Your search keyword '"Elaine A. Sia"' showing total 23 results

1. Roles for the Rad27 Flap Endonuclease in Mitochondrial Mutagenesis and Double-Strand Break Repair in Saccharomyces cerevisiae

Author

Lidza Kalifa, Alexis Stein, Prabha Nagarajan, Rachel Kasimer, Elaine A. Sia, and Christopher T Prevost

Subjects

0301 basic medicine, Genetics, Nuclease, Mitochondrial DNA, biology, DNA repair, Point mutation, Mutagenesis, Double Strand Break Repair, 03 medical and health sciences, 030104 developmental biology, 0302 clinical medicine, biology.protein, Flap endonuclease, 030217 neurology & neurosurgery, Nucleotide excision repair

Abstract

The structure-specific nuclease, Rad27p/FEN1, plays a crucial role in DNA repair and replication mechanisms in the nucleus. Genetic assays using the rad27-∆ mutant have shown altered rates of DNA recombination, microsatellite instability, and point mutation in mitochondria. In this study, we examined the role of Rad27p in mitochondrial mutagenesis and double-strand break (DSB) repair in Saccharomyces cerevisiae. Our findings show that Rad27p is essential for efficient mitochondrial DSB repair by a pathway that generates deletions at a region flanked by direct repeat sequences. Mutant analysis suggests that both exonuclease and endonuclease activities of Rad27p are required for its role in mitochondrial DSB repair. In addition, we found that the nuclease activities of Rad27p are required for the prevention of mitochondrial DNA (mtDNA) point mutations, and in the generation of spontaneous mtDNA rearrangements. Overall, our findings underscore the importance of Rad27p in the maintenance of mtDNA, and demonstrate that it participates in multiple DNA repair pathways in mitochondria, unlinked to nuclear phenotypes.

Published

2017

2. The influence of mitochondrial dynamics on mitochondrial genome stability

Author

Kathryn Wershing, Deanna R Pedeville, Elaine A. Sia, Christina Seger, Christopher T Prevost, Rey A. L. Sia, and Nicole Peris

Subjects

0301 basic medicine, Mitochondrial DNA, Saccharomyces cerevisiae Proteins, DNA Repair, Cell Respiration, Saccharomyces cerevisiae, Mitochondrion, Biology, DNA, Mitochondrial, Mitochondrial Dynamics, Genomic Instability, GTP Phosphohydrolases, Mitochondrial Proteins, 03 medical and health sciences, Raffinose, 0302 clinical medicine, Mitophagy, Genetics, DNA Breaks, Double-Stranded, Sequence Deletion, General Medicine, biology.organism_classification, Carbon, Mitochondria, Cell biology, 030104 developmental biology, mitochondrial fusion, Mitochondrial matrix, Genome, Mitochondrial, Mitochondrial Membranes, Mutation, Retrograde signaling, Mitochondrial fission, Gene Deletion, 030217 neurology & neurosurgery

Abstract

Mitochondria are dynamic organelles that fuse and divide. These changes alter the number and distribution of mitochondrial structures throughout the cell in response to developmental and metabolic cues. We have demonstrated that mitochondrial fission is essential to the maintenance of mitochondrial DNA (mtDNA) under changing metabolic conditions in wild-type Saccharomyces cerevisiae. While increased loss of mtDNA integrity has been demonstrated for dnm1-∆ fission mutants after growth in a non-fermentable carbon source, we demonstrate that growth of yeast in different carbon sources affects the frequency of mtDNA loss, even when the carbon sources are fermentable. In addition, we demonstrate that the impact of fission on mtDNA maintenance during growth in different carbon sources is neither mediated by retrograde signaling nor mitophagy. Instead, we demonstrate that mitochondrial distribution and mtDNA maintenance phenotypes conferred by loss of Dnm1p are suppressed by the loss of Sod2p, the mitochondrial matrix superoxide dismutase.

Published

2017

3. Human mitochondrial DNA repair

Author

Alexis Stein and Elaine Ayres Sia

Subjects

Mitochondrial DNA, Nuclear gene, Mitochondrial DNA repair, Computational biology, Mitochondrion, Biology, Subcellular localization, Human mitochondrial genetics, Genome, Gene

Abstract

Human diseases caused by inherited mutations in the mitochondrial genome demonstrate the importance of maintaining mitochondrial DNA with high fidelity. Although the mitochondrial genome encodes few genes, relative to the nuclear genome, functional copies of these genes are essential to the viability of humans. Many repair proteins are shared between nuclei and mitochondria, but the mechanisms of their action and the regulation of their subcellular localization are not well understood. While some pathways of mitochondrial DNA repair have been studied for decades, a comprehensive picture of the suite of proteins that ensure maintenance of the mitochondrial genome is still developing. The results of recent studies suggest a robust and complex network of repair pathways that maintain the integrity of this organellar genome.

Published

2020

4. Mitochondria-encoded genes contribute to evolution of heat and cold tolerance in yeast

Author

Justin C. Fay, Elaine A. Sia, Xueying C. Li, Chris Todd Hittinger, David Peris, National Institutes of Health (US), National Institute of Food and Agriculture (US), National Science Foundation (US), Great Lakes Bioenergy Research Center (US), The Pew Charitable Trusts, and European Commission

Subjects

Thermotolerance, Mitochondrial DNA, congenital, hereditary, and neonatal diseases and abnormalities, Hot Temperature, Saccharomyces cerevisiae Proteins, Saccharomyces cerevisiae, genetic processes, information science, Mitochondrion, urologic and male genital diseases, Genetic analysis, DNA, Mitochondrial, Electron Transport Complex IV, Evolution, Molecular, 03 medical and health sciences, Genetics, Gene, Research Articles, Alleles, 030304 developmental biology, 0303 health sciences, Multidisciplinary, biology, Base Sequence, 030306 microbiology, food and beverages, SciAdv r-articles, Reproductive isolation, biology.organism_classification, Phenotype, Yeast, Cold Temperature, Genes, Mitochondrial, Genome, Mitochondrial, Research Article

