Your search keyword '"Jay P. Uhler"' showing total 23 results

1. Copy-choice recombination during mitochondrial L-strand synthesis causes DNA deletions

Author

Örjan Persson, Yazh Muthukumar, Swaraj Basu, Louise Jenninger, Jay P. Uhler, Anna-Karin Berglund, Robert McFarland, Robert W. Taylor, Claes M. Gustafsson, Erik Larsson, and Maria Falkenberg

Subjects

Science

Abstract

Large-scale deletions of mitochondrial DNA (mtDNA) are associated with different human mitochondrial diseases and normal human ageing. Here the authors present a model for mtDNA formation based on generation sequencing analysis of patients samples and in vitro reconstituted mtDNA deletion using purified proteins.

Published

2019

2. Mice lacking the mitochondrial exonuclease MGME1 accumulate mtDNA deletions without developing progeria

Author

Stanka Matic, Min Jiang, Thomas J. Nicholls, Jay P. Uhler, Caren Dirksen-Schwanenland, Paola Loguercio Polosa, Marie-Lune Simard, Xinping Li, Ilian Atanassov, Oliver Rackham, Aleksandra Filipovska, James B. Stewart, Maria Falkenberg, Nils-Göran Larsson, and Dusanka Milenkovic

Subjects

Science

Abstract

It has been debated whether premature ageing in mitochondrial DNA mutator mice is driven by point mutations or deletions of mtDNA. Matic et al generate Mgme1 knockout mice and show here that these mice have tissue-specific replication stalling and accumulate deleted mtDNA, without developing progeria.

Published

2018

3. RNase H1 directs origin-specific initiation of DNA replication in human mitochondria.

Author

Viktor Posse, Ali Al-Behadili, Jay P Uhler, Anders R Clausen, Aurelio Reyes, Massimo Zeviani, Maria Falkenberg, and Claes M Gustafsson

Subjects

Genetics, QH426-470

Abstract

Human mitochondrial DNA (mtDNA) replication is first initiated at the origin of H-strand replication. The initiation depends on RNA primers generated by transcription from an upstream promoter (LSP). Here we reconstitute this process in vitro using purified transcription and replication factors. The majority of all transcription events from LSP are prematurely terminated after ~120 nucleotides, forming stable R-loops. These nascent R-loops cannot directly prime mtDNA synthesis, but must first be processed by RNase H1 to generate 3'-ends that can be used by DNA polymerase γ to initiate DNA synthesis. Our findings are consistent with recent studies of a knockout mouse model, which demonstrated that RNase H1 is required for R-loop processing and mtDNA maintenance in vivo. Both R-loop formation and DNA replication initiation are stimulated by the mitochondrial single-stranded DNA binding protein. In an RNase H1 deficient patient cell line, the precise initiation of mtDNA replication is lost and DNA synthesis is initiated from multiple sites throughout the mitochondrial control region. In combination with previously published in vivo data, the findings presented here suggest a model, in which R-loop processing by RNase H1 directs origin-specific initiation of DNA replication in human mitochondria.

Published

2019

4. In Vitro Assays of TWINKLE Function

Author

Jay P. Uhler, Ulrika Alexandersson, and Maria Falkenberg

Published

2023

5. In Vitro Analysis of mtDNA Replication

Author

Jay P, Uhler and Maria, Falkenberg

Subjects

DNA Replication, DNA-Binding Proteins, Mitochondrial Proteins, Genome, Mitochondrial, DNA, Single-Stranded, Humans, In Vitro Techniques, DNA, Mitochondrial, Recombinant Proteins, DNA Polymerase gamma, Mitochondria

Abstract

Human mitochondrial DNA is a small circular double-stranded molecule that is essential for cellular energy production. A specialized protein machinery replicates the mitochondrial genome, with DNA polymerase γ carrying out synthesis of both strands. According to the prevailing mitochondrial DNA replication model, the two strands are replicated asynchronously, with the leading heavy-strand initiating first, followed by the lagging light-strand. By using purified recombinant forms of the replication proteins and synthetic DNA templates, it is possible to reconstitute mitochondrial DNA replication in vitro. Here we provide details on how to differentially reconstitute replication of the leading- and lagging-strands.

Published

2020

6. In Vitro Analysis of mtDNA Replication

Author

Jay P. Uhler and Maria Falkenberg

Subjects

0303 health sciences, Mitochondrial DNA, biology, DNA polymerase, Mitochondrion, Human mitochondrial genetics, In vitro, law.invention, Cell biology, 03 medical and health sciences, 0302 clinical medicine, law, Replication (statistics), biology.protein, Recombinant DNA, 030217 neurology & neurosurgery, 030304 developmental biology, Mitochondrial DNA replication

Abstract

Human mitochondrial DNA is a small circular double-stranded molecule that is essential for cellular energy production. A specialized protein machinery replicates the mitochondrial genome, with DNA polymerase γ carrying out synthesis of both strands. According to the prevailing mitochondrial DNA replication model, the two strands are replicated asynchronously, with the leading heavy-strand initiating first, followed by the lagging light-strand. By using purified recombinant forms of the replication proteins and synthetic DNA templates, it is possible to reconstitute mitochondrial DNA replication in vitro. Here we provide details on how to differentially reconstitute replication of the leading- and lagging-strands.

