Your search keyword '"Vijg, Jan"' showing total 34 results

1. Aging and Genome Maintenance: Lessons from the Mouse?

Author

Hasty, Paul, Campisi, Judith, Hoeijmakers, Jan, van Steeg, Harry, and Vijg, Jan

Published

2003

2. Clonally Expanded mtDNA Point Mutations are Abundant in Individual Cells of Human Tissues

Author

Nekhaeva, Ekaterina, Bodyak, Natalya D., Kraytsberg, Yevgenya, McGrath, Sean B., Van Orsouw, Nathalie J., Pluzhnikov, Anna, Wei, Jeanne Y., Vijg, Jan, and Khrapko, Konstantin

Published

2002

3. Distinct Spectra of Somatic Mutations Accumulated with Age in Mouse Heart and Small Intestine

Author

Snyder, Wendy K., Gossen, Jan A., and Vijg, Jan

Published

2000

4. Efficient Rescue of Integrated Shuttle Vectors from Transgenic Mice: A Model for Studying Mutations in vivo

Author

Gossen, Jan A., Zwarthoff, Ellen C., Berends, Frits, Knook, Dick L., and Vijg, Jan

Published

1989

5. Genomic Priorities in Aging

Author

Hasty, Paul and Vijg, Jan

Published

2002

6. Do DNA Double-Strand Breaks Drive Aging?

Author

White, Ryan R. and Vijg, Jan

Subjects

*DNA damage, *GENETICS of aging, *CANCER genetics, *CELL death, *GENETIC mutation

Abstract

DNA double-strand breaks (DSBs) are rare, but highly toxic, lesions requiring orchestrated and conserved machinery to prevent adverse consequences, such as cell death and cancer-causing genome structural mutations. DSBs trigger the DNA damage response (DDR) that directs a cell to repair the break, undergo apoptosis, or become senescent. There is increasing evidence that the various endpoints of DSB processing by different cells and tissues are part of the aging phenotype, with each stage of the DDR associated with specific aging pathologies. In this Perspective, we discuss the possibility that DSBs are major drivers of intrinsic aging, highlighting the dynamics of spontaneous DSBs in relation to aging, the distinct age-related pathologies induced by DSBs, and the segmental progeroid phenotypes in humans and mice with genetic defects in DSB repair. A model is presented as to how DSBs could drive some of the basic mechanisms underlying age-related functional decline and death. [ABSTRACT FROM AUTHOR]

Published

2016

7. Comparative analysis of genome maintenance genes in naked mole rat, mouse, and human.

Author

MacRae, Sheila L., Zhang, Quanwei, Lemetre, Christophe, Seim, Inge, Calder, Robert B., Hoeijmakers, Jan, Suh, Yousin, Gladyshev, Vadim N., Seluanov, Andrei, Gorbunova, Vera, Vijg, Jan, and Zhang, Zhengdong D.

Subjects

COMPARATIVE studies, CELLULAR aging, DNA copy number variations, TELOMERES, DNA repair, GENETIC mutation, NUCLEAR magnetic resonance, LABORATORY rats

Abstract

Genome maintenance ( GM) is an essential defense system against aging and cancer, as both are characterized by increased genome instability. Here, we compared the copy number variation and mutation rate of 518 GM-associated genes in the naked mole rat ( NMR), mouse, and human genomes. GM genes appeared to be strongly conserved, with copy number variation in only four genes. Interestingly, we found NMR to have a higher copy number of CEBPG, a regulator of DNA repair, and TINF2, a protector of telomere integrity. NMR, as well as human, was also found to have a lower rate of germline nucleotide substitution than the mouse. Together, the data suggest that the long-lived NMR, as well as human, has more robust GM than mouse and identifies new targets for the analysis of the exceptional longevity of the NMR. [ABSTRACT FROM AUTHOR]

Published

2015

8. Deficiency of the DNA repair protein nibrin increases the basal but not the radiation induced mutation frequency in vivo.

Author

Wessendorf, Petra, Vijg, Jan, Nussenzweig, André, and Digweed, Martin

Subjects

*DNA repair, *GENETIC mutation, *NIBRIN, *PHYSIOLOGICAL effects of radiation, *CELL cycle, *LYMPHATIC cancer, *PLASMIDS, *LABORATORY mice

Abstract

Nibrin (NBN) is a member of a DNA repair complex together with MRE11 and RAD50. The complex is associated particularly with the repair of DNA double strand breaks and with the regulation of cell cycle check points. Hypomorphic mutation of components of the complex leads to human disorders characterised by radiosensitivity and increased tumour occurrence, particularly of the lymphatic system. We have examined here the relationship between DNA damage, mutation frequency and mutation spectrum in vitro and in vivo in mouse models carrying NBN mutations and a lacZ reporter plasmid. We find that NBN mutation leads to increased spontaneous DNA damage in fibroblasts in vitro and high basal mutation rates in lymphatic tissue of mice in vivo . The characteristic mutation spectrum is dominated by single base transitions rather than the deletions and complex rearrangements expected after abortive repair of DNA double strand breaks. We conclude that in the absence of wild type nibrin, the repair of spontaneous errors, presumably arising during DNA replication, makes a major contribution to the basal mutation rate. This applies also to cells heterozygous for an NBN null mutation. Mutation frequencies after irradiation in vivo were not increased in mice with nibrin mutations as might have been expected considering the radiosensitivity of NBS patient cells in vitro . Evidently apoptosis is efficient, even in the absence of wild type nibrin. [ABSTRACT FROM AUTHOR]

Published

2014

9. Whole genome sequencing of glioblastoma multiforme identifies multiple structural variations involved in EGFR activation.