Abstract

Genetic analysis of phenotypic differences between species is typically limited to interfertile species. Here, we conducted a genome-wide noncomplementation screen to identify genes that contribute to a major difference in thermal growth profile between two reproductively isolated yeast species, Saccharomyces cerevisiae and Saccharomyces uvarum. The screen identified only a single nuclear-encoded gene with a moderate effect on heat tolerance, but, in contrast, revealed a large effect of mitochondrial DNA (mitotype) on both heat and cold tolerance. Recombinant mitotypes indicate that multiple genes contribute to thermal divergence, and we show that protein divergence in COX1 affects both heat and cold tolerance. Our results point to the yeast mitochondrial genome as an evolutionary hotspot for thermal divergence., This work was supported by the NIH (grant GM080669) to J.C.F. Additional support to C.T.H. was provided by the USDA National Institute of Food and Agriculture (Hatch project 1003258), the National Science Foundation (DEB-1253634), and the DOE Great Lakes Bioenergy Research Center (DOE BER Office of Science DE-SC0018409 and DE-FC02-07ER64494 to T. J. Donohue). C.T.H. is a Pew Scholar in the Biomedical Sciences and a Vilas Faculty Early Career Investigator, supported by the Pew Charitable Trusts and the Vilas Trust Estate, respectively. D.P. is a Marie Sklodowska-Curie fellow of the European Union’s Horizon 2020 research and innovation programme (grant agreement no. 747775).

Published

2019

5. Mitochondrial DNA repair and damage tolerance

Author

Alexis Stein and Elaine A. Sia

Subjects

0301 basic medicine, Mitochondrial DNA, DNA Repair, DNA repair, DNA damage, Saccharomyces cerevisiae, Biology, Genome, DNA, Mitochondrial, 03 medical and health sciences, Animals, Humans, DNA, Fungal, Genetics, Genome, Human, Base excision repair, Cell biology, Mitochondria, 030104 developmental biology, Mitochondrial DNA repair, Genome, Mitochondrial, Mutation, DNA mismatch repair, Genome, Fungal, Homologous recombination, DNA Damage

Abstract

The accurate maintenance of mitochondrial DNA (mtDNA) is required in order for eukaryotic cells to assemble a functional electron transport chain. This independently-maintained genome relies on nuclear-encoded proteins that are imported into the mitochondria to carry out replication and repair processes. Decades of research has made clear that mitochondria employ robust and varied mtDNA repair and damage tolerance mechanisms in order to ensure the proper maintenance of the mitochondrial genome. This review focuses on our current understanding of mtDNA repair and damage tolerance pathways including base excision repair, mismatch repair, homologous recombination, non-homologous end joining, translesion synthesis and mtDNA degradation in both yeast and mammalian systems.

Published

2016

6. Mitochondrial Genome Maintenance: Roles for Nuclear Nonhomologous End-Joining Proteins in Saccharomyces cerevisiae

Author

Daniel F Quintana, Lidza Kalifa, Garry L Coles, Laura K Schiraldi, Rey A. L. Sia, Naina Phadnis, and Elaine A. Sia

Subjects

Mitochondrial DNA, DNA End-Joining Repair, Saccharomyces cerevisiae Proteins, DNA Repair, Saccharomyces cerevisiae, Investigations, Biology, DNA, Mitochondrial, Human mitochondrial genetics, Genome, Mutation Rate, Gene Order, Genetics, DNA Breaks, Double-Stranded, Deoxyribonucleases, Type II Site-Specific, Ku Autoantigen, Repetitive Sequences, Nucleic Acid, Sequence Deletion, Cell Nucleus, Recombination, Genetic, mtDNA control region, Endodeoxyribonucleases, Models, Genetic, Mitochondrial genome maintenance, Nuclear Proteins, Antigens, Nuclear, Mitochondria, DNA-Binding Proteins, Non-homologous end joining, Exodeoxyribonucleases, Phenotype, mitochondrial fusion, Genome, Mitochondrial, Homologous recombination, Signal Transduction

Abstract

Mitochondrial DNA (mtDNA) deletions are associated with sporadic and inherited diseases and age-associated neurodegenerative disorders. Approximately 85% of mtDNA deletions identified in humans are flanked by short directly repeated sequences; however, mechanisms by which these deletions arise are unknown. A limitation in deciphering these mechanisms is the essential nature of the mitochondrial genome in most living cells. One exception is budding yeast, which are facultative anaerobes and one of the few organisms for which directed mtDNA manipulation is possible. Using this model system, we have developed a system to simultaneously monitor spontaneous direct-repeat–mediated deletions (DRMDs) in the nuclear and mitochondrial genomes. In addition, the mitochondrial DRMD reporter contains a unique KpnI restriction endonuclease recognition site that is not present in otherwise wild-type (WT) mtDNA. We have expressed KpnI fused to a mitochondrial localization signal to induce a specific mitochondrial double-strand break (mtDSB). Here we report that loss of the MRX (Mre11p, Rad50p, Xrs2p) and Ku70/80 (Ku70p, Ku80p) complexes significantly impacts the rate of spontaneous deletion events in mtDNA, and these proteins contribute to the repair of induced mtDSBs. Furthermore, our data support homologous recombination (HR) as the predominant pathway by which mtDNA deletions arise in yeast, and suggest that the MRX and Ku70/80 complexes are partially redundant in mitochondria.