Published

2020

7. Accurate mapping of mitochondrial DNA deletions and duplications using deep sequencing

Author

Sammy Kimoloi, Jay P. Uhler, Xie Xie, Anders Oldfors, Maria Falkenberg, Stanka Matic, Erik Larsson, Claes M. Gustafsson, James B. Stewart, Carola Hedberg-Oldfors, Swaraj Basu, Rudolf J. Wiesner, Nils-Göran Larsson, Olivier R. Baris, Dusanka Milenkovic, Physiopathologie Cardiovasculaire et Mitochondriale (MITOVASC), and Université d'Angers (UA)-Institut National de la Santé et de la Recherche Médicale (INSERM)-Centre National de la Recherche Scientifique (CNRS)

Subjects

Cancer Research, Heredity, [SDV]Life Sciences [q-bio], QH426-470, Genome, Biochemistry, Mice, Database and Informatics Methods, 0302 clinical medicine, Gene Duplication, Genome Sequencing, Genetics (clinical), Energy-Producing Organelles, 0303 health sciences, Mammalian Genomics, Genetically Modified Organisms, High-Throughput Nucleotide Sequencing, Genomics, Animal Models, Heteroplasmy, Mitochondrial DNA, 3. Good health, Mitochondria, Nucleic acids, Experimental Organism Systems, Engineering and Technology, Cellular Structures and Organelles, Genetic Engineering, Sequence Analysis, Research Article, Biotechnology, Forms of DNA, Bioinformatics, Mitochondrial disease, Sequence alignment, Mouse Models, Bioengineering, Computational biology, Biology, Bioenergetics, Research and Analysis Methods, DNA, Mitochondrial, DNA sequencing, Deep sequencing, 03 medical and health sciences, Model Organisms, medicine, Genetics, Animals, Molecular Biology Techniques, Sequencing Techniques, Molecular Biology, Ecology, Evolution, Behavior and Systematics, 030304 developmental biology, Biology and life sciences, Genetically Modified Animals, Reproducibility of Results, Sequence Analysis, DNA, DNA, Cell Biology, medicine.disease, Animal Genomics, Animal Studies, Sequence Alignment, 030217 neurology & neurosurgery, Gene Deletion

Abstract

Deletions and duplications in mitochondrial DNA (mtDNA) cause mitochondrial disease and accumulate in conditions such as cancer and age-related disorders, but validated high-throughput methodology that can readily detect and discriminate between these two types of events is lacking. Here we establish a computational method, MitoSAlt, for accurate identification, quantification and visualization of mtDNA deletions and duplications from genomic sequencing data. Our method was tested on simulated sequencing reads and human patient samples with single deletions and duplications to verify its accuracy. Application to mouse models of mtDNA maintenance disease demonstrated the ability to detect deletions and duplications even at low levels of heteroplasmy., Author summary Deletions in the mitochondrial genome cause a wide variety of rare disorders, but are also linked to more common conditions such as neurodegeneration, diabetes type 2, and the normal ageing process. There is also a growing awareness that mtDNA duplications, which are also relevant for human disease, may be more common than previously thought. Despite their clinical importance, our current knowledge about the abundance, characteristics and diversity of mtDNA deletions and duplications is fragmented, and based to large extent on a limited view provided by traditional low-throughput analyses. Here, we describe a bioinformatics method, MitoSAlt, that can accurately map and classify mtDNA deletions and duplications using high-throughput sequencing. Application of this methodology to mouse models of mitochondrial deficiencies revealed a large number of duplications, suggesting that these may previously have been underestimated.

Published

2020

8. Identification of a G-quadruplex forming sequence in the promoter of UCP1

Author

Yuanbo Zhao and Jay P. Uhler

Subjects

0301 basic medicine, Porphyrins, Brown fat cell differentiation, Biophysics, medicine.disease_cause, G-quadruplex, Biochemistry, 03 medical and health sciences, chemistry.chemical_compound, medicine, Humans, heterocyclic compounds, Luciferase, Promoter Regions, Genetic, Gene, Uncoupling Protein 1, Mutation, Base Sequence, Chemistry, RNA, DNA, General Medicine, Cell biology, G-Quadruplexes, HEK293 Cells, 030104 developmental biology, Gene Expression Regulation, Nucleic acid

Abstract

G-quadruplexes are higher-order nucleic acid structures formed in G-rich sequences in DNA or RNA. G-quadruplexes are distributed in many locations in the human genome, including promoter regions, and are viewed as promising therapeutic targets. Uncoupling protein-1 (UCP1) is a mitochondrial thermogenic gene critical for energy expenditure in the form of heat in the brown adipose tissue. UCP1 is only expressed during brown fat cell differentiation and is a candidate target for treating obesity. However, the regulation of UCP1 expression is not clear. We reported here that a G-quadruplex forming sequence exists in the promoter of UCP1. The 5,10,15,20-tetra(N-methyl-4-pyridyl) porphyrin (TMPyP4) enhanced cellular expression of UCP1 and destabilized the G-quadruplex formed by the sequence from the promoter of UCP1. Mutations in the G-quadruplex regulated the cellular activity of UCP1 promoter as evidenced by a UCP1-promoter luciferase assay. These results suggest that G-quadruplex structure is a potential target to regulate the expression of UCP1.

