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

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

Author

Bernardino Gomes TM, Vincent AE, Menger KE, Stewart JB, and Nicholls TJ

Subjects

Humans, Sequence Deletion, Genome, Mitochondrial, Mitochondria genetics, Mitochondria metabolism, DNA Repair, DNA, Mitochondrial genetics, DNA, Mitochondrial metabolism, DNA Replication, Mitochondrial Diseases genetics, Mitochondrial Diseases metabolism, Mitochondrial Diseases pathology

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., (© 2024 The Author(s).)

Published

2024

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

Author

Jiang M, Xie X, Zhu X, Jiang S, Milenkovic D, Misic J, Shi Y, Tandukar N, Li X, Atanassov I, Jenninger L, Hoberg E, Albarran-Gutierrez S, Szilagyi Z, Macao B, Siira SJ, Carelli V, Griffith JD, Gustafsson CM, Nicholls TJ, Filipovska A, Larsson NG, and Falkenberg M

Subjects

Animals, DNA, Mitochondrial genetics, DNA, Mitochondrial metabolism, HeLa Cells, Humans, Mammals genetics, Mice, Mitochondria genetics, Mitochondria metabolism, DNA Replication, DNA-Binding Proteins genetics, DNA-Binding Proteins metabolism

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., (Copyright © 2021 The Authors, some rights reserved; exclusive licensee American Association for the Advancement of Science. No claim to original U.S. Government Works. Distributed under a Creative Commons Attribution NonCommercial License 4.0 (CC BY-NC).)

Published

2021

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

Author

Nicholls TJ, Nadalutti CA, Motori E, Sommerville EW, Gorman GS, Basu S, Hoberg E, Turnbull DM, Chinnery PF, Larsson NG, Larsson E, Falkenberg M, Taylor RW, Griffith JD, and Gustafsson CM

Subjects

Cell Line, Tumor, DNA, Mitochondrial genetics, HeLa Cells, Humans, Mitochondria genetics, Mitochondrial Diseases genetics, Ophthalmoplegia, Chronic Progressive External genetics, Chromosome Segregation genetics, DNA Replication genetics, DNA Topoisomerases, Type I metabolism, DNA, Mitochondrial biosynthesis, Mitochondrial Dynamics genetics

Abstract

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., (Copyright © 2017 Elsevier Inc. All rights reserved.)

Published

2018

4. MGME1 processes flaps into ligatable nicks in concert with DNA polymerase γ during mtDNA replication.

Author

Uhler JP, Thörn C, Nicholls TJ, Matic S, Milenkovic D, Gustafsson CM, and Falkenberg M

Subjects

Cell-Free System metabolism, Cloning, Molecular, DNA Cleavage, DNA Polymerase gamma, DNA, Mitochondrial metabolism, DNA, Single-Stranded metabolism, DNA-Directed DNA Polymerase metabolism, Escherichia coli genetics, Escherichia coli metabolism, Exodeoxyribonucleases metabolism, Gene Expression, Humans, Recombinant Proteins genetics, Recombinant Proteins metabolism, DNA Replication, DNA, Mitochondrial genetics, DNA, Single-Stranded genetics, DNA-Directed DNA Polymerase genetics, Exodeoxyribonucleases genetics

Abstract

Recently, MGME1 was identified as a mitochondrial DNA nuclease with preference for single-stranded DNA (ssDNA) substrates. Loss-of-function mutations in patients lead to mitochondrial disease with DNA depletion, deletions, duplications and rearrangements. Here, we assess the biochemical role of MGME1 in the processing of flap intermediates during mitochondrial DNA replication using reconstituted systems. We show that MGME1 can cleave flaps to enable efficient ligation of newly replicated DNA strands in combination with POLγ. MGME1 generates a pool of imprecisely cut products (short flaps, nicks and gaps) that are converted to ligatable nicks by POLγ through extension or excision of the 3'-end strand. This is dependent on the 3'-5' exonuclease activity of POLγ which limits strand displacement activity and enables POLγ to back up to the nick by 3'-5' degradation. We also demonstrate that POLγ-driven strand displacement is sufficient to generate DNA- but not RNA-flap substrates suitable for MGME1 cleavage and ligation during replication. Our findings have implications for RNA primer removal models, the 5'-end processing of nascent DNA at OriH, and DNA repair., (© The Author(s) 2016. Published by Oxford University Press on behalf of Nucleic Acids Research.)