Published

2012

7. Evidence for a role of FEN1 in maintaining mitochondrial DNA integrity

Author

Gisela Beutner, Elaine A. Sia, Shey-Shing Sheu, Naina Phadnis, and Lidza Kalifa

Subjects

Male, Mitochondrial DNA, Saccharomyces cerevisiae Proteins, DNA Repair, Flap Endonucleases, DNA repair, Saccharomyces cerevisiae, Mitochondrion, Biology, DNA, Mitochondrial, Biochemistry, Article, Mice, Animals, Molecular Biology, DNA synthesis, Cell Biology, Base excision repair, biology.organism_classification, Molecular biology, Cell biology, Protein Transport, genomic DNA, Microscopy, Fluorescence, Mitochondrial fission, Gene Deletion

Abstract

Although the nuclear processes responsible for genomic DNA replication and repair are well characterized, the pathways involved in mitochondrial DNA (mtDNA) replication and repair remain unclear. DNA repair has been identified as being particularly important within the mitochondrial compartment due to the organelle’s high propensity to accumulate oxidative DNA damage. It has been postulated that continual accumulation of mtDNA damage and subsequent mutagenesis may function in cellular aging. Mitochondrial base excision repair (mtBER) plays a major role in combating mtDNA oxidative damage; however, the proteins involved in mtBER have yet to be fully characterized. It has been established that during nuclear long-patch (LP) BER, FEN1 is responsible for cleavage of 5′ flap structures generated during DNA synthesis. Furthermore, removal of 5′ flaps has been observed in mitochondrial extracts of mammalian cell lines; yet, the mitochondrial localization of FEN1 has not been clearly demonstrated. In this study, we analyzed the effects of deleting the yeast FEN1 homolog, RAD27, on mtDNA stability in Saccharomyces cerevisiae. Our findings demonstrate that Rad27p/FEN1 is localized in the mitochondrial compartment of both yeast and mice and that Rad27p has a significant role in maintaining mtDNA integrity.

Published

2009

8. Structural and Functional Divergence within the Dim1/KsgA Family of rRNA Methyltransferases

Author

Zhili Xu, Leah A. Pogorzala, Faik N. Musayev, Nagesh Pulicherla, Gloria M. Culver, Jason P. Rife, Heather C. O′Farrell, J. Neel Scarsdale, and Elaine A. Sia

Subjects

Models, Molecular, Methanococcus, Saccharomyces cerevisiae Proteins, Archaeal Proteins, Recombinant Fusion Proteins, Molecular Sequence Data, Saccharomyces cerevisiae, Ribosome biogenesis, RRNA methylation, Crystallography, X-Ray, Ribosome, Article, Structural Biology, Animals, Humans, Amino Acid Sequence, Molecular Biology, Genetics, biology, Genetic Complementation Test, Methanocaldococcus jannaschii, Methyltransferases, Ribosomal RNA, biology.organism_classification, Protein Structure, Tertiary, Sequence Alignment, Functional divergence

Abstract

The enzymes of the KsgA/Dim1 family are universally distributed throughout all phylogeny; however, structural and functional differences are known to exist. The well-characterized function of these enzymes is to dimethylate two adjacent adenosines of the small ribosomal subunit in the normal course of ribosome maturation, and the structures of KsgA from Escherichia coli and Dim1 from Homo sapiens and Plasmodium falciparum have been determined. To this point, no examples of archaeal structures have been reported. Here, we report the structure of Dim1 from the thermophilic archaeon Methanocaldococcus jannaschii. While it shares obvious similarities with the bacterial and eukaryotic orthologs, notable structural differences exist among the three members, particularly in the C-terminal domain. Previous work showed that eukaryotic and archaeal Dim1 were able to robustly complement for KsgA in E. coli. Here, we repeated similar experiments to test for complementarity of archaeal Dim1 and bacterial KsgA in Saccharomyces cerevisiae. However, neither the bacterial nor the archaeal ortholog could complement for the eukaryotic Dim1. This might be related to the secondary, non-methyltransferase function that Dim1 is known to play in eukaryotic ribosomal maturation. To further delineate regions of the eukaryotic Dim1 critical to its function, we created and tested KsgA/Dim1 chimeras. Of the chimeras, only one constructed with the N-terminal domain from eukaryotic Dim1 and the C-terminal domain from archaeal Dim1 was able to complement, suggesting that eukaryotic-specific Dim1 function resides in the N-terminal domain also, where few structural differences are observed between members of the KsgA/Dim1 family. Future work is required to identify those determinants directly responsible for Dim1 function in ribosome biogenesis. Finally, we have conclusively established that none of the methyl groups are critically important to growth in yeast under standard conditions at a variety of temperatures.

Published

2009

9. Evidence That Msh1p Plays Multiple Roles in Mitochondrial Base Excision Repair

Author

Shona A. Mookerjee, Elaine Ayres Sia, and Leah A. Pogorzala

Subjects

Mitochondrial DNA, Saccharomyces cerevisiae Proteins, DNA Repair, DNA repair, Saccharomyces cerevisiae, Mutant, Investigations, Mitochondrion, medicine.disease_cause, DNA, Mitochondrial, Fungal Proteins, Mitochondrial Proteins, Adenosine Triphosphate, DNA-(Apurinic or Apyrimidinic Site) Lyase, Genetics, medicine, DNA, Fungal, Adenosine Triphosphatases, Cell Nucleus, Mutation, Endodeoxyribonucleases, Base Sequence, Models, Genetic, biology, Epistasis, Genetic, Base excision repair, biology.organism_classification, DNA-Binding Proteins, DNA Repair Enzymes, mitochondrial fusion, Gene Deletion, Protein Binding

Abstract

Mitochondrial DNA is thought to be especially prone to oxidative damage by reactive oxygen species generated through electron transport during cellular respiration. This damage is mitigated primarily by the base excision repair (BER) pathway, one of the few DNA repair pathways with confirmed activity on mitochondrial DNA. Through genetic epistasis analysis of the yeast Saccharomyces cerevisiae, we examined the genetic interaction between each of the BER proteins previously shown to localize to the mitochondria. In addition, we describe a series of genetic interactions between BER components and the MutS homolog MSH1, a respiration-essential gene. We show that, in addition to their variable effects on mitochondrial function, mutant msh1 alleles conferring partial function interact genetically at different points in mitochondrial BER. In addition to this separation of function, we also found that the role of Msh1p in BER is unlikely to be involved in the avoidance of large-scale deletions and rearrangements.