Author

Furgason, John M., Li, Wenge, Milholland, Brandon, Cross, Emily, Li, Yaqin, McPherson, Christopher M., Warnick, Ronald E., Rixe, Olivier, Stambrook, Peter J., Vijg, Jan, and Bahassi, El Mustapha

Subjects

GLIOBLASTOMA multiforme treatment, NUCLEOTIDE sequencing, EPIDERMAL growth factor receptors, GENETIC mutation, PHENOTYPES, DRUG resistance in cancer cells, GENE amplification

Abstract

Next generation sequencing has become a powerful tool in dissecting and identifying mutations and genomic structural variants that accompany tumourigenesis. Sequence analysis of glioblastoma multiforme (GBM) illustrates the ability to rapidly identify mutations that may affect phenotype. Approximately 50% of human GBMs overexpress epidermal growth factor receptor (EGFR) which renders the EGFR protein a compelling therapeutic target. In brain tumours, attempts to target EGFR as a cancer therapeutic, however, have achieved little or no benefit. The mechanisms that drive therapeutic resistance to EGFR inhibitors in brain tumours are not well defined, and drug resistance contributes to the deadly and aggressive nature of the disease. Whole genome sequencing of four primary GBMs revealed multiple pathways by which EGFR protein abundance becomes deregulated in these tumours and will guide the development of new strategies for treating EGFR overexpressing tumours. Each of the four tumours displayed a different mechanism leading to increased EGFR protein levels. One mechanism is mediated by gene amplification and tandem duplication of the kinase domain. A second involves an intragenic deletion that generates a constitutively active form of the protein. A third combines the loss of a gene which encodes a protein that regulates EGFR abundance as well as an miRNA that modulates EGFR expression. A fourth mechanism entails loss of an ubiquitin ligase docking site in the C-terminal part of the protein whose absence inhibits turnover of the receptor. [ABSTRACT FROM AUTHOR]

Published

2014

10. The Progeroid Phenotype of Ku80 Deficiency Is Dominant over DNA-PKCS Deficiency.

Author

Reiling, Erwin, Dollé, Martijn E. T., Youssef, Sameh A., Lee, Moonsook, Nagarajah, Bhawani, Roodbergen, Marianne, de With, Piet, de Bruin, Alain, Hoeijmakers, Jan H., Vijg, Jan, van Steeg, Harry, and Hasty, Paul

Subjects

DNA repair, PHENOTYPES, DNA helicases, PROTEIN deficiency, SERINE/THREONINE kinases, LABORATORY mice, ANIMAL life spans, GENETIC mutation

Abstract

Ku80 and DNA-PKCS are both involved in the repair of double strand DNA breaks via the nonhomologous end joining (NHEJ) pathway. While ku80−/− mice exhibit a severely reduced lifespan and size, this phenotype is less pronounced in dna-pkcs−/− mice. However, these observations are based on independent studies with varying genetic backgrounds. Here, we generated ku80−/−, dna-pkcs−/− and double knock out mice in a C57Bl6/J*FVB F1 hybrid background and compared their lifespan, end of life pathology and mutation frequency in liver and spleen using a lacZ reporter. Our data confirm that inactivation of Ku80 and DNA-PKCS causes reduced lifespan and bodyweights, which is most severe in ku80−/− mice. All mutant mice exhibited a strong increase in lymphoma incidence as well as other aging-related pathology (skin epidermal and adnexal atrophy, trabacular bone reduction, kidney tubular anisokaryosis, and cortical and medullar atrophy) and severe lymphoid depletion. LacZ mutation frequency analysis did not show strong differences in mutation frequencies between knock out and wild type mice. The ku80−/− mice had the most severe phenotype and the Ku80-mutation was dominant over the DNA-PKCS-mutation. Presumably, the more severe degenerative effect of Ku80 inactivation on lifespan compared to DNA-PKCS inactivation is caused by additional functions of Ku80 or activity of free Ku70 since both Ku80 and DNA-PKCS are essential for NHEJ. [ABSTRACT FROM AUTHOR]

Published

2014

11. Aging genomes: A necessary evil in the logic of life.

Author

Vijg, Jan

Subjects

*GENETICS of aging, *NUCLEOTIDE sequence, *NATURAL selection, *GENETIC mutation, *DNA damage, *DNA repair, *GENETIC pleiotropy

Abstract

Genomes are inherently unstable because of the need for DNA sequence variation as a substrate for evolution through natural selection. However, most multicellular organisms have postmitotic tissues, with limited opportunity for selective removal of cells harboring persistent damage and deleterious mutations, which can therefore contribute to functional decline, disease, and death. Key in this process is the role of genome maintenance, the network of protein products that repair DNA damage and signal DNA damage response pathways. Genome maintenance is beneficial early in life by swiftly eliminating DNA damage or damaged cells, facilitating rapid cell proliferation. However, at later ages accumulation of unrepaired damage and mutations, as well as ongoing cell depletion, promotes cancer, atrophy, and other deleterious effects associated with aging. As such, genome maintenance and its phenotypic sequelae provide yet another example of antagonistic pleiotropy in aging and longevity. [ABSTRACT FROM AUTHOR]