Published

2018

9. UBTD1 is a mechano‐regulator controlling cancer aggressiveness

Author

Damien Ambrosetti, Amel Mettouchi, Frédéric Bost, Christophe Lamaze, Maeva Gesson, Stéphanie Torrino, Jay P. Uhler, Emmanuel Lemichez, Lisa Kaminski, Stephan Clavel, Kathiane Laurent, Jean-François Michiels, Sabrina Pisano, François-René Roustan, Thomas Bertero, Maeva Dufies, Cedric Gaggioli, Centre méditerranéen de médecine moléculaire (C3M), Université Nice Sophia Antipolis (1965 - 2019) (UNS), COMUE Université Côte d'Azur (2015-2019) (COMUE UCA)-COMUE Université Côte d'Azur (2015-2019) (COMUE UCA)-Institut National de la Santé et de la Recherche Médicale (INSERM)-Université Côte d'Azur (UCA), COMUE Université Côte d'Azur (2015-2019) (COMUE UCA), Centre National de la Recherche Scientifique (CNRS), Institut de Recherche sur le Cancer et le Vieillissement (IRCAN), COMUE Université Côte d'Azur (2015-2019) (COMUE UCA)-COMUE Université Côte d'Azur (2015-2019) (COMUE UCA)-Institut National de la Santé et de la Recherche Médicale (INSERM)-Centre National de la Recherche Scientifique (CNRS)-Université Côte d'Azur (UCA), Hôpital Pasteur [Nice] (CHU), University of Gothenburg (GU), Toxines bactériennes - Bacterial Toxins, Institut Pasteur [Paris] (IP)-Université Paris Diderot - Paris 7 (UPD7)-Centre National de la Recherche Scientifique (CNRS), Chimie biologique des membranes et ciblage thérapeutique (CBMCT - UMR 3666 / U1143), Université Paris Descartes - Paris 5 (UPD5)-Institut Curie [Paris]-Institut National de la Santé et de la Recherche Médicale (INSERM)-Institut de Chimie du CNRS (INC)-Centre National de la Recherche Scientifique (CNRS), This work has been supported by the French government, through the UCA‐JEDI Investments in the Future project managed by the National Research Agency (ANR) with the reference number ANR‐15‐IDEX‐01. S.T. is a recipient of a post‐doctoral fellowship from 'La Fondation de France'. L.K. is a recipient of a doctoral fellowship from the French ministry of research. F.B. is a CNRS researcher., We thank the GIS‐IBISA multi‐sites platform 'Microscopie Imagerie Côte d'Azur' (MICA), and particularly the imaging site of C3M and IRCAN (PICMI), which are supported by the 'Conseil General 06' and 'Conseil Départemental 06'. The PICMI AFM was supported by the Association pour la Recherche sur le Cancer (ARC) and by the 'Conseil General 06 de la Région Provence Alpes‐Côte'., ANR-15-IDEX-0001,UCA JEDI,Idex UCA JEDI(2015), Université Nice Sophia Antipolis (... - 2019) (UNS), Institut Pasteur [Paris]-Université Paris Diderot - Paris 7 (UPD7)-Centre National de la Recherche Scientifique (CNRS), Dynamique et mécanique membranaires de la signalisation intracellulaire, Institut National de la Santé et de la Recherche Médicale (INSERM)-Centre National de la Recherche Scientifique (CNRS)-Université Paris sciences et lettres (PSL), Université Côte d'Azur (UCA)-Université Côte d'Azur (UCA)-Institut National de la Santé et de la Recherche Médicale (INSERM), Université Côte d'Azur (UCA), Centre National de la Recherche Scientifique (CNRS)-Institut National de la Santé et de la Recherche Médicale (INSERM)-Université Nice Sophia Antipolis (... - 2019) (UNS), Université Côte d'Azur (UCA)-Université Côte d'Azur (UCA), Institut National de la Santé et de la Recherche Médicale (INSERM)-Centre National de la Recherche Scientifique (CNRS)-Paris Sciences et Lettres (PSL), and ANR: 15-IDEX-0001,UCA JEDI,Idex UCA JEDI(2015)

Subjects

RHOA, Cell, Regulator, Cell Cycle Proteins, [SDV.BC.BC]Life Sciences [q-bio]/Cellular Biology/Subcellular Processes [q-bio.SC], Mechanotransduction, Cellular, Biochemistry, 0302 clinical medicine, Ubiquitin, Neoplasms, matrix stiffness, ROCK2, Insulin-Like Growth Factor I, beta Catenin, 0303 health sciences, biology, Chemistry, Articles, Prognosis, 3. Good health, Cell biology, Ubiquitin ligase, Gene Expression Regulation, Neoplastic, medicine.anatomical_structure, Disease Progression, Disease Susceptibility, YAP, Protein Binding, Signal Transduction, [SDV.CAN]Life Sciences [q-bio]/Cancer, Protein Serine-Threonine Kinases, Models, Biological, UBTD1, 03 medical and health sciences, Cell Adhesion, Genetics, medicine, Humans, Hippo Signaling Pathway, Ubiquitins, Molecular Biology, 030304 developmental biology, Cancer, [SDV.BBM.BM]Life Sciences [q-bio]/Biochemistry, Molecular Biology/Molecular biology, β‐TrCP, beta-Transducin Repeat-Containing Proteins, medicine.disease, Cancer cell, biology.protein, rhoA GTP-Binding Protein, Protein Processing, Post-Translational, 030217 neurology & neurosurgery, Transcription Factors