Published

2016

5. Linear mtDNA fragments and unusual mtDNA rearrangements associated with pathological deficiency of MGME1 exonuclease.

Author

Nicholls TJ, Zsurka G, Peeva V, Schöler S, Szczesny RJ, Cysewski D, Reyes A, Kornblum C, Sciacco M, Moggio M, Dziembowski A, Kunz WS, and Minczuk M

Subjects

Cell Line, DNA Polymerase gamma, DNA, Mitochondrial metabolism, DNA-Directed DNA Polymerase metabolism, Exodeoxyribonucleases metabolism, Humans, Mitochondrial Diseases enzymology, Mutation, DNA Replication, DNA, Mitochondrial genetics, Exodeoxyribonucleases genetics, Gene Rearrangement, Mitochondrial Diseases genetics

Abstract

MGME1, also known as Ddk1 or C20orf72, is a mitochondrial exonuclease found to be involved in the processing of mitochondrial DNA (mtDNA) during replication. Here, we present detailed insights on the role of MGME1 in mtDNA maintenance. Upon loss of MGME1, elongated 7S DNA species accumulate owing to incomplete processing of 5' ends. Moreover, an 11-kb linear mtDNA fragment spanning the entire major arc of the mitochondrial genome is generated. In contrast to control cells, where linear mtDNA molecules are detectable only after nuclease S1 treatment, the 11-kb fragment persists in MGME1-deficient cells. In parallel, we observed characteristic mtDNA duplications in the absence of MGME1. The fact that the breakpoints of these mtDNA rearrangements do not correspond to either classical deletions or the ends of the linear 11-kb fragment points to a role of MGME1 in processing mtDNA ends, possibly enabling their repair by homologous recombination. In agreement with its functional involvement in mtDNA maintenance, we show that MGME1 interacts with the mitochondrial replicase PolgA, suggesting that it is a constituent of the mitochondrial replisome, to which it provides an additional exonuclease activity. Thus, our results support the viewpoint that MGME1-mediated mtDNA processing is essential for faithful mitochondrial genome replication and might be required for intramolecular recombination of mtDNA., (© The Author 2014. Published by Oxford University Press.)

Published

2014

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

Author

Nicholls TJ and Minczuk M

Subjects

Age Factors, Aging genetics, Aging metabolism, Animals, DNA, Mitochondrial chemistry, DNA, Mitochondrial genetics, Gene Expression Regulation, Humans, Nucleic Acid Conformation, Structure-Activity Relationship, DNA Replication, DNA, Mitochondrial biosynthesis, Mitochondria metabolism

Abstract

Given the tiny size of the mammalian mitochondrial genome, at only 16.5 kb, 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 © 2014 Elsevier Inc. All rights reserved.)

Published

2014

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

Author

Kornblum C, Nicholls TJ, Haack TB, Schöler S, Peeva V, Danhauser K, Hallmann K, Zsurka G, Rorbach J, Iuso A, Wieland T, Sciacco M, Ronchi D, Comi GP, Moggio M, Quinzii CM, DiMauro S, Calvo SE, Mootha VK, Klopstock T, Strom TM, Meitinger T, Minczuk M, Kunz WS, and Prokisch H

Subjects

Amino Acid Sequence, Base Sequence, Cloning, Molecular, Codon, Nonsense genetics, DNA Primers genetics, Gene Components, HeLa Cells, Humans, Mitochondrial Diseases enzymology, Molecular Sequence Data, Sequence Analysis, DNA, DNA Replication genetics, DNA, Mitochondrial genetics, Exodeoxyribonucleases genetics, Mitochondrial Diseases genetics, Models, Molecular

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.