Published

2014

12. Myc-Dependent Genome Instability and Lifespan in Drosophila.

Author

Greer, Christina, Lee, Moonsook, Westerhof, Maaike, Milholland, Brandon, Spokony, Rebecca, Vijg, Jan, and Secombe, Julie

Subjects

GENOMES, DROSOPHILA, GENETIC mutation, GENE expression, DATA analysis, CELL proliferation

Abstract

The Myc family of transcription factors are key regulators of cell growth and proliferation that are dysregulated in a large number of human cancers. When overexpressed, Myc family proteins also cause genomic instability, a hallmark of both transformed and aging cells. Using an in vivo lacZ mutation reporter, we show that overexpression of Myc in Drosophila increases the frequency of large genome rearrangements associated with erroneous repair of DNA double-strand breaks (DSBs). In addition, we find that overexpression of Myc shortens adult lifespan and, conversely, that Myc haploinsufficiency reduces mutation load and extends lifespan. Our data provide the first evidence that Myc may act as a pro-aging factor, possibly through its ability to greatly increase genome instability. [ABSTRACT FROM AUTHOR]

Published

2013

13. Deletion of p66 Shc in mice increases the frequency of size-change mutations in the lac Z transgene.

Author

Beltrami, Elena, Ruggiero, Antonella, Busuttil, Rita, Migliaccio, Enrica, Pelicci, Pier Giuseppe, Vijg, Jan, and Giorgio, Marco

Subjects

LABORATORY mice, GENETIC mutation, TRANSGENES, OXIDATIVE stress, DNA damage, REACTIVE oxygen species, APOPTOSIS

Abstract

Upon oxidative challenge the genome accumulates adducts and breaks that activate the DNA damage response to repair, arrest, or eliminate the damaged cell. Thus, reactive oxygen species ( ROS) generated by endogenous oxygen metabolism are thought to affect mutation frequency. However, few studies determined the mutation frequency when oxidative stress is reduced. To test whether in vivo spontaneous mutation frequency is altered in mice with reduced oxidative stress and cell death rate, we crossed p66Shc knockout (p66 KO) mice, characterized by reduced intracellular concentration of ROS and by impaired apoptosis, with a transgenic line harboring multiple copies of the lac Z mutation reporter gene as part of a plasmid that can be recovered from organs into Escherichia coli to measure mutation rate. Liver and small intestine from 2- to 24-month-old, lac Z (p66Shc+/+) and lac Zp66 KO mice, were investigated revealing no difference in overall mutation frequency but a significant increase in the frequency of size-change mutations in the intestine of lac Zp66 KO mice. This difference was further increased upon irradiation of mice with X-ray. In addition, we found that knocking down cyclophilin D, a gene that facilitates mitochondrial apoptosis acting downstream of p66 Shc, increased the size-change mutation frequency in small intestine. Size-change mutations also accumulated in death-resistant embryonic fibroblasts from lac Zp66 KO mice treated with H2 O2. These results indicate that p66 Shc plays a role in the accumulation of DNA rearrangements and suggest that p66 Shc functions to clear damaged cells rather than affect DNA metabolism. [ABSTRACT FROM AUTHOR]

Published

2013

14. Direct mutation analysis by high-throughput sequencing: From germline to low-abundant, somatic variants

Author

Gundry, Michael and Vijg, Jan

Subjects

*GENETIC mutation, *MOSAICISM, *BIOLOGICAL variation, *GERM cells, *GENOMES, *SOMATIC cells, *HETEROGENEITY, *NUCLEOTIDE sequence

Abstract

Abstract: DNA mutations are the source of genetic variation within populations. The majority of mutations with observable effects are deleterious. In humans mutations in the germ line can cause genetic disease. In somatic cells multiple rounds of mutations and selection lead to cancer. The study of genetic variation has progressed rapidly since the completion of the draft sequence of the human genome. Recent advances in sequencing technology, most importantly the introduction of massively parallel sequencing (MPS), have resulted in more than a hundred-fold reduction in the time and cost required for sequencing nucleic acids. These improvements have greatly expanded the use of sequencing as a practical tool for mutation analysis. While in the past the high cost of sequencing limited mutation analysis to selectable markers or small forward mutation targets assumed to be representative for the genome overall, current platforms allow whole genome sequencing for less than $5000. This has already given rise to direct estimates of germline mutation rates in multiple organisms including humans by comparing whole genome sequences between parents and offspring. Here we present a brief history of the field of mutation research, with a focus on classical tools for the measurement of mutation rates. We then review MPS, how it is currently applied and the new insight into human and animal mutation frequencies and spectra that has been obtained from whole genome sequencing. While great progress has been made, we note that the single most important limitation of current MPS approaches for mutation analysis is the inability to address low-abundance mutations that turn somatic tissues into mosaics of cells. Such mutations are at the basis of intra-tumor heterogeneity, with important implications for clinical diagnosis, and could also contribute to somatic diseases other than cancer, including aging. Some possible approaches to gain access to low-abundance mutations are discussed, with a brief overview of new sequencing platforms that are currently waiting in the wings to advance this exploding field even further. [Copyright &y& Elsevier]