Abstract

International audience; Ubiquitin domain-containing protein 1 (UBTD1) is highly evolutionary conserved and has been described to interact with E2 enzymes of the ubiquitin-proteasome system. However, its biological role and the functional significance of this interaction remain largely unknown. Here, we demonstrate that depletion of UBTD1 drastically affects the mechanical properties of epithelial cancer cells via RhoA activation and strongly promotes their aggressiveness. On a stiff matrix, UBTD1 expression is regulated by cell-cell contacts, and the protein is associated with β-catenin at cell junctions. Yes-associated protein (YAP) is a major cell mechano-transducer, and we show that UBTD1 is associated with components of the YAP degradation complex. Interestingly, UBTD1 promotes the interaction of YAP with its E3 ubiquitin ligase β-TrCP Consequently, in cancer cells, UBTD1 depletion decreases YAP ubiquitylation and triggers robust ROCK2-dependent YAP activation and downstream signaling. Data from lung and prostate cancer patients further corroborate the in cellulo results, confirming that low levels of UBTD1 are associated with poor patient survival, suggesting that biological functions of UBTD1 could be beneficial in limiting cancer progression.

Published

2019

10. Deep sequencing of mitochondrial DNA and characterization of a novel POLG mutation in a patient with arPEO

Author

Carola Hedberg-Oldfors, Bertil Macao, Swaraj Basu, Christopher Lindberg, Bradley Peter, Direnis Erdinc, Jay P. Uhler, Erik Larsson, Maria Falkenberg, Anders Oldfors

Published

2019

11. Regulation of DNA replication at the end of the mitochondrial D-loop involves the helicase TWINKLE and a conserved sequence element

Author

Majda Mehmedovic, Claes M. Gustafsson, Tore Samuelsson, Yonghong Shi, Elisabeth Jemt, Örjan Persson, Marcela Dávila López, Jay P. Uhler, Maria Falkenberg, and Christoph Freyer

Subjects

DNA Replication, Genome Integrity, Repair and Replication, Regulatory Sequences, Nucleic Acid, Biology, DNA, Mitochondrial, Mitochondrial Proteins, Mice, Replication factor C, Control of chromosome duplication, Minichromosome maintenance, RNA, Small Cytoplasmic, Genetics, Animals, Humans, Nucleotide Motifs, Conserved Sequence, Base Sequence, Inverted Repeat Sequences, DNA Helicases, DnaA, Prokaryotic DNA replication, Transcription Termination, Genetic, Coding strand, Vertebrates, Origin recognition complex, Signal Recognition Particle, HeLa Cells, Mitochondrial DNA replication

Abstract

The majority of mitochondrial DNA replication events are terminated prematurely. The nascent DNA remains stably associated with the template, forming a triple-stranded displacement loop (D-loop) structure. However, the function of the D-loop region of the mitochondrial genome remains poorly understood. Using a comparative genomics approach we here identify two closely related 15 nt sequence motifs of the D-loop, strongly conserved among vertebrates. One motif is at the D-loop 5'-end and is part of the conserved sequence block 1 (CSB1). The other motif, here denoted coreTAS, is at the D-loop 3'-end. Both these sequences may prevent transcription across the D-loop region, since light and heavy strand transcription is terminated at CSB1 and coreTAS, respectively. Interestingly, the replication of the nascent D-loop strand, occurring in a direction opposite to that of heavy strand transcription, is also terminated at coreTAS, suggesting that coreTAS is involved in termination of both transcription and replication. Finally, we demonstrate that the loading of the helicase TWINKLE at coreTAS is reversible, implying that this site is a crucial component of a switch between D-loop formation and full-length mitochondrial DNA replication.

Published

2015

12. Mice lacking the mitochondrial exonuclease MGME1 accumulate mtDNA deletions without developing progeria

Author

Thomas J. Nicholls, Stanka Matic, Paola Loguercio Polosa, Aleksandra Filipovska, Nils-Göran Larsson, Xinping Li, Min Jiang, Marie Lune Simard, James B. Stewart, Oliver Rackham, Ilian Atanassov, Dusanka Milenkovic, Jay P. Uhler, Caren Dirksen-Schwanenland, and Maria Falkenberg

Subjects

0301 basic medicine, DNA Replication, Male, Mitochondrial DNA, Transcription, Genetic, Science, Mitochondrial disease, General Physics and Astronomy, Biology, DNA, Mitochondrial, General Biochemistry, Genetics and Molecular Biology, Article, 03 medical and health sciences, Exonuclease 1, Mice, 0302 clinical medicine, Progeria, medicine, Animals, Humans, Point Mutation, Tissue Distribution, lcsh:Science, Gene, Gene knockout, Gene Library, Genetics, Mice, Knockout, Multidisciplinary, Point mutation, Homozygote, Mitochondrial genome maintenance, General Chemistry, Fibroblasts, medicine.disease, 3. Good health, Mitochondria, Mice, Inbred C57BL, 030104 developmental biology, Exodeoxyribonucleases, Phenotype, Sperm Motility, lcsh:Q, Female, 030217 neurology & neurosurgery, Gene Deletion, HeLa Cells