Published

2013

8. 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

9. Linear mtDNA fragments and unusual mtDNA rearrangements associated with pathological deficiency of MGME1 exonuclease

Author

Nicholls, Thomas J, Zsurka, Gábor, Peeva, Viktoriya, Schöler, Susanne, Szczesny, Roman J, Cysewski, Dominik, Reyes, Aurelio, Kornblum, Cornelia, Sciacco, Monica, Moggio, Maurizio, Dziembowski, Andrzej, Kunz, Wolfram S, Minczuk, Michal, Reyes Tellez, Aurelio [0000-0003-2876-2202], Minczuk, Michal [0000-0001-8242-1420], and Apollo - University of Cambridge Repository

Subjects

DNA Replication, Gene Rearrangement, Exodeoxyribonucleases, Mitochondrial Diseases, Mutation, Humans, DNA-Directed DNA Polymerase, DNA, Mitochondrial, Cell Line, DNA Polymerase gamma

Abstract

MGME1, also known as Ddk1 or C20orf72, is a mitochondrial exonuclease found to be involved in the processing of mitochondrial DNA (mtDNA) during replication. Here, we present detailed insights on the role of MGME1 in mtDNA maintenance. Upon loss of MGME1, elongated 7S DNA species accumulate owing to incomplete processing of 5' ends. Moreover, an 11-kb linear mtDNA fragment spanning the entire major arc of the mitochondrial genome is generated. In contrast to control cells, where linear mtDNA molecules are detectable only after nuclease S1 treatment, the 11-kb fragment persists in MGME1-deficient cells. In parallel, we observed characteristic mtDNA duplications in the absence of MGME1. The fact that the breakpoints of these mtDNA rearrangements do not correspond to either classical deletions or the ends of the linear 11-kb fragment points to a role of MGME1 in processing mtDNA ends, possibly enabling their repair by homologous recombination. In agreement with its functional involvement in mtDNA maintenance, we show that MGME1 interacts with the mitochondrial replicase PolgA, suggesting that it is a constituent of the mitochondrial replisome, to which it provides an additional exonuclease activity. Thus, our results support the viewpoint that MGME1-mediated mtDNA processing is essential for faithful mitochondrial genome replication and might be required for intramolecular recombination of mtDNA.

Published

2017

10. 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

11. Mammalian RNase H1 directs RNA primer formation for mtDNA replication initiation and is also necessary for mtDNA replication completion

Author

Jelena Misic, Dusanka Milenkovic, Ali Al-Behadili, Xie Xie, Min Jiang, Shan Jiang, Roberta Filograna, Camilla Koolmeister, Stefan J Siira, Louise Jenninger, Aleksandra Filipovska, Anders R Clausen, Leonardo Caporali, Maria Lucia Valentino, Chiara La Morgia, Valerio Carelli, Thomas J Nicholls, Anna Wredenberg, Maria Falkenberg, Nils-Göran Larsson, Misic, Jelena, Milenkovic, Dusanka, Al-Behadili, Ali, Xie, Xie, Jiang, Min, Jiang, Shan, Filograna, Roberta, Koolmeister, Camilla, Siira, Stefan J, Jenninger, Louise, Filipovska, Aleksandra, Clausen, Anders R, Caporali, Leonardo, Valentino, Maria Lucia, La Morgia, Chiara, Carelli, Valerio, Nicholls, Thomas J, Wredenberg, Anna, Falkenberg, Maria, and Larsson, Nils-Göran

Subjects

Mammals, DNA Replication, Mice, Animal, Ribonuclease H, Genetics, Animals, RNA, DNA, Mitochondrial, Mammal, Mitochondria

Abstract

The in vivo role for RNase H1 in mammalian mitochondria has been much debated. Loss of RNase H1 is embryonic lethal and to further study its role in mtDNA expression we characterized a conditional knockout of Rnaseh1 in mouse heart. We report that RNase H1 is essential for processing of RNA primers to allow site-specific initiation of mtDNA replication. Without RNase H1, the RNA:DNA hybrids at the replication origins are not processed and mtDNA replication is initiated at non-canonical sites and becomes impaired. Importantly, RNase H1 is also needed for replication completion and in its absence linear deleted mtDNA molecules extending between the two origins of mtDNA replication are formed accompanied by mtDNA depletion. The steady-state levels of mitochondrial transcripts follow the levels of mtDNA, and RNA processing is not altered in the absence of RNase H1. Finally, we report the first patient with a homozygous pathogenic mutation in the hybrid-binding domain of RNase H1 causing impaired mtDNA replication. In contrast to catalytically inactive variants of RNase H1, this mutant version has enhanced enzyme activity but shows impaired primer formation. This finding shows that the RNase H1 activity must be strictly controlled to allow proper regulation of mtDNA replication.

Published

2022

12. 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