Published

2012

15. Age- and Temperature-Dependent Somatic Mutation Accumulation in Drosophila melanogaster.

Author

Garcia, Ana Maria, Calder, R. Brent, Dollé, Martijn E. T., Lundell, Martha, Kapahi, Pankaj, and Vijg, Jan

Subjects

TRANSGENIC mice, DROSOPHILA melanogaster, GENETIC mutation, GENETICS, CHROMOSOME abnormalities

Abstract

Using a transgenic mouse model harboring a mutation reporter gene that can be efficiently recovered from genomic DNA, we previously demonstrated that mutations accumulate in aging mice in a tissue-specific manner. Applying a recently developed, similar reporter-based assay in Drosophila melanogaster, we now show that the mutation frequency at the lacZ locus in somatic tissue of flies is about three times as high as in mouse tissues, with a much higher fraction of large genome rearrangements. Similar to mice, somatic mutations in the fly also accumulate as a function of age, but they do so much more quickly at higher temperature, a condition which in invertebrates is associated with decreased life span. Most mutations were found to accumulate in the thorax and less in abdomen, suggesting the highly oxidative flight muscles as a possible source of genotoxic stress. These results show that somatic mutation loads in short-lived flies are much more severe than in the much longer-lived mice, with the mutation rate in flies proportional to biological rather than chronological aging. [ABSTRACT FROM AUTHOR]

Published

2010

16. Genome instability, cancer and aging

Author

Maslov, Alexander Y. and Vijg, Jan

Subjects

*GENETICS of aging, *CANCER genetics, *DNA damage, *BIOLOGICAL evolution, *GENETICS, *CELL cycle regulation, *CELL death, *DNA repair, *GENETIC mutation, *CHROMATIN

Abstract

Abstract: DNA damage-driven genome instability underlies the diversity of life forms generated by the evolutionary process but is detrimental to the somatic cells of individual organisms. The cellular response to DNA damage can be roughly divided in two parts. First, when damage is severe, programmed cell death may occur or, alternatively, temporary or permanent cell cycle arrest. This protects against cancer but can have negative effects on the long term, e.g., by depleting stem cell reservoirs. Second, damage can be repaired through one or more of the many sophisticated genome maintenance pathways. However, erroneous DNA repair and incomplete restoration of chromatin after damage is resolved, produce mutations and epimutations, respectively, both of which have been shown to accumulate with age. An increased burden of mutations and/or epimutations in aged tissues increases cancer risk and adversely affects gene transcriptional regulation, leading to progressive decline in organ function. Cellular degeneration and uncontrolled cell proliferation are both major hallmarks of aging. Despite the fact that one seems to exclude the other, they both may be driven by a common mechanism. Here, we review age-related changes in the mammalian genome and their possible functional consequences, with special emphasis on genome instability in stem/progenitor cells. [Copyright &y& Elsevier]

Published

2009

17. Mitochondrial DNA mutations and aging: devils in the details?

Author

Khrapko, Konstantin and Vijg, Jan

Subjects

*MITOCHONDRIAL DNA, *GENETIC mutation, *AGING, *BIOACCUMULATION, *ETIOLOGY of diseases, *ANIMAL disease models, *LABORATORY mice

Abstract

Although several lines of evidence support a role for accumulating somatic mitochondrial DNA (mtDNA) mutations in the etiology of aging, it remains unclear if they are a major cause of age-related deterioration and death. Mouse models that harbor elevated mtDNA mutation frequencies age prematurely; these findings were thought to provide conclusive evidence for a causal role of such mutations in aging. Yet, the presence of several conflicting reports has sparked controversy in the field and this is further aggravated by discrepancies in the estimates of mtDNA mutant fractions, which disagree by orders of magnitude. Here, we briefly review the evidence and some of the unresolved questions surrounding a causative role for accumulating mtDNA mutations in aging. [Copyright &y& Elsevier]

Published

2009

18. Effect of Ku80 Deficiency on Mutation Frequencies and Spectra at a LacZ Reporter Locus in Mouse Tissues and Cells.

Author

Busuttil, Rita A., Muñoz, Denise P., Garcia, Ana Maria, Rodier, Francis, Woo Ho Kim, Yousin Suh, Hasty, Paul, Campisi, Judith, and Vijg, Jan

Subjects

GRAFT versus host disease, GENETIC mutation, GENE mapping, TISSUE analysis, GENOMES, EMBRYONIC stem cells, IMMUNOSUPPRESSIVE agents, LABORATORY mice, FIBROBLAST growth factors

Abstract

Non-homologous end joining (NHEJ) is thought to be an important mechanism for preventing the adverse effects of DNA double strand breaks (DSBs) and its absence has been associated with premature aging. To investigate the effect of inactivated NHEJ on spontaneous mutation frequencies and spectra in vivo and in cultured cells, we crossed a Ku80-deficient mouse with mice harboring a lacZ-plasmid-based mutation reporter. We analyzed various organs and tissues, as well as cultured embryonic fibroblasts, for mutations at the lacZ locus. When comparing mutant with wild-type mice, we observed a significantly higher number of genome rearrangements in liver and spleen and a significantly lower number of point mutations in liver and brain. The reduced point mutation frequency was not due to a decrease in small deletion mutations thought to be a hallmark of NHEJ, but could be a consequence of increased cellular responses to unrepaired DSBs. Indeed, we found a substantial increase in persistent 53BP1 and cH2AX DNA damage foci in Ku80-/- as compared to wild-type liver. Treatment of cultured Ku80-deficient or wild-type embryonic fibroblasts, either proliferating or quiescent, with hydrogen peroxide or bleomycin showed no differences in the number or type of induced genome rearrangements. However, after such treatment, Ku80-deficient cells did show an increased number of persistent DNA damage foci. These results indicate that Ku80-dependent repair of DNA damage is predominantly error-free with the effect of alternative more error-prone pathways creating genome rearrangements only detectable after extended periods of time, i.e., in young adult animals. The observed premature aging likely results from a combination of increased cellular senescence and an increased load of stable, genome rearrangements. [ABSTRACT FROM AUTHOR]