Abstract

Replication of mammalian mitochondrial DNA (mtDNA) is an essential process that requires high fidelity and control at multiple levels to ensure proper mitochondrial function. Mutations in the mitochondrial genome maintenance exonuclease 1 (MGME1) gene were recently reported in mitochondrial disease patients. Here, to study disease pathophysiology, we generated Mgme1 knockout mice and report that homozygous knockouts develop depletion and multiple deletions of mtDNA. The mtDNA replication stalling phenotypes vary dramatically in different tissues of Mgme1 knockout mice. Mice with MGME1 deficiency accumulate a long linear subgenomic mtDNA species, similar to the one found in mtDNA mutator mice, but do not develop progeria. This finding resolves a long-standing debate by showing that point mutations of mtDNA are the main cause of progeria in mtDNA mutator mice. We also propose a role for MGME1 in the regulation of replication and transcription termination at the end of the control region of mtDNA., It has been debated whether premature ageing in mitochondrial DNA mutator mice is driven by point mutations or deletions of mtDNA. Matic et al generate Mgme1 knockout mice and show here that these mice have tissue-specific replication stalling and accumulate deleted mtDNA, without developing progeria.

Published

2018

13. A role for noncoding transcription in activation of the yeast PHO5 gene

Author

Jay P. Uhler, Jesper Q. Svejstrup, and Christina Bech Hertel

Subjects

Genetics, Saccharomyces cerevisiae Proteins, Multidisciplinary, Transcription, Genetic, TATA box, Acid Phosphatase, Promoter, RNA polymerase II, Biological Sciences, Biology, TATA Box, Chromatin remodeling, Chromatin, Kinetics, Open Reading Frames, Histone, Transcription (biology), Gene Expression Regulation, Fungal, biology.protein, Nucleosome, Promoter Regions, Genetic

Abstract

Noncoding, or intergenic, transcription by RNA polymerase II (RNAPII) is remarkably widespread in eukaryotic organisms, but the effects of such transcription remain poorly understood. Here we show that noncoding transcription plays a role in activation, but not repression, of the Saccharomyces cerevisiae PHO5 gene. Histone eviction from the PHO5 promoter during activation occurs with normal kinetics even in the absence of the PHO5 TATA box, showing that transcription of the gene itself is not required for promoter remodeling. Nevertheless, we find that mutations that impair transcript elongation by RNAPII affect the kinetics of histone eviction from the PHO5 promoter. Most dramatically, inactivation of RNAPII itself abolishes eviction completely. Under repressing conditions, an ≈2.4-kb noncoding exosome-degraded transcript is detected that originates near the PHO5 termination site and is transcribed in the antisense direction. Abrogation of this transcript delays chromatin remodeling and subsequent RNAPII recruitment to PHO5 upon activation. We propose that noncoding transcription through positioned nucleosomes can enhance chromatin plasticity so that chromatin remodeling and activation of traversed genes occur in a timely manner.

Published

2007

14. Primer removal during mammalian mitochondrial DNA replication

Author

Maria Falkenberg and Jay P. Uhler

Subjects

DNA Replication, Mitochondrial DNA, Mitochondrial Diseases, Flap Endonucleases, Ribonuclease H, Eukaryotic DNA replication, Biology, Pre-replication complex, Biochemistry, DNA, Mitochondrial, Control of chromosome duplication, DNA2, Animals, Humans, FEN1, MGME1, Molecular Biology, Genetics, mtDNA, DNA replication, DNA Helicases, Cell Biology, RNA primer, Exodeoxyribonucleases, Replication Initiation, Genome, Mitochondrial, Origin recognition complex, RNA, RNase H1, Mitochondrial DNA replication

Abstract

The small circular mitochondrial genome in mammalian cells is replicated by a dedicated replisome, defects in which can cause mitochondrial disease in humans. A fundamental step in mitochondrial DNA (mtDNA) replication and maintenance is the removal of the RNA primers needed for replication initiation. The nucleases RNase H1, FEN1, DNA2, and MGME1 have been implicated in this process. Here we review the role of these nucleases in the light of primer removal pathways in mitochondria, highlight associations with disease, as well as consider the implications for mtDNA replication initiation.

Published

2015

15. The exonuclease activity of DNA polymerase γ is required for ligation during mitochondrial DNA replication

Author

Jay P. Uhler, Wenwen Sheng, Claes M. Gustafsson, Yonghong Shi, Maria Falkenberg, James B. Stewart, Xuefeng Zhu, Triinu Siibak, Bertil Macao, and Monica Olsson

Subjects

Exonuclease, DNA Replication, DNA polymerase, DNA polymerase II, General Physics and Astronomy, DNA-Directed DNA Polymerase, Spodoptera, DNA polymerase delta, DNA, Mitochondrial, Polymerase Chain Reaction, General Biochemistry, Genetics and Molecular Biology, Article, Mice, Sf9 Cells, Animals, Humans, Klenow fragment, Multidisciplinary, DNA clamp, biology, DNA replication, General Chemistry, Molecular biology, DNA Polymerase gamma, Blotting, Southern, Exodeoxyribonucleases, biology.protein, Mitochondrial DNA replication

Abstract

Mitochondrial DNA (mtDNA) polymerase γ (POLγ) harbours a 3′–5′ exonuclease proofreading activity. Here we demonstrate that this activity is required for the creation of ligatable ends during mtDNA replication. Exonuclease-deficient POLγ fails to pause on reaching a downstream 5′-end. Instead, the enzyme continues to polymerize into double-stranded DNA, creating an unligatable 5′-flap. Disease-associated mutations can both increase and decrease exonuclease activity and consequently impair DNA ligation. In mice, inactivation of the exonuclease activity causes an increase in mtDNA mutations and premature ageing phenotypes. These mutator mice also contain high levels of truncated, linear fragments of mtDNA. We demonstrate that the formation of these fragments is due to impaired ligation, causing nicks near the origin of heavy-strand DNA replication. In the subsequent round of replication, the nicks lead to double-strand breaks and linear fragment formation., Mitochondrial DNA (mtDNA) polymerase γ has a 3′–5′ exonuclease proofreading activity. Here, the authors show it is required for creating ligatable ends during mtDNA replication, and inactivation of the activity in mice causes strand-specific nicks in DNA and the formation of linear mtDNA fragments.