Published

2009

10. Analysis of Rev1p and Pol ζ in mitochondrial mutagenesis suggests an alternative pathway of damage tolerance

Author

Elaine A. Sia and Lidza Kalifa

Subjects

DNA Replication, Mitochondrial DNA, Saccharomyces cerevisiae Proteins, biology, Ultraviolet Rays, DNA repair, DNA polymerase, DNA damage, Point mutation, Mutagenesis, DNA replication, DNA-Directed DNA Polymerase, Cell Biology, Mitochondrion, Nucleotidyltransferases, Biochemistry, Molecular biology, Article, biology.protein, Point Mutation, DNA, Fungal, Molecular Biology, DNA Damage

Abstract

Ultraviolet light is a potent DNA damaging agent that induces bulky lesions in DNA which block the replicative polymerases. In order to ensure continued DNA replication and cell viability, specialized translesion polymerases bypass these lesions at the expense of introducing mutations in the nascent DNA strand. A recent study has shown that the N-terminal sequences of the nuclear translesion polymerases Rev1p and Pol zeta can direct GFP to the mitochondrial compartment of Saccharomyces cerevisiae. We have investigated the role of these polymerases in mitochondrial mutagenesis. Our analysis of mitochondrial DNA point mutations, microsatellite instability, and the spectra of mitochondrial mutations indicate that these translesion polymerases function in a less mutagenic pathway in the mitochondrial compartment than they do in the nucleus. Mitochondrial phenotypes resulting from the loss of Rev1p and Pol zeta suggest that although these polymerases are responsible for the majority of mitochondrial frameshift mutations, they do not greatly contribute to mitochondrial DNA point mutations. Analysis of spontaneous mitochondrial DNA point mutations suggests that Pol zeta may play a role in general mitochondrial DNA maintenance. In addition, we observe a 20-fold increase in UV-induced mitochondrial DNA point mutations in rev deficient strains. Our data provides evidence for an alternative damage tolerance pathway that is specific to the mitochondrial compartment.

Published

2007

11. Members of the RAD52 Epistasis Group Contribute to Mitochondrial Homologous Recombination and Double-Strand Break Repair in Saccharomyces cerevisiae

Author

Lidza Kalifa, Alexis Stein, and Elaine A. Sia

Subjects

Cancer Research, Mitochondrial DNA, Saccharomyces cerevisiae Proteins, DNA Repair, lcsh:QH426-470, DNA repair, Saccharomyces cerevisiae, Biology, Mitochondrion, Genome, DNA, Mitochondrial, Genetics, DNA, Fungal, Molecular Biology, Genetics (clinical), Ecology, Evolution, Behavior and Systematics, Recombination, Genetic, Epistasis, Genetic, biology.organism_classification, Double Strand Break Repair, Nuclear DNA, Rad52 DNA Repair and Recombination Protein, DNA-Binding Proteins, lcsh:Genetics, Rad51 Recombinase, Homologous recombination, DNA Damage, Research Article

Abstract

Mitochondria contain an independently maintained genome that encodes several proteins required for cellular respiration. Deletions in the mitochondrial genome have been identified that cause several maternally inherited diseases and are associated with certain cancers and neurological disorders. The majority of these deletions in human cells are flanked by short, repetitive sequences, suggesting that these deletions may result from recombination events. Our current understanding of the maintenance and repair of mtDNA is quite limited compared to our understanding of similar events in the nucleus. Many nuclear DNA repair proteins are now known to also localize to mitochondria, but their function and the mechanism of their action remain largely unknown. This study investigated the contribution of the nuclear double-strand break repair (DSBR) proteins Rad51p, Rad52p and Rad59p in mtDNA repair. We have determined that both Rad51p and Rad59p are localized to the matrix of the mitochondria and that Rad51p binds directly to mitochondrial DNA. In addition, a mitochondrially-targeted restriction endonuclease (mtLS-KpnI) was used to produce a unique double-strand break (DSB) in the mitochondrial genome, which allowed direct analysis of DSB repair in vivo in Saccharomyces cerevisiae. We find that loss of these three proteins significantly decreases the rate of spontaneous deletion events and the loss of Rad51p and Rad59p impairs the repair of induced mtDNA DSBs., Author Summary Mitochondria are the powerhouse of the cell, providing energy in the form of ATP. Several proteins required for the production of ATP are encoded in the mitochondrial genome, which is maintained independently from the nuclear genome. Mutations in mitochondrial DNA are responsible for several inherited diseases and are associated with certain cancers, neurological disorders, and aging. In human mtDNA, 90% of deletions, a specific type of mutation, are flanked by repetitive sequences. Deletions in this context are generally produced through homologous recombination, specifically single-strand annealing. For the first time, in this study we show that the proteins involved in nuclear homologous recombination, Rad51p, Rad52p, and Rad59p, also contribute to the formation of mitochondrial deletions. Our data also suggest a novel mitochondrial-specific role for Rad51p in the generation of this type of deletion. Further study of these repair pathways allows us to garner a better understanding of these processes that are involved in disease pathologies and aging.