Published

2008

19. Aging and Genome Maintenance.

Author

VIJG, JAN, BUSUTTIL, RITA A., BAHAR, RUMANA, and DOLLÉ, MARTIJN E.T.

Subjects

GENOMICS, AGING, TRANSGENIC mice, GENETIC mutation, GENE expression

Abstract

Genomic instability in somatic cells has been implicated as a major stochastic mechanism of aging. Using a transgenic mouse model with chromosomally integrated lac-Z mutational target genes, we found mutations to accumulate with age at an organ- and tissue-specific rate. Also the spectrum of age-accumulated mutations was found to differ greatly from organ to organ; while initially similar, mutation spectra of different tissues diverged significantly over the lifetime. To explain how genomic instability, which is inherently stochastic, can be a causal factor in aging, it is proposed that randomly induced mutations may adversely affect normal patterns of gene regulation, resulting in a mosaic of cells at various stages on a trajectory of degeneration, eventually resulting in cell death or neoplastic transformation. To directly address this question we demonstrate that it is now possible to analyze single cells, isolated from old and young tissues, for specific alterations in gene expression. [ABSTRACT FROM AUTHOR]

Published

2005

20. Accelerating aging by mouse reverse genetics: a rational approach to understanding longevity.

Author

Hasty, Paul and Vijg, Jan

Subjects

*ANIMAL models for aging, *ACCELERATED life testing, *GENOMES, *PHENOTYPES, *GENETIC mutation, *LIFE spans

Abstract

Investigating the molecular basis of aging has been difficult, primarily owing to the pleiotropic and segmental nature of the aging phenotype. There are many often interacting symptoms of aging, some of which are obvious and appear to be common to every aged individual, whereas others affect only a subset of the elderly population. Although at first sight this would suggest multiple molecular mechanisms of aging, there now appears to be almost universal consensus that aging is ultimately the result of the accumulation of somatic damage in cellular macromolecules, with reactive oxygen species likely to be the main damage-inducing agent. What remains significant is unravelling how such damage can give rise to the large variety of aging symptoms and how these can be controlled. Although humans, with over a century of clinical observations, remain the obvious target of study, the mouse, with a relatively short lifespan, easy genetic accessibility and close relatedness to humans, is the tool par excellence to model aging-related phenotypes and test strategies of intervention. Here we present the argument that mouse models with engineered defects in genome maintenance systems are especially important because they often exhibit a premature appearance of aging symptoms. Confirming studies on human segmental progeroid syndromes, most of which are based on heritable mutations in genes involved in genome maintenance, the results thus far obtained with mouse models strongly suggest that lifespan and onset of aging are directly related to the quality of DNA metabolism. This may be in keeping with the recent discovery of a possible ‘universal survival’ pathway that improves antioxidant defence and genome maintenance and simultaneously extends lifespan in the mouse and several invertebrate species. [ABSTRACT FROM AUTHOR]

Published

2004

21. Interpreting epidemiological research: blinded comparison of methods used to estimate the prevalence of inherited mutations in BRCA1.

Author

Eng, Charis, Brody, Lawrence C., Wagner, Teresa M. U., Devilee, Peter, Vijg, Jan, Szabo, Csilla, Tavtigian, Sean V., Nathanson, Katharine L., Ostrander, Elaine, and Frank, Thomas S.

Subjects

GENETIC mutation, EPIDEMIOLOGICAL research, GENES, CONFORMATIONAL analysis, GENETIC polymorphisms, GEL electrophoresis

Abstract

While sequence analysis is considered by many to be the most sensitive method of detecting unknown mutations in large genes such as BRCA1, most published estimates of the prevalence of mutations in this gene have been derived from studies that have used other methods of gene analysis. In order to determine the relative sensitivity of techniques that are widely used in research on BRCA1, a set of blinded samples containing 58 distinct mutations were analysed by four separate laboratories. Each used one of the following methods: single strand conformational polymorphism analysis (SSCP), conformation sensitive gel electrophoresis (CSGE), two dimensional gene scanning (TDGS), and denaturing high performance liquid chromatography (DHPLC). Only the laboratory using DHPLC correctly identified each of the mutations. The laboratory using TDGS correctly identified 91% of the mutations but produced three apparent false positive results. The laboratories using SSCP and CSGE detected abnormal migration for 72% and 76% of the mutations, respectively, but subsequently confirmed and reported only 65% and 60% of mutations, respectively. False negatives therefore resulted not only from failure of the techniques to distinguish wild type from mutant, but also from failure to confirm the mutation by sequence analysis as well as from human errors leading to misreporting of results. These findings characterise sources of error in commonly used methods of mutation detection that should be addressed by laboratories using these methods. Based upon sources of error identified in this comparison, it is likely that mutations in BRCA1 and BRCA2 are more prevalent than some studies have previously reported. The findings of this comparison provide a basis for interpreting studies of mutations in susceptibility genes across many inherited cancer syndromes. [ABSTRACT FROM AUTHOR]

Published

2001

22. From DNA damage to mutations: All roads lead to aging.

Author

Vijg, Jan

Subjects

*SOMATIC mutation, *DNA damage, *GENETIC mutation, *CANCER treatment, *GENE regulatory networks, *CELLULAR aging, *NATURAL selection

Abstract

Mutations accumulate in the somatic cells organs and tissues during the aging process. Some mutations clonally expand (orange cells), with cancer as an example. [Display omitted] • There is abundant evidence for DNA damage as a cause of aging. • DNA damage can cause aging by affecting transcription, signaling apoptosis or cellular senescence or through somatic mutations. • Somatic mutations can now be quantitated at the single-cell level and have been found to accumulate with age in multiple human tissues. • Somatic mutations can cause cell functional loss and age-related disease by clonal expansion or through interference in gene regulatory networks. • Somatic mutations may lead to age-related loss of function through transcriptional noise. Damage to the repository of genetic information in cells has plagued life since its very beginning 3–4 billion years ago. Initially, in the absence of an ozone layer, especially damage from solar UV radiation must have been frequent, with other sources, most notably endogenous sources related to cell metabolism, gaining in importance over time. To cope with this high frequency of damage to the increasingly long DNA molecules that came to encode the growing complexity of cellular functions in cells, DNA repair evolved as one of the earliest genetic traits. Then as now, errors during the repair of DNA damage generated mutations, which provide the substrate for evolution by natural selection. With the emergence of multicellular organisms also the soma became a target of DNA damage and mutations. In somatic cells selection against the adverse effects of DNA damage is greatly diminished, especially in postmitotic cells after the age of first reproduction. Based on an abundance of evidence, DNA damage is now considered as the single most important driver of the degenerative processes that collectively cause aging. Here I will first briefly review the evidence for DNA damage as a cause of aging since the beginning of life. Then, after discussing the possible direct adverse effects of DNA damage and its cellular responses, I will provide an overview of the considerable progress that has recently been made in analyzing a major consequence of DNA damage in humans and other complex organisms: somatic mutations and the resulting genome mosaicism. Recent advances in studying somatic mutagenesis and genome mosaicism in different human and animal tissues will be discussed with a focus on the possible mechanisms through which loss of DNA sequence integrity could cause age-related functional decline and disease. [ABSTRACT FROM AUTHOR]

Published

2021

23. Characterization of color mutants in lacZ plasmid-based transgenic mice, as detected by positive selection.

Author

DolléHans-Jörg^Martus, Martijn E. T., Novak, Maja, van Orsouw, Nathalie J., and Vijg, Jan

Subjects

GENOTYPE-environment interaction, OIL pollution of water, ANIMAL models in research, GENETIC mutation, WATER pollution, CHROMOSOME abnormalities, GENETICS

Abstract

The plasmid-based transgenic mouse model, which uses the lacZ gene as the target for mutation, is sensitive to a wide range of in vivo mutations, ranging from point mutations to insertions and deletions extending far into the mouse genome. In this study, the nature of subtle lacZ mutations, which do not completely abolish β-galactosidase activity, as detected by positive selection, was investigated. These subtle mutants are called `color mutants' due to their light blue staining on X-gal medium. Replating of color mutants and retransformation of plasmid DNA, purified from individual color mutants, resulted in the same phenotype as the original color mutant. The p-gal positive selection system tolerates ~10% of wild-type activity as indicated by spectrophotometric determination of β-galactosidase activity of individual color mutants. Restriction digestion and size separation of plasmid DNA revealed no visible change in the size of the plasmid in color mutants. Sequence analysis confirmed the presence of a point mutation in each lacZ gene of nine different color mutants. The results indicate that color mutants are caused neither by the presence of a mixture of wild-type and mutated lacZ plasmids within the same host cell nor by a mixture of cells within the original mutant colony which carry either wild-type or mutated lacZ plasmids. In addition, it was discovered that the mouse line studied harbors four polymorphic base changes among the integrated plasmid copies. [ABSTRACT FROM PUBLISHER]

Published

1999

24. Genome instability: A conserved mechanism of aging?

Author

Vijg, Jan

Subjects

*DEGENERATION (Pathology), *AGE factors in disease, *GENETICS of aging, *HERITABILITY, *GENETIC mutation

Published

2017

25. Mitochondrial DNA mutations and aging: a case closed?

Author

Khrapko, Konstantin and Vijg, Jan

Subjects

*MITOCHONDRIAL DNA abnormalities, *GENETIC mutation, *AGING, *LABORATORY mice, *MUTAGENESIS

Abstract

Recent reports of premature aging in mutant mice with greatly increased rates of mitochondrial DNA mutagenesis (so-called 'mitochondrial mutator mice') appeared to confirm that accumulation of mtDNA mutations is a key mechanism of normal aging. Now, in a dramatic turnaround, a new study reports that levels of point mutations in tissues of aged normal mice are much lower than in the mutator mice, apparently ruling out a causal role in normal aging. [ABSTRACT FROM AUTHOR]