Published

2015

16. The UbL protein UBTD1 stably interacts with the UBE2D family of E2 ubiquitin conjugating enzymes

Author

Géraldine Farge, Maria Falkenberg, Henrik Spåhr, Claes M. Gustafsson, Stephan Clavel, Tore Samuelsson, Nils-Göran Larsson, Jay P. Uhler, Institut de Biologie Valrose (IBV), Université Nice Sophia Antipolis (... - 2019) (UNS), and COMUE Université Côte d'Azur (2015-2019) (COMUE UCA)-COMUE Université Côte d'Azur (2015-2019) (COMUE UCA)-Institut National de la Santé et de la Recherche Médicale (INSERM)-Centre National de la Recherche Scientifique (CNRS)-Université Côte d'Azur (UCA)

Subjects

Proteolysis, Molecular Sequence Data, Biophysics, Ubiquitin-conjugating enzyme, Biochemistry, Conserved sequence, Ubiquitin, Two-Hybrid System Techniques, medicine, Humans, Amino Acid Sequence, Ubiquitins, Molecular Biology, Peptide sequence, [SDV.BDD]Life Sciences [q-bio]/Development Biology, Conserved Sequence, Phylogeny, biology, medicine.diagnostic_test, Ubiquitination, Cell Biology, Protein Structure, Tertiary, Ubiquitin ligase, Proteasome, Ubiquitin-Conjugating Enzymes, biology.protein, Metabolic Networks and Pathways

Abstract

International audience; UBTD1 is a previously uncharacterized ubiquitin-like (UbL) domain containing protein with high homology to the mitochondrial Dc-UbP/UBTD2 protein. Here we show that UBTD1 and UBTD2 belong to a family of proteins that is conserved through evolution and found in metazoa, funghi, and plants. To gain further insight into the function of UBTD1, we screened for interacting proteins. In a yeast-2-hybrid (Y2H) screen, we identified several proteins involved in the ubiquitylation pathway, including the UBE2D family of E2 ubiquitin conjugating enzymes. An affinity capture screen for UBTD1 interacting proteins in whole cell extracts also identified members of the UBE2D family. Biochemical characterization of recombinant UBTD1 and UBE2D demonstrated that the two proteins form a stable, stoichiometric complex that can be purified to near homogeneity. We discuss the implications of these findings in light of the ubiquitin proteasome system (UPS).

Published

2014

17. A hybrid G-quadruplex structure formed between RNA and DNA explains the extraordinary stability of the mitochondrial R-loop

Author

Jay P. Uhler, Claes M. Gustafsson, Maria Falkenberg, Yonghong Shi, Fredrik Westerlund, and Paulina H. Wanrooij

Subjects

DNA Replication, Transcription, Genetic, Base pair, RNA, Mitochondrial, RNA-dependent RNA polymerase, Biology, Genome Integrity, Repair and Replication, DNA, Mitochondrial, 03 medical and health sciences, 0302 clinical medicine, Transcription (biology), Genetics, Humans, 030304 developmental biology, Transcription bubble, 0303 health sciences, Okazaki fragments, Circular Dichroism, Molecular biology, Cell biology, G-Quadruplexes, Coding strand, Transcription Termination, Genetic, RNA, Primase, 030217 neurology & neurosurgery, Mitochondrial DNA replication

Abstract

In human mitochondria the transcription machinery generates the RNA primers needed for initiation of DNA replication. A critical feature of the leading-strand origin of mitochondrial DNA replication is a CG-rich element denoted conserved sequence block II (CSB II). During transcription of CSB II, a G-quadruplex structure forms in the nascent RNA, which stimulates transcription termination and primer formation. Previous studies have shown that the newly synthesized primers form a stable and persistent RNA-DNA hybrid, a R-loop, near the leading-strand origin of DNA replication. We here demonstrate that the unusual behavior of the RNA primer is explained by the formation of a stable G-quadruplex structure, involving the CSB II region in both the nascent RNA and the non-template DNA strand. Based on our data, we suggest that G-quadruplex formation between nascent RNA and the non-template DNA strand may be a regulated event, which decides the fate of RNA primers and ultimately the rate of initiation of DNA synthesis in human mitochondria.

Published

2012

18. G-quadruplex structures in RNA stimulate mitochondrial transcription termination and primer formation

Author

Jay P. Uhler, Tomas Simonsson, Maria Falkenberg, Claes M. Gustafsson, and Paulina H. Wanrooij

Subjects

Terminator Regions, Genetic, Multidisciplinary, General transcription factor, biology, Transcription, Genetic, Termination factor, Molecular Sequence Data, RNA polymerase II, Biological Sciences, Molecular biology, Mitochondria, G-Quadruplexes, Terminator (genetics), Intrinsic termination, biology.protein, RNA, Transcription factor II F, Transcription factor II E, Transcription factor II D, Conserved Sequence, DNA Primers

Abstract

The human mitochondrial transcription machinery generates the primers required for initiation of leading-strand DNA replication. According to one model, the 3′ end of the primer is defined by transcription termination at conserved sequence block II (CSB II) in the mitochondrial DNA control region. We here demonstrate that this site-specific termination event is caused by G-quadruplex structures formed in nascent RNA upon transcription of CSB II. We also demonstrate that a poly-dT stretch downstream of CSB II has a modest stimulatory effect on the termination efficiency. The mechanism is reminiscent of Rho-independent transcription termination in prokaryotes, with the exception that a G-quadruplex structure replaces the hairpin loop formed in bacterial mRNA during transcription of terminator sequences.

Published

2010

19. Reversal of RNA polymerase II ubiquitylation by the ubiquitin protease Ubp3

Author

Stefan Sigurdsson, Michael Taschner, Hediye Erdjument-Bromage, Jay P. Uhler, Kristian Kvint, Jesper Svejstrup, and Paul Tempst

Subjects

Saccharomyces cerevisiae Proteins, DNA Repair, DNA repair, Antimetabolites, Cell Survival, Ultraviolet Rays, Proteolysis, RNA polymerase II, Saccharomyces cerevisiae, chemistry.chemical_compound, Ubiquitin, Endopeptidases, medicine, Humans, Uracil, Molecular Biology, Polymerase, biology, medicine.diagnostic_test, Ubiquitination, Cell Biology, Cell biology, Elongation factor, chemistry, biology.protein, Transcription factor II F, RNA Polymerase II, Transcriptional Elongation Factors, DNA

Abstract

The final outcome of protein polyubiquitylation is often proteasome-mediated proteolysis, meaning that "proofreading" of ubiquitylation by ubiquitin proteases (UBPs) is crucial. Transcriptional arrest can trigger ubiquitin-mediated proteolysis of RNA polymerase II (RNAPII) so a UBP reversing RNAPII ubiquitylation might be expected. Here, we show that Ubp3 deubiquitylates RNAPII in yeast. Genetic characterization of ubp3 cells is consistent with a role in elongation, and Ubp3 can be purified with RNAPII, Def1, and the elongation factors Spt5 and TFIIF. This Ubp3 complex deubiquitylates both mono- and polyubiquitylated RNAPII in vitro, and ubp3 cells have elevated levels of ubiquitylated RNAPII in vivo. Moreover, RNAPII is degraded faster in a ubp3 mutant after UV irradiation. Problems posed by damage-arrested RNAPII are thought to be resolved either by removing the damage or degrading the polymerase. In agreement with this, cells with compromised DNA repair are better equipped to survive UV damage when UPB3 is deleted.

Published

2006

20. Altered Electrical Properties in DrosophilaNeurons Developing without Synaptic Transmission

Author

Jay P. Uhler, Michael Bate, Richard A. Baines, Sean T. Sweeney, and Annemarie Thompson

Subjects

Patch-Clamp Techniques, Potassium Channels, Neural facilitation, Action Potentials, Neurotransmission, Biology, In Vitro Techniques, Synaptic Transmission, Sodium Channels, Choline O-Acetyltransferase, Tetanus Toxin, Synaptic augmentation, Animals, ARTICLE, Motor Neurons, Synaptic scaling, Synaptic pharmacology, General Neuroscience, Temperature, Excitatory Postsynaptic Potentials, Metalloendopeptidases, Acetylcholine, Synaptic fatigue, Synaptic plasticity, Synapses, Drosophila, Calcium Channels, Synaptic tagging, Neuroscience

Abstract

We examine the role of synaptic activity in the development of identified Drosophila embryonic motorneurons. Synaptic activity was blocked by both pan-neuronal expression of tetanus toxin light chain (TeTxLC) and by reduction of acetylcholine (ACh) using a temperature-sensitive allele of choline acetyltransferase (Cha(ts2)). In the absence of synaptic activity, aCC and RP2 motorneurons develop with an apparently normal morphology and retain their capacity to form synapses. However, blockade of synaptic transmission results in significant changes in the electrical phenotype of these neurons. Specifically, increases are seen in both voltage-gated inward Na(+) and voltage-gated outward K(+) currents. Voltage-gated Ca(2+) currents do not change. The changes in conductances appear to promote neuron excitability. In the absence of synaptic activity, the number of action potentials fired by a depolarizing ramp (-60 to +60 mV) is increased and, in addition, the amplitude of the initial action potential fired is also significantly larger. Silencing synaptic input to just aCC, without affecting inputs to other neurons, demonstrates that the capability to respond to changing levels of synaptic excitation is intrinsic to these neurons. The alteration to electrical properties are not permanent, being reversed by restoration of normal synaptic function. Whereas our data suggest that synaptic activity makes little or no contribution to the initial formation of embryonic neural circuits, the electrical development of neurons that constitute these circuits seems to depend on a process that requires synaptic activity.

Published

2001

21. The kakapo mutation affects terminal arborization and central dendritic sprouting of Drosophila motorneurons

Author

Jay P. Uhler, John Roote, Andreas Prokop, and Michael Bate

Subjects

dendrites, Cellular differentiation, Mutant, Genes, Insect, Nerve Tissue Proteins, Microtubules, Article, 03 medical and health sciences, 0302 clinical medicine, Microtubule, medicine, Animals, Actin, Alleles, 030304 developmental biology, Motor Neurons, 0303 health sciences, Polytene chromosome, biology, neuromuscular junction, Gene Expression Regulation, Developmental, Membrane Proteins, cytoskeleton, Cell Biology, biology.organism_classification, Sensory neuron, Cell biology, Cytoskeletal Proteins, Microscopy, Electron, medicine.anatomical_structure, nervous system, Mutation, Synapses, Insect Proteins, Drosophila, Drosophila melanogaster, Neural development, 030217 neurology & neurosurgery

Abstract

The lethal mutation l(2)CA4 causes specific defects in local growth of neuronal processes. We uncovered four alleles of l(2)CA4 and mapped it to bands 50A-C on the polytene chromosomes and found it to be allelic to kakapo (Prout et al. 1997. Genetics. 146:275– 285). In embryos carrying our kakapo mutant alleles, motorneurons form correct nerve branches, showing that long distance growth of neuronal processes is unaffected. However, neuromuscular junctions (NMJs) fail to form normal local arbors on their target muscles and are significantly reduced in size. In agreement with this finding, antibodies against kakapo (Gregory and Brown. 1998. J. Cell Biol. 143:1271–1282) detect a specific epitope at all or most Drosophila NMJs. Within the central nervous system of kakapo mutant embryos, neuronal dendrites of the RP3 motorneuron form at correct positions, but are significantly reduced in size. At the subcellular level we demonstrate two phenotypes potentially responsible for the defects in neuronal branching: first, transmembrane proteins, which can play important roles in neuronal growth regulation, are incorrectly localized along neuronal processes. Second, microtubules play an important role in neuronal growth, and kakapo appears to be required for their organization in certain ectodermal cells: On the one hand, kakapo mutant embryos exhibit impaired microtubule organization within epidermal cells leading to detachment of muscles from the cuticle. On the other, a specific type of sensory neuron (scolopidial neurons) shows defects in microtubule organization and detaches from its support cells.

Published

1998

22. A two-nuclease pathway involving RNase H1 is required for primer removal at human mitochondrial OriL

Author

Sjoerd Wanrooij, Mara Doimo, Massimo Zeviani, Maria Falkenberg, Anna-Karin Berglund, Jay P. Uhler, Ali Al-Behadili, Bradley Peter, Aurelio Reyes, Reyes Tellez, Aurelio [0000-0003-2876-2202], Apollo - University of Cambridge Repository, and Apollo-University Of Cambridge Repository

Subjects

0301 basic medicine, DNA Replication, Mitochondrial DNA, RNase P, Flap Endonucleases, Ribonuclease H, Genome Integrity, Repair and Replication, Mitochondrion, Biology, DNA, Mitochondrial, Mitochondrial Proteins, 03 medical and health sciences, Genetics, Humans, Ribonuclease, Nuclease, DNA synthesis, Biochemistry and Molecular Biology, RNA, Ribonucleotides, Recombinant Proteins, Mitochondria, 030104 developmental biology, Biochemistry, biology.protein, Primer (molecular biology), Biokemi och molekylärbiologi

Abstract

The role of Ribonuclease H1 (RNase H1) during primer removal and ligation at the mitochondrial origin of light-strand DNA synthesis (OriL) is a key, yet poorly understood, step in mitochondrial DNA maintenance. Here, we reconstitute the replication cycle of L-strand synthesis in vitro using recombinant mitochondrial proteins and model OriL substrates. The process begins with initiation of DNA replication at OriL and ends with primer removal and ligation. We find that RNase H1 partially removes the primer, leaving behind the last one to three ribonucleotides. These 5′-end ribonucleotides disturb ligation, a conclusion which is supported by analysis of RNase H1-deficient patient cells. A second nuclease is therefore required to remove the last ribonucleotides and we demonstrate that Flap endonuclease 1 (FEN1) can execute this function in vitro. Removal of RNA primers at OriL thus depends on a two-nuclease model, which in addition to RNase H1 requires FEN1 or a FEN1-like activity. These findings define the role of RNase H1 at OriL and help to explain the pathogenic consequences of disease causing mutations in RNase H1.

23. Accurate mapping of mitochondrial DNA deletions and duplications using deep sequencing.

Author

Swaraj Basu, Xie Xie, Jay P Uhler, Carola Hedberg-Oldfors, Dusanka Milenkovic, Olivier R Baris, Sammy Kimoloi, Stanka Matic, James B Stewart, Nils-Göran Larsson, Rudolf J Wiesner, Anders Oldfors, Claes M Gustafsson, Maria Falkenberg, and Erik Larsson

Subjects

Genetics, QH426-470

Abstract

Deletions and duplications in mitochondrial DNA (mtDNA) cause mitochondrial disease and accumulate in conditions such as cancer and age-related disorders, but validated high-throughput methodology that can readily detect and discriminate between these two types of events is lacking. Here we establish a computational method, MitoSAlt, for accurate identification, quantification and visualization of mtDNA deletions and duplications from genomic sequencing data. Our method was tested on simulated sequencing reads and human patient samples with single deletions and duplications to verify its accuracy. Application to mouse models of mtDNA maintenance disease demonstrated the ability to detect deletions and duplications even at low levels of heteroplasmy.

Published

2020