoded factors distinct from those involved in nuclear DNA replication. At replication termination the genomes remain interlinked, and require the action of a mitochondrial isoform of TOP3α for their resolution. mtDNA is associated with the inner mitochondrial membrane (IMM) in the vicinity of contact sites with the endoplasmic reticulum. The separation and distribution of nucleoids are affected by factors involved in mitochondrial dynamics, IMM structure, and membrane composition. Mitochondrial fission is implicated in mtDNA segregation by dividing the replicated genomes into separate mitochondria. [ABSTRACT FROM AUTHOR]

Published

2018

2. Mutations in GTPBP3 Cause a Mitochondrial Translation Defect Associated with Hypertrophic Cardiomyopathy, Lactic Acidosis, and Encephalopathy.

Author

Kopajtich, Robert, Nicholls, Thomas J., Rorbach, Joanna, Metodiev, Metodi D., Freisinger, Peter, Mandel, Hanna, Vanlander, Arnaud, Ghezzi, Daniele, Carrozzo, Rosalba, Taylor, Robert W., Marquard, Klaus, Murayama, Kei, Wieland, Thomas, Schwarzmayr, Thomas, Mayr, Johannes A., Pearce, Sarah F., Powell, Christopher A., Saada, Ann, Ohtake, Akira, and Invernizzi, Federica

Subjects

*GENETIC mutation, *MITOCHONDRIAL pathology, *GENETIC translation, *HYPERTROPHIC cardiomyopathy, *LACTIC acidosis, *HEPATIC encephalopathy

Abstract

Respiratory chain deficiencies exhibit a wide variety of clinical phenotypes resulting from defective mitochondrial energy production through oxidative phosphorylation. These defects can be caused by either mutations in the mtDNA or mutations in nuclear genes coding for mitochondrial proteins. The underlying pathomechanisms can affect numerous pathways involved in mitochondrial physiology. By whole-exome and candidate gene sequencing, we identified 11 individuals from 9 families carrying compound heterozygous or homozygous mutations in GTPBP3 , encoding the mitochondrial GTP-binding protein 3. Affected individuals from eight out of nine families presented with combined respiratory chain complex deficiencies in skeletal muscle. Mutations in GTPBP3 are associated with a severe mitochondrial translation defect, consistent with the predicted function of the protein in catalyzing the formation of 5-taurinomethyluridine (τm 5 U) in the anticodon wobble position of five mitochondrial tRNAs. All case subjects presented with lactic acidosis and nine developed hypertrophic cardiomyopathy. In contrast to individuals with mutations in MTO1 , the protein product of which is predicted to participate in the generation of the same modification, most individuals with GTPBP3 mutations developed neurological symptoms and MRI involvement of thalamus, putamen, and brainstem resembling Leigh syndrome. Our study of a mitochondrial translation disorder points toward the importance of posttranscriptional modification of mitochondrial tRNAs for proper mitochondrial function. [ABSTRACT FROM AUTHOR]

Published

2014

3. In D-loop: 40years of mitochondrial 7S DNA.

Author

Nicholls, Thomas J. and Minczuk, Michal

Subjects

*MITOCHONDRIAL DNA, *MOLECULAR biology, *ORIGIN of life, *NON-coding DNA, *DNA synthesis

Abstract

Abstract: Given the tiny size of the mammalian mitochondrial genome, at only 16.5kb, it is often surprising how little we know about some of its molecular features, and the molecular mechanisms governing its maintenance. One such conundrum is the biogenesis and function of the mitochondrial displacement loop (D-loop). The mitochondrial D-loop is a triple-stranded region found in the major non-coding region (NCR) of many mitochondrial genomes, and is formed by stable incorporation of a third, short DNA strand known as 7S DNA. In this article we review the current affairs regarding the main features of the D-loop structure, the diverse frequency of D-loops in the mtDNAs of various species and tissues, and also the mechanisms of its synthesis and turnover. This is followed by an account of the possible functions of the mitochondrial D-loop that have been proposed over the last four decades. In the last section, we discuss the potential links of the D-loop with mammalian ageing. [Copyright &y& Elsevier]