Published

2007

26. Editorial.

Author

Vijg, Jan

Subjects

*GENETIC mutation, *PRIMROSES, *CELLULAR signal transduction, *GENETIC regulation, *MENDEL'S law, *MUTAGENESIS

Published

2015

27. Mutation and catastrophe in the aging genome.

Author

Milholland, Brandon, Suh, Yousin, and Vijg, Jan

Subjects

*GENETICS of aging, *GENETIC mutation, *GENETIC translation, *PROTEIN synthesis, *SOMATIC cells, *BIOACCUMULATION

Abstract

In the 1960s, Leslie Orgel proposed what is now known as the error catastrophe theory of aging, arguing that errors in protein translation that reduce the fidelity of the protein-translating enzymes would lead to a feedback loop of increasingly inaccurate protein synthesis, terminating in the death of the organism. This mechanism of aging would be consistent with the exponential increase of mortality observed in humans, but the error catastrophe theory of aging has been generally disregarded by researchers due to a lack of evidence for an age-related increase in protein errors. Another theory of aging, proposed at roughly the same time, is Leo Szilard's two-hit model of somatic mutation accumulation, which assumed a linear increase in mutations over time but explained the nonlinear pattern of human mortality through a mechanism of genetic and cellular redundancy which kept mortality low until the redundancy was exhausted, at which point mortality rapidly rose. Here, we synthesize the two theories, along with the latest advances in genomics research. We propose a new catastrophe theory of aging, this time with somatic mutations as the primary agent of the feedback loop. Similar to protein errors affecting translation itself, somatic mutations in genes involved in DNA replication and repair would lead to a feedback loop of exponentially increasing mutation load. The difference from protein errors is that somatic mutations would mainly affect gene regulatory regions rather than the much smaller part of the genome encoding protein-coding information. Although the self-stimulating accumulation of somatic mutations is not mutually exclusive with the Szilard-based loss of redundancy, we present evidence that suggests that the accumulated mutations themselves could be numerous enough to cause mortality. Finally, we acknowledge the limits of our current knowledge and propose a course of research practices that will help to confirm or refute our model and advance the field of aging research as a whole. [ABSTRACT FROM AUTHOR]

Published

2017

28. Single-cell analysis of somatic mutation burden in mammary epithelial cells of pathogenic BRCA1/2 mutation carriers.

Author

Shixiang Sun, Brazhnik, Kristina, Moonsook Lee, Maslov, Alexander Y., Yi Zhang, Zhenqiu Huang, Klugman, Susan, Park, Ben H., Vijg, Jan, Montagna, Cristina, Sun, Shixiang, Lee, Moonsook, Zhang, Yi, and Huang, Zhenqiu

Subjects

*SOMATIC mutation, *OVARIAN cancer, *EPITHELIAL cells, *BRCA genes, *GENETIC mutation, *NUCLEOTIDE sequencing, *PROTEINS, *RESEARCH, *OVARIAN tumors, *RESEARCH methodology, *EVALUATION research, *COMPARATIVE studies, *DISEASE susceptibility, *CYTOLOGY, *BREAST tumors

Abstract

Inherited germline mutations in the breast cancer gene 1 (BRCA1) or BRCA2 genes (herein BRCA1/2) greatly increase the risk of breast and ovarian cancer, presumably by elevating somatic mutational errors as a consequence of deficient DNA repair. However, this has never been directly demonstrated by a comprehensive analysis of the somatic mutational landscape of primary, noncancer, mammary epithelial cells of women diagnosed with pathogenic BRCA1/2 germline mutations. Here, we used an accurate, single-cell whole-genome sequencing approach to first show that telomerized primary mammary epithelial cells heterozygous for a highly penetrant BRCA1 variant displayed a robustly elevated mutation frequency as compared with their isogenic control cells. We then demonstrated a small but statistically significant increase in mutation frequency in mammary epithelial cells isolated from the breast of BRCA1/2 mutation carriers as compared with those obtained from age-matched controls with no genetically increased risk for breast cancer. [ABSTRACT FROM AUTHOR]

Published

2022

29. High-throughput sequencing in mutation detection: A new generation of genotoxicity tests?

Author

Maslov, Alexander Y., Quispe-Tintaya, Wilber, Gorbacheva, Tatyana, White, Ryan R., and Vijg, Jan

Subjects

*GENETIC mutation, *GENETIC toxicology, *CELL culture, *BIOMARKERS

Abstract

The advent of next generation sequencing (NGS) technology has provided the means to directly analyze the genetic material in primary cells or tissues of any species in a high throughput manner for mutagenic effects of potential genotoxic agents. In principle, direct, genome-wide sequencing of human primary cells and/or tissue biopsies would open up opportunities to identify individuals possibly exposed to mutagenic agents, thereby replacing current risk assessment procedures based on surrogate markers and extrapolations from animal studies. NGS-based tests can also precisely characterize the mutation spectra induced by genotoxic agents, improving our knowledge of their mechanism of action. Thus far, NGS has not been widely employed in genetic toxicology due to the difficulties in measuring low-abundant somatic mutations. Here, we review different strategies to employ NGS for the detection of somatic mutations in a cost-effective manner and discuss the potential applicability of these methods in testing the mutagenicity of genotoxic agents. [ABSTRACT FROM AUTHOR]

Published

2015

30. Single-cell transcriptogenomics reveals transcriptional exclusion of ENU-mutated alleles.

Author

Li, Wenge, Calder, R. Brent, Mar, Jessica C., and Vijg, Jan

Subjects

*GENETIC mutation, *ALLELES, *RNA sequencing, *PHENOTYPES, *ETHYLNITROSOUREA, *GERM cells, *GENETIC transcription

Abstract

Recently, great progress has been made in single cell genomics and transcriptomics. Here, we present an integrative method, termed single-cell transcriptogenomics (SCTG), in which whole exome sequencing and RNA-seq is performed concurrently on single cells. This methodology enables one to track germline and somatic variants directly from the genome to the transcriptome in individual cells. Mouse embryonic fibroblasts were treated with the powerful mutagen ethylnitrosourea (ENU) and subjected to SCTG. Interestingly, while germline variants were found to be transcribed in an allelically balanced fashion, a significantly different pattern of allelic exclusion was observed for ENU-mutant variants. These results suggest that the adverse effects of induced mutations, in contrast to germline variants, may be mitigated by allelically biased transcription. They also illustrate how SCTG can be instrumental in the direct assessment of phenotypic consequences of genomic variants. [ABSTRACT FROM AUTHOR]

Published

2015

31. Myc-Dependent Genome Instability and Lifespan in Drosophila.

Author

Greer, Christina, Lee, Moonsook, Westerhof, Maaike, Milholland, Brandon, Spokony, Rebecca, Vijg, Jan, and Secombe, Julie

Subjects

*GENOMES, *DROSOPHILA, *GENETIC mutation, *GENE expression, *DATA analysis, *CELL proliferation

Abstract

The Myc family of transcription factors are key regulators of cell growth and proliferation that are dysregulated in a large number of human cancers. When overexpressed, Myc family proteins also cause genomic instability, a hallmark of both transformed and aging cells. Using an in vivo lacZ mutation reporter, we show that overexpression of Myc in Drosophila increases the frequency of large genome rearrangements associated with erroneous repair of DNA double-strand breaks (DSBs). In addition, we find that overexpression of Myc shortens adult lifespan and, conversely, that Myc haploinsufficiency reduces mutation load and extends lifespan. Our data provide the first evidence that Myc may act as a pro-aging factor, possibly through its ability to greatly increase genome instability. [ABSTRACT FROM AUTHOR]

Published

2013

32. Genetic analysis reveals an intrinsic property of the germinal center B cells to generate A:T mutations

Author

Ouchida, Rika, Ukai, Akiko, Mori, Hiromi, Kawamura, Kiyoko, Dollé, Martijn E.T., Tagawa, Masatoshi, Sakamoto, Akemi, Tokuhisa, Takeshi, Yokosuka, Tadashi, Saito, Takashi, Yokoi, Masayuki, Hanaoka, Fumio, Vijg, Jan, and Wang, Ji-Yang

Subjects

*IMMUNOGLOBULINS, *GENES, *B cells, *GENETIC mutation, *DNA damage, *DNA polymerases

Abstract

Abstract: The immunoglobulin genes undergo a high frequency of point mutations at both C:G and A:T pairs in the germinal center (GC) B cells. This hypermutation process is initiated by the activation-induced cytidine deaminase (AID), which converts cytosine to uracil and generates a U:G lesion. Replication of this lesion, or its repair intermediate the abasic site, could introduce C:G mutations but the mechanisms leading to mutations at non-damaged A:T pairs remain elusive. Using a lacZ-transgenic system in which endogenous genome mutations can be detected with high sensitivity, we found that GC B cells exhibited a much higher ratio of A:T mutations as compared to naïve B, non-GC B, and cells of other tissues. This property does not require AID or active transcription of the target gene, and is dependent on DNA polymerase η. These in vivo results demonstrate that GC B cells are unique in having an intrinsic propensity to generate A:T mutations during repair of endogenous DNA damage. These findings have important implications in understanding how AID, which can only target C:G base pairs, is able to induce the entire spectrum of mutations observed in immunoglobulin variable region genes in GC B cells. [Copyright &y& Elsevier]

Published

2008

33. Increased genomic instability is not a prerequisite for shortened lifespan in DNA repair deficient mice

Author

Dollé, Martijn E.T., Busuttil, Rita A., Garcia, Ana Maria, Wijnhoven, Susan, van Drunen, Ellen, Niedernhofer, Laura J., van der Horst, Gijsbertus, Hoeijmakers, Jan H.J., van Steeg, Harry, and Vijg, Jan

Subjects

*DNA, *GENETIC disorders, *NUCLEOTIDE sequence, *GENETIC mutation

Abstract

Abstract: Genetic defects in nucleotide excision repair (NER) are associated with premature aging, including cancer, in both humans and mice. To investigate the possible role of increased somatic mutation accumulation in the accelerated appearance of symptoms of aging as a consequence of NER deficiency, we crossed four different mouse mutants, Xpa −/−, Ercc6(Csb)−/−, Ercc2(Xpd) m/m and Ercc1 −/m , with mice harboring lacZ-reporter genes to assess mutant frequencies and spectra in different organs during aging. The results indicate an accelerated accumulation of mutations in both liver and kidney of Xpa defective mice, which correlated with a trend towards a decreased lifespan. Until 52 weeks, Xpa deficiency resulted mainly in 1-bp deletions. At old age (104 weeks), the spectrum had undergone a shift, in both organs, to G:C