Published

2015

12. Overlapping contributions of Msh1p and putative recombination proteins Cce1p, Din7p, and Mhr1p in large-scale recombination and genome sorting events in the mitochondrial genome of Saccharomyces cerevisiae

Author

Elaine A. Sia and Shona A. Mookerjee

Subjects

Mitochondrial DNA, Saccharomyces cerevisiae Proteins, Health, Toxicology and Mutagenesis, Cell Respiration, Genes, Fungal, Molecular Sequence Data, Saccharomyces cerevisiae, medicine.disease_cause, DNA, Mitochondrial, Genome, Genomic Instability, Fungal Proteins, Mitochondrial Proteins, Genetics, medicine, Point Mutation, Amino Acid Sequence, DNA, Fungal, Molecular Biology, Gene, Sequence Deletion, Recombination, Genetic, Mutation, biology, Point mutation, Holliday Junction Resolvases, Nuclear Proteins, biology.organism_classification, Diploidy, Heteroplasmy, DNA-Binding Proteins, Protein Transport, Exodeoxyribonucleases, DNA mismatch repair, Genome, Fungal, Dimerization, Transcription Factors

Abstract

The mechanisms that govern mutation avoidance in the mitochondrial genome, though believed to be numerous, are poorly understood. The identification of individual genes has implicated mismatch repair and several recombination pathways in maintaining the fidelity and structural stability of mitochondrial DNA. However, the majority of genes in these pathways have not been identified and the interactions between different pathways have not been extensively studied. Additionally, the multicopy presence of the mitochondrial genome affects the occurrence and persistence of mutant phenotypes, making mitochondrial DNA transmission and sorting important factors affecting mutation accumulation. We present new evidence that the putative recombination genes CCE1, DIN7, and MHR1 have overlapping function with the mismatch repair homolog MSH1 in point mutation avoidance and suppression of aberrant recombination events. In addition, we demonstrate a novel role for Msh1p in mtDNA transmission, a role not predicted by studies of its nuclear homologs.

Published

2006

13. Analysis of the functional domains of the mismatch repair homologue Msh1p and its role in mitochondrial genome maintenance

Author

Shona A. Mookerjee, Hiram D. Lyon, and Elaine A. Sia

Subjects

Mitochondrial DNA, Saccharomyces cerevisiae Proteins, DNA Repair, Base Pair Mismatch, DNA repair, Blotting, Western, Molecular Sequence Data, Biology, Mitochondrion, Fungal Proteins, Mitochondrial Proteins, MutS-1, Genetics, Amino Acid Sequence, DNA Primers, Base Sequence, Sequence Homology, Amino Acid, Mitochondrial genome maintenance, General Medicine, Mismatch Repair Protein, DNA-Binding Proteins, Microscopy, Fluorescence, mitochondrial fusion, DNA mismatch repair, Genome, Fungal, Plasmids

Abstract

Mitochondrial DNA (mtDNA) repair occurs in all eukaryotic organisms and is essential for the maintenance of mitochondrial function. Evidence from both humans and yeast suggests that mismatch repair is one of the pathways that functions in overall mtDNA stability. In the mitochondria of the yeast Saccharomyces cerevisiae, the presence of a homologue to the bacterial MutS mismatch repair protein, MSH1, has long been known to be essential for mitochondrial function. The mechanisms for which it is essential are unclear, however. Here, we analyze the effects of two point mutations, msh1-F105A and msh1-G776D, both predicted to be defective in mismatch repair; and we show that they are both able to maintain partial mitochondrial function. Moreover, there are significant differences in the severity of mitochondrial disruption between the two mutants that suggest multiple roles for Msh1p in addition to mismatch repair. Our overall findings suggest that these additional predicted functions of Msh1p, including recombination surveillance and heteroduplex rejection, may be primarily responsible for its essential role in mtDNA stability.

Published

2004

14. DNA double-strand breaks activate ATM independent of mitochondrial dysfunction in A549 cells

Author

Michael A. O'Reilly, Paul S. Brookes, Rhonda J. Staversky, Elaine A. Sia, Jennifer S. Gewandter, and Lidza Kalifa

Subjects

Cyclin-Dependent Kinase Inhibitor p21, Mitochondrial DNA, DNA Repair, DNA damage, DNA repair, Chromosomal Proteins, Non-Histone, Apoptosis, Cell Cycle Proteins, Ataxia Telangiectasia Mutated Proteins, Mitochondrion, Biology, Tripartite Motif-Containing Protein 28, Transfection, Biochemistry, Article, Physiology (medical), Cell Line, Tumor, medicine, Humans, DNA Breaks, Double-Stranded, Phosphorylation, Deoxyribonucleases, Type II Site-Specific, Cell Proliferation, Cell Nucleus, Membrane Potential, Mitochondrial, DNA, medicine.disease, Molecular biology, Nuclear DNA, Mitochondria, Repressor Proteins, Cell nucleus, medicine.anatomical_structure, Retroviridae, Ataxia-telangiectasia, Tumor Suppressor Protein p53, Reactive Oxygen Species

Abstract

Excessive nuclear or mitochondrial DNA damage can lead to mitochondrial dysfunction, decreased energy production, and increased generation of reactive oxygen species (ROS). Although numerous cell signaling pathways are activated when cells are injured, the ataxia telangiectasia mutant (ATM) protein has emerged as a major regulator of the response to both mitochondrial dysfunction and nuclear DNA double-strand breaks (DSBs). Because mitochondrial dysfunction is often a response to excessive DNA damage, it has been difficult to determine whether nuclear and/or mitochondrial DNA DSBs activate ATM independent of mitochondrial dysfunction. In this study, mitochondrial and nuclear DNA DSBs were generated in the A549 human lung adenocarcinoma cell line by infecting with retroviruses expressing the restriction endonuclease PstI fused to a mitochondrial targeting sequence (MTS) or nuclear localization sequence (NLS) and a hemagglutinin antigen epitope tag (HA). Expression of MTS-PstI-HA or NLS-PstI-HA activated the DNA damage response defined by phosphorylation of ATM, the tumor suppressor protein p53 (TP53), KRAB-associated protein (KAP)-1, and structural maintenance of chromosomes (SMC)-1. Phosphorylated ATM and SMC1 were detected in nuclear fractions, whereas phosphorylated TP53 and KAP1 were detected in both mitochondrial and nuclear fractions. PstI also enhanced expression of the cyclin-dependent kinase inhibitor p21 and inhibited cell growth. This response to DNA damage occurred in the absence of detectable mitochondrial dysfunction and excess production of ROS. These findings reveal that DNA DSBs are sufficient to activate ATM independent of mitochondrial dysfunction and suggest that the activated form of ATM and some of its substrates are restricted to the nuclear compartment, regardless of the site of DNA damage.

Published

2014

15. Using Genetic Reporters to Assess Stability and Mutation of the Yeast Mitochondrial Genome

Author

Elaine A. Sia and Shona A. Mookerjee

Subjects

Genetics, 0303 health sciences, Mutation, Mitochondrial DNA, Cell, Biology, Mitochondrion, medicine.disease_cause, Yeast, 03 medical and health sciences, chemistry.chemical_compound, 0302 clinical medicine, medicine.anatomical_structure, chemistry, Extrachromosomal DNA, medicine, 030217 neurology & neurosurgery, Function (biology), DNA, 030304 developmental biology

Abstract

The mitochondrion has been an identified subcellular organelle since the late 1800s, though its function and importance remained relatively cryptic until almost a century later. With the molecular renaissance of the 1950s and 1960s came the tools and perspectives, including peptide sequencing, microscopy, and the chemiosmotic hypothesis, with which to formulate and test crucial questions about what mitochondria do and how they function. In addition, shortly after the structure of DNA was elucidated and its role as the genetic material of the cell established, the presence of extranuclear DNA was revealed by electron microscopy (Nass and Nass, 1963) and by density gradient fractionation (Haslbrunner et al., 1964), identifying this DNA as part of highly purified mitochondria.

Published

2013

16. Ntg1p, the base excision repair protein, generates mutagenic intermediates in yeast mitochondrial DNA

Author

Elaine A. Sia, Naina Phadnis, Nida Meednu, and Reema Mehta

Subjects

Mitochondrial DNA, Saccharomyces cerevisiae Proteins, DNA Repair, Ultraviolet Rays, Gene Expression, Oxidative phosphorylation, Saccharomyces cerevisiae, Mitochondrion, Biochemistry, Genome, DNA, Mitochondrial, Models, Biological, AP endonuclease, DNA Glycosylases, DNA-(Apurinic or Apyrimidinic Site) Lyase, Point Mutation, DNA, Fungal, Frameshift Mutation, Molecular Biology, N-Glycosyl Hydrolases, Recombination, Genetic, Endodeoxyribonucleases, biology, Base Sequence, Point mutation, Cell Biology, Base excision repair, Yeast, Oxygen, DNA Repair Enzymes, Mutation, biology.protein, Genome, Fungal

Abstract

Mitochondrial DNA is predicted to be highly prone to oxidative damage due to its proximity to free radicals generated by oxidative phosphorylation. Base excision repair (BER) is the primary repair pathway responsible for repairing oxidative damage in nuclear and mitochondrial genomes. In yeast mitochondria, three N-glycosylases have been identified so far, Ntg1p, Ogg1p and Ung1p. Ntg1p, a broad specificity N-glycosylase, takes part in catalyzing the first step of BER that involves the removal of the damaged base. In this study, we examined the role of Ntg1p in maintaining yeast mitochondrial genome integrity. Using genetic reporters and assays to assess mitochondrial mutations, we found that loss of Ntg1p suppresses mitochondrial point mutation rates, frameshifts and recombination rates. We also observed a suppression of respiration loss in the ntg1-Δ cells in response to ultraviolet light exposure implying an overlap between BER and UV-induced damage in the yeast mitochondrial compartment. Over-expression of the BER AP endonuclease, Apn1p, did not significantly affect the mitochondrial mutation rate in the presence of Ntg1p, whereas Apn1p over-expression in an ntg1-Δ background increased the frequency of mitochondrial mutations. In addition, loss of Apn1p also suppressed mitochondrial point mutations. Our work suggests that both Ntg1p and Apn1p generate mutagenic intermediates in the yeast mitochondrial genome.

Published

2006

17. Analysis of repeat-mediated deletions in the mitochondrial genome of Saccharomyces cerevisiae

Author

Naina Phadnis, Rey A. L. Sia, and Elaine A. Sia

Subjects

Genetics, Mitochondrial DNA, Models, Genetic, Point mutation, Saccharomyces cerevisiae, Biology, Investigations, biology.organism_classification, DNA, Mitochondrial, Polymerase Chain Reaction, Homology (biology), Non-homologous end joining, Blotting, Southern, Mutation, biology.protein, Direct repeat, Homologous recombination, Polymerase, Gene Deletion, Repetitive Sequences, Nucleic Acid

Abstract

Mitochondrial DNA deletions and point mutations accumulate in an age-dependent manner in mammals. The mitochondrial genome in aging humans often displays a 4977-bp deletion flanked by short direct repeats. Additionally, direct repeats flank two-thirds of the reported mitochondrial DNA deletions. The mechanism by which these deletions arise is unknown, but direct-repeat-mediated deletions involving polymerase slippage, homologous recombination, and nonhomologous end joining have been proposed. We have developed a genetic reporter to measure the rate at which direct-repeat-mediated deletions arise in the mitochondrial genome of Saccharomyces cerevisiae. Here we analyze the effect of repeat size and heterology between repeats on the rate of deletions. We find that the dependence on homology for repeat-mediated deletions is linear down to 33 bp. Heterology between repeats does not affect the deletion rate substantially. Analysis of recombination products suggests that the deletions are produced by at least two different pathways, one that generates only deletions and one that appears to generate both deletions and reciprocal products of recombination. We discuss how this reporter may be used to identify the proteins in yeast that have an impact on the generation of direct-repeat-mediated deletions.

Published

2005

18. The yeast MSH1 gene is not involved in DNA repair or recombination during meiosis

Author

Elaine A. Sia and David T. Kirkpatrick

Subjects

Saccharomyces cerevisiae Proteins, DNA Repair, FLP-FRT recombination, Molecular Sequence Data, Saccharomyces cerevisiae, Biology, Biochemistry, Genetic recombination, Fungal Proteins, Mitochondrial Proteins, MutS-1, Amino Acid Sequence, DNA, Fungal, Molecular Biology, Replication protein A, Genetics, Recombination, Genetic, Sequence Homology, Amino Acid, Cell Biology, DNA repair protein XRCC4, Spores, Fungal, DNA-Binding Proteins, Meiosis, MSH2, DNA mismatch repair, Homologous recombination

Abstract

Six strong homologs of the bacterial MutS DNA mismatch repair (MMR) gene have been identified in the yeast Saccharomyces cerevisiae. With the exception of the MSH1 gene, the involvement of each homolog in DNA repair and recombination during meiosis has been determined previously. Five of the homologs have been demonstrated to act in meiotic DNA repair (MSH2, MSH3, MSH6 and MSH4) and/or meiotic recombination (MSH4 and MSH5). Unfortunately the loss of mitochondrial function that results from deletion of MSH1 disrupts meiotic progression, precluding an analysis of MSH1 function in meiotic DNA repair and recombination. However, the recent identification of two separation-of-function alleles of MSH1 that interfere with protein function but still maintain functional mitochondria allow the meiotic activities of MSH1 to be determined. We show that the G776D and F105A alleles of MSH1 exhibit no defects in meiotic recombination, repair base–base mismatches and large loop mismatches efficiently during meiosis, and have high levels of spore viability. These data indicate that the MSH1 protein, unlike other MutS homologs in yeast, plays no role in DNA repair or recombination during meiosis.

Published

2004

19. Role of the putative structural protein Sed1p in mitochondrial genome maintenance

Author

Naina Phadnis and Elaine Ayres Sia

Subjects

Genetics, Mitochondrial DNA, Membrane Glycoproteins, Saccharomyces cerevisiae Proteins, Base Sequence, Mitochondrial genome maintenance, Fluorescent Antibody Technique, Biology, MT-RNR1, DNA, Mitochondrial, Heteroplasmy, Mitochondria, Structural Biology, Two-Hybrid System Techniques, DNAJA3, Point Mutation, Mitochondrial fission, ATP–ADP translocase, Genome, Fungal, Molecular Biology, HSPA9

Abstract

The nuclear gene MIP1 encodes the mitochondrial DNA polymerase responsible for replicating the mitochondrial genome in Saccharomyces cerevisiae. A number of other factors involved in replicating and segregating the mitochondrial genome are yet to be identified. Here, we report that a bacterial two-hybrid screen using the mitochondrial polymerase, Mip1p, as bait identified the yeast protein Sed1p. Sed1p is a cell surface protein highly expressed in the stationary phase. We find that several modified forms of Sed1p are expressed and the largest of these forms interacts with the mitochondrial polymerase in vitro. Deletion of SED1 causes a 3.5-fold increase in the rate of mitochondrial DNA point mutations as well as a 4.3-fold increase in the rate of loss of respiration. In contrast, we see no change in the rate of nuclear point mutations indicating the specific role of Sed1p function in mitochondrial genome stability. Indirect immunofluorescence analysis of Sed1p localization shows that Sed1p is targeted to the mitochondria. Moreover, Sed1p is detected in purified mitochondrial fractions and the localization to the mitochondria of the largest modified form is insensitive to the action of proteinase K. Deletion of the sed1 gene results in a reduction in the quantity of Mip1p and also affects the levels of a mitochondrially-expressed protein, Cox3p. Our results point towards a role for Sed1p in mitochondrial genome maintenance.

Published

2004

20. Isolation and Characterization of Point Mutations in Mismatch Repair Genes That Destabilize Microsatellites in Yeast

Author

Thomas D. Petes, Elaine Ayres Sia, Lela Stefanovic, and Margaret Dominska

Subjects

Heterozygote, Saccharomyces cerevisiae Proteins, DNA Repair, DNA repair, Base Pair Mismatch, Saccharomyces cerevisiae, Biology, Fungal Proteins, medicine, Point Mutation, DNA, Fungal, Molecular Biology, Adaptor Proteins, Signal Transducing, Genes, Dominant, Genetics, Point mutation, Mutagenesis, Microsatellite instability, Cell Biology, medicine.disease, Molecular biology, DNA Dynamics and Chromosome Structure, Diploidy, DNA-Binding Proteins, MutL Proteins, MutS Homolog 2 Protein, Phenotype, MSH3, MSH2, MutS Homolog 3 Protein, DNA mismatch repair, Carrier Proteins, MutL Protein Homolog 1, Genetic screen, Microsatellite Repeats

Abstract

The stability of simple repetitive DNA sequences (microsatellites) is a sensitive indicator of the ability of a cell to repair DNA mismatches. In a genetic screen for yeast mutants with elevated microsatellite instability, we identified strains containing point mutations in the yeast mismatch repair genes, MSH2, MSH3, MLH1, and PMS1. Some of these mutations conferred phenotypes significantly different from those of null mutations in these genes. One semidominant MSH2 mutation was identified. Finally we showed that strains heterozygous for null mutations of mismatch repair genes in diploid strains in yeast confer subtle defects in the repair of small DNA loops.

Published

2001

21. Analysis of microsatellite mutations in the mitochondrial DNA of Saccharomyces cerevisiae

Author

Thomas D. Petes, Margaret Dominska, Elaine Ayres Sia, Thomas D. Fox, Patricia W. Greenwell, and Christine A. Butler

Subjects

Mitochondrial DNA, Nuclear gene, Saccharomyces cerevisiae Proteins, Saccharomyces cerevisiae, DNA Mutational Analysis, medicine.disease_cause, DNA, Mitochondrial, Fungal Proteins, Mitochondrial Proteins, Genes, Reporter, medicine, Coding region, Repeated sequence, DNA, Fungal, Dinucleotide Repeats, Genetics, Reporter gene, Mutation, Multidisciplinary, biology, Biological Sciences, biology.organism_classification, Molecular biology, DNA-Binding Proteins, Microsatellite, Microsatellite Repeats

Abstract

In the nuclear genome of Saccharomyces cerevisiae , simple, repetitive DNA sequences (microsatellites) mutate at rates much higher than nonrepetitive sequences. Most of these mutations are deletions or additions of repeat units. The yeast mitochondrial genome also contains many microsatellites. To examine the stability of these sequences, we constructed a reporter gene ( arg8 m ) containing out-of-frame insertions of either poly(AT) or poly(GT) tracts within the coding sequence. Yeast strains with this reporter gene inserted within the mitochondrial genome were constructed. Using these strains, we showed that poly(GT) tracts were considerably less stable than poly(AT) tracts and that alterations usually involved deletions rather than additions of repeat units. In contrast, in the nuclear genome, poly(GT) and poly(AT) tracts had similar stabilities, and alterations usually involved additions rather than deletions. Poly(GT) tracts were more stable in the mitochondria of diploid cells than in haploids. In addition, an msh1 mutation destabilized poly(GT) tracts in the mitochondrial genome.

Published

2000

22. Microsatellite instability in yeast: dependence on repeat unit size and DNA mismatch repair genes

Author

Thomas D. Petes, Robert J. Kokoska, Elaine Ayres Sia, Margaret Dominska, and Patricia W. Greenwell

Subjects

Genetics, DNA Repair, DNA repair, Nucleic Acid Heteroduplexes, Chromosome Mapping, Cell Biology, Saccharomyces cerevisiae, Biology, Molecular biology, Variable number tandem repeat, MSH3, MSH2, Mutagenesis, Coding strand, Microsatellite, Humans, DNA mismatch repair, DNA, Fungal, Molecular Biology, Repeat unit, Microsatellite Repeats, Repetitive Sequences, Nucleic Acid, Research Article

Abstract

We examined the stability of microsatellites of different repeat unit lengths in Saccharomyces cerevisiae strains deficient in DNA mismatch repair. The msh2 and msh3 mutations destabilized microsatellites with repeat units of 1, 2, 4, 5, and 8 bp; a poly(G) tract of 18 bp was destabilized several thousand-fold by the msh2 mutation and about 100-fold by msh3. The msh6 mutations destabilized microsatellites with repeat units of 1 and 2 bp but had no effect on microsatellites with larger repeats. These results argue that coding sequences containing repetitive DNA tracts will be preferred target sites for mutations in human tumors with mismatch repair defects. We find that the DNA mismatch repair genes destabilize microsatellites with repeat units from 1 to 13 bp but have no effect on the stability of minisatellites with repeat units of 16 or 20 bp. Our data also suggest that displaced loops on the nascent strand, resulting from DNA polymerase slippage, are repaired differently than loops on the template strand.

Published

1997

23. Genetic control of microsatellite stability

Author

Elaine Ayres Sia, Thomas D. Petes, and Sue Jinks-Robertson

Subjects

Genetics, Mutation, DNA Repair, Base pair, DNA-Directed DNA Polymerase, Saccharomyces cerevisiae, Biology, Toxicology, medicine.disease_cause, Genome, DNA sequencing, medicine, Escherichia coli, Microsatellite, DNA mismatch repair, Repeated sequence, Molecular Biology, Gene, Microsatellite Repeats

Abstract

The genomes of all eukaryotes thus far examined Ž contain many tracts of simple repetitive DNA mi. crosatellites . These are regions of DNA in which a single base or a small number of bases is repeated. The definition of a microsatellite is somewhat arbitrary. We will define a microsatellite as a region in which 1–10 base pairs is tandemly repeated eight times or more. Microsatellites represent unstable regions of the genome, undergoing mutational changes Žusually additions or deletions of integral numbers of . repeats at rates that are much greater than that observed for non-repetitive DNA sequences. This instability has a number of interesting and important consequences. First, the instability results in polymorphic alleles that have been extremely useful in mapping studies in humans and other higher eukaryotes. Second, alterations in the lengths of simple repetitive tracts within or near genes can alter the Ž expression or function of these genes Nelson and . Warren, 1993 . In humans, a number of genetic diseases reflect expansions of simple repetitive tracts. Third, an increase in tract instability is diagnostic of

Published

1997