Published

2014

4. Mitochondria: Mitochondrial RNA metabolism and human disease

Author

Nicholls, Thomas J., Rorbach, Joanna, and Minczuk, Michal

Subjects

*MITOCHONDRIAL pathology, *MITOCHONDRIAL RNA, *GENETIC regulation, *GENETIC code, *GENETIC mutation, *PROTEIN metabolism

Abstract

Abstract: Post-transcriptional control of RNA stability, processing, modification, and degradation is key to the regulation of gene expression in all living cells. In mitochondria, these post-transcriptional processes are also vital for proper expression of the thirteen proteins encoded by the mitochondrial genome, as well as mitochondrial tRNAs and rRNAs. Our knowledge on mitochondrial RNA (mt-RNA) metabolic pathways, however, is far from complete. All the proteins involved in mt-RNA metabolism are encoded by the nucleus, and must be imported into the organelle. Mutations in these nuclear genes can lead to perturbations in mitochondrial RNA processing, modification, stability and decay and thus are a cause of human mitochondrial disease. This review summarises the current knowledge on mt-RNA metabolism and its links with human mitochondrial pathologies. [Copyright &y& Elsevier]

Published

2013

5. Loss-of-function mutations in MGME1 impair mtDNA replication and cause multisystemic mitochondrial disease.

Author

Kornblum, Cornelia, Nicholls, Thomas J, Haack, Tobias B, Schöler, Susanne, Peeva, Viktoriya, Danhauser, Katharina, Hallmann, Kerstin, Zsurka, Gábor, Rorbach, Joanna, Iuso, Arcangela, Wieland, Thomas, Sciacco, Monica, Ronchi, Dario, Comi, Giacomo P, Moggio, Maurizio, Quinzii, Catarina M, DiMauro, Salvatore, Calvo, Sarah E, Mootha, Vamsi K, and Klopstock, Thomas

Subjects

*FUNCTIONAL loss in older people, *GENETIC mutation, *MITOCHONDRIAL DNA, *DNA replication, *MITOCHONDRIAL pathology, *ETIOLOGY of diseases, *FIBROBLASTS

Abstract

Known disease mechanisms in mitochondrial DNA (mtDNA) maintenance disorders alter either the mitochondrial replication machinery (POLG, POLG2 and C10orf2) or the biosynthesis pathways of deoxyribonucleoside 5?-triphosphates for mtDNA synthesis. However, in many of these disorders, the underlying genetic defect has yet to be discovered. Here, we identify homozygous nonsense and missense mutations in the orphan gene C20orf72 in three families with a mitochondrial syndrome characterized by external ophthalmoplegia, emaciation and respiratory failure. Muscle biopsies showed mtDNA depletion and multiple mtDNA deletions. C20orf72, hereafter MGME1 (mitochondrial genome maintenance exonuclease 1), encodes a mitochondrial RecB-type exonuclease belonging to the PD-(D/E)XK nuclease superfamily. We show that MGME1 cleaves single-stranded DNA and processes DNA flap substrates. Fibroblasts from affected individuals do not repopulate after chemically induced mtDNA depletion. They also accumulate intermediates of stalled replication and show increased levels of 7S DNA, as do MGME1-depleted cells. Thus, we show that MGME1-mediated mtDNA processing is essential for mitochondrial genome maintenance. [ABSTRACT FROM AUTHOR]

Published

2013

6. Dinucleotide Degradation by REXO2 Maintains Promoter Specificity in Mammalian Mitochondria.

Author

Nicholls, Thomas J., Spåhr, Henrik, Jiang, Shan, Siira, Stefan J., Koolmeister, Camilla, Sharma, Sushma, Kauppila, Johanna H.K., Jiang, Min, Kaever, Volkhard, Rackham, Oliver, Chabes, Andrei, Falkenberg, Maria, Filipovska, Aleksandra, Larsson, Nils-Göran, and Gustafsson, Claes M.

Subjects

*MITOCHONDRIA, *EMBRYOLOGY, *DINUCLEOTIDES, *HUMAN embryology, *KNOCKOUT mice, *GENE expression

Abstract

Oligoribonucleases are conserved enzymes that degrade short RNA molecules of up to 5 nt in length and are assumed to constitute the final stage of RNA turnover. Here we demonstrate that REXO2 is a specialized dinucleotide-degrading enzyme that shows no preference between RNA and DNA dinucleotide substrates. A heart- and skeletal-muscle-specific knockout mouse displays elevated dinucleotide levels and alterations in gene expression patterns indicative of aberrant dinucleotide-primed transcription initiation. We find that dinucleotides act as potent stimulators of mitochondrial transcription initiation in vitro. Our data demonstrate that increased levels of dinucleotides can be used to initiate transcription, leading to an increase in transcription levels from both mitochondrial promoters and other, nonspecific sequence elements in mitochondrial DNA. Efficient RNA turnover by REXO2 is thus required to maintain promoter specificity and proper regulation of transcription in mammalian mitochondria. • REXO2 is a specialized dinucleotidase present in mammalian mitochondria • REXO2 is essential for embryonic development in mice • Dinucleotides stimulate mitochondrial transcription in vitro and in vivo • Dinucleotide degradation is required to prevent their use as transcription primers Nicholls et al. study the function of the human oligoribonuclease REXO2 and find that it is a specialized dinucleotidase. The Rexo2 gene is essential for embryonic development, and its conditional loss results in changes to mitochondrial transcription patterns, indicating the use of dinucleotides for promoter-independent mitochondrial transcription initiation. [ABSTRACT FROM AUTHOR]

Published

2019

7. Mechanisms and pathologies of human mitochondrial DNA replication and deletion formation.

Author

Gomes, Tiago M. Bernardino, Vincent, Amy E., Menger, Katja E., Stewart, James B., and Nicholls, Thomas J.

Subjects

*MITOCHONDRIAL DNA, *HUMAN DNA, *DELETION mutation, *DNA replication, *MITOCHONDRIAL pathology, *RECESSIVE genes, *ENERGY metabolism

Abstract

Human mitochondria possess a multi-copy circular genome, mitochondrial DNA (mtDNA), that is essential for cellular energy metabolism. The number of copies of mtDNA per cell, and their integrity, are maintained by nuclear-encoded mtDNA replication and repair machineries. Aberrant mtDNA replication and mtDNA breakage are believed to cause deletions within mtDNA. The genomic location and breakpoint sequences of these deletions show similar patterns across various inherited and acquired diseases, and are also observed during normal ageing, suggesting a common mechanism of deletion formation. However, an ongoing debate over the mechanism by which mtDNA replicates has made it difficult to develop clear and testable models for how mtDNA rearrangements arise and propagate at a molecular and cellular level. These deletions may impair energy metabolism if present in a high proportion of the mtDNA copies within the cell, and can be seen in primary mitochondrial diseases, either in sporadic cases or caused by autosomal variants in nuclear-encoded mtDNA maintenance genes. These mitochondrial diseases have diverse genetic causes and multiple modes of inheritance, and show notoriously broad clinical heterogeneity with complex tissue specificities, which further makes establishing genotype-phenotype relationships challenging. In this review, we aim to cover our current understanding of how the human mitochondrial genome is replicated, the mechanisms by which mtDNA replication and repair can lead to mtDNA instability in the form of large-scale rearrangements, how rearranged mtDNAs subsequently accumulate within cells, and the pathological consequences when this occurs. [ABSTRACT FROM AUTHOR]

Published

2024

8. Topoisomerase 3α Is Required for Decatenation and Segregation of Human mtDNA.

Author

Nicholls, Thomas J., Nadalutti, Cristina A., Motori, Elisa, Sommerville, Ewen W., Gorman, Gráinne S., Basu, Swaraj, Hoberg, Emily, Turnbull, Doug M., Chinnery, Patrick F., Larsson, Nils-Göran, Larsson, Erik, Falkenberg, Maria, Taylor, Robert W., Griffith, Jack D., and Gustafsson, Claes M.

Subjects

*DNA topoisomerases, *MITOCHONDRIAL DNA, *MITOCHONDRIAL enzymes, *CHROMOSOME segregation, *DNA separation, *CHRONIC progressive external opthalmoplegia

Abstract

Summary How mtDNA replication is terminated and the newly formed genomes are separated remain unknown. We here demonstrate that the mitochondrial isoform of topoisomerase 3α (Top3α) fulfills this function, acting independently of its nuclear role as a component of the Holliday junction-resolving BLM-Top3α-RMI1-RMI2 (BTR) complex. Our data indicate that mtDNA replication termination occurs via a hemicatenane formed at the origin of H-strand replication and that Top3α is essential for resolving this structure. Decatenation is a prerequisite for separation of the segregating unit of mtDNA, the nucleoid, within the mitochondrial network. The importance of this process is highlighted in a patient with mitochondrial disease caused by biallelic pathogenic variants in TOP3A , characterized by muscle-restricted mtDNA deletions and chronic progressive external ophthalmoplegia (CPEO) plus syndrome. Our work establishes Top3α as an essential component of the mtDNA replication machinery and as the first component of the mtDNA separation machinery. [ABSTRACT FROM AUTHOR]

Published

2018

9. The mitochondrial single-stranded DNA binding protein is essential for initiation of mtDNA replication.

Author

Min Jiang, Xie Xie, Xuefeng Zhu, Shan Jiang, Milenkovic, Dusanka, Misic, Jelena, Yonghong Shi, Tandukar, Nirwan, Xinping Li, Atanassov, Ilian, Jenninger, Louise, Hoberg, Emily, Albarran-Gutierrez, Sara, Szilagyi, Zsolt, Macao, Bertil, Siira, Stefan J., Carelli, Valerio, Griffith, Jack D., Gustafsson, Claes M., and Nicholls, Thomas J.

Subjects

*MITOCHONDRIAL DNA, *SINGLE-stranded DNA, *DNA-binding proteins, *GENE expression, *BIOCHEMICAL models

Abstract

We report a role for the mitochondrial single-stranded DNA binding protein (mtSSB) in regulating mitochondrial DNA (mtDNA) replication initiation in mammalian mitochondria. Transcription from the light-strand promoter (LSP) is required both for gene expression and for generating the RNA primers needed for initiation of mtDNA synthesis. In the absence of mtSSB, transcription from LSP is strongly up-regulated, but no replication primers are formed. Using deep sequencing in a mouse knockout model and biochemical reconstitution experiments with pure proteins, we find that mtSSB is necessary to restrict transcription initiation to optimize RNA primer formation at both origins of mtDNA replication. Last, we show that human pathological versions of mtSSB causing severe mitochondrial disease cannot efficiently support primer formation and initiation of mtDNA replication. [ABSTRACT FROM AUTHOR]

Published

2021

10. The Maintenance of Mitochondrial DNA Integrity and Dynamics by Mitochondrial Membranes.

Author

Chapman, James, Ng, Yi Shiau, and Nicholls, Thomas J.

Subjects

*MITOCHONDRIAL DNA, *MITOCHONDRIAL membranes, *CIRCULAR DNA, *GENETIC mutation, *INTEGRITY, *MITOCHONDRIA

Abstract

Mitochondria are complex organelles that harbour their own genome. Mitochondrial DNA (mtDNA) exists in the form of a circular double-stranded DNA molecule that must be replicated, segregated and distributed around the mitochondrial network. Human cells typically possess between a few hundred and several thousand copies of the mitochondrial genome, located within the mitochondrial matrix in close association with the cristae ultrastructure. The organisation of mtDNA around the mitochondrial network requires mitochondria to be dynamic and undergo both fission and fusion events in coordination with the modulation of cristae architecture. The dysregulation of these processes has profound effects upon mtDNA replication, manifesting as a loss of mtDNA integrity and copy number, and upon the subsequent distribution of mtDNA around the mitochondrial network. Mutations within genes involved in mitochondrial dynamics or cristae modulation cause a wide range of neurological disorders frequently associated with defects in mtDNA maintenance. This review aims to provide an understanding of the biological mechanisms that link mitochondrial dynamics and mtDNA integrity, as well as examine the interplay that occurs between mtDNA, mitochondrial dynamics and cristae structure. [ABSTRACT FROM AUTHOR]

Published

2020

11. The human mitochondrial genome contains a second light strand promoter.

Author

Tan, Benedict G., Mutti, Christian D., Shi, Yonghong, Xie, Xie, Zhu, Xuefeng, Silva-Pinheiro, Pedro, Menger, Katja E., Díaz-Maldonado, Héctor, Wei, Wei, Nicholls, Thomas J., Chinnery, Patrick F., Minczuk, Michal, Falkenberg, Maria, and Gustafsson, Claes M.

Subjects

*HUMAN genome, *HUMAN DNA, *MITOCHONDRIAL DNA, *DNA primers, *DNA replication, *GENE expression, *GENES, *GENOMES

Abstract

The human mitochondrial genome must be replicated and expressed in a timely manner to maintain energy metabolism and supply cells with adequate levels of adenosine triphosphate. Central to this process is the idea that replication primers and gene products both arise via transcription from a single light strand promoter (LSP) such that primer formation can influence gene expression, with no consensus as to how this is regulated. Here, we report the discovery of a second light strand promoter (LSP2) in humans, with features characteristic of a bona fide mitochondrial promoter. We propose that the position of LSP2 on the mitochondrial genome allows replication and gene expression to be orchestrated from two distinct sites, which expands our long-held understanding of mitochondrial gene expression in humans. [Display omitted] • Human mitochondrial DNA (mtDNA) contains an additional light strand promoter (LSP2) • LSP2 contains identical molecular properties to canonical promoters LSP and HSP • Base edits to LSP2 affect mitochondrial gene transcript levels in living cells Mitochondrial DNA replication primers and light strand gene products were both thought to arise via transcription from a single promoter (LSP) in humans for over 40 years. Tan et al. report the discovery of an additional promoter (LSP2) on the human mitochondrial genome. [ABSTRACT FROM AUTHOR]

Published

2022

12. ELAC2 Mutations Cause a Mitochondrial RNA Processing Defect Associated with Hypertrophic Cardiomyopathy.

Author

Haack, Tobias?B., Kopajtich, Robert, Freisinger, Peter, Wieland, Thomas, Rorbach, Joanna, Nicholls, Thomas?J., Baruffini, Enrico, Walther, Anett, Danhauser, Katharina, Zimmermann, Franz?A., Husain, Ralf?A., Schum, Jessica, Mundy, Helen, Ferrero, Ileana, Strom, Tim?M., Meitinger, Thomas, Taylor, Robert?W., Minczuk, Michal, Mayr, Johannes?A., and Prokisch, Holger

Subjects

*GENETIC mutation, *MITOCHONDRIAL RNA, *HYPERTROPHIC cardiomyopathy, *GENETIC code, *FIBROBLASTS, *RIBONUCLEASES

Abstract

The human mitochondrial genome encodes RNA components of its own translational machinery to produce the 13 mitochondrial-encoded subunits of the respiratory chain. Nuclear-encoded gene products are essential for all processes within the organelle, including RNA processing. Transcription of the mitochondrial genome generates large polycistronic transcripts punctuated by the 22 mitochondrial (mt) tRNAs that are conventionally cleaved by the RNase P-complex and the RNase Z activity of ELAC2 at 5′ and 3′ ends, respectively. We report the identification of mutations in ELAC2 in five individuals with infantile hypertrophic cardiomyopathy and complex I deficiency. We observed accumulated mtRNA precursors in affected individuals muscle and fibroblasts. Although mature mt-tRNA, mt-mRNA, and mt-rRNA levels were not decreased in fibroblasts, the processing defect was associated with impaired mitochondrial translation. Complementation experiments in mutant cell lines restored RNA processing and a yeast model provided additional evidence for the disease-causal role of defective ELAC2, thereby linking mtRNA processing to human disease. [ABSTRACT FROM AUTHOR]

Published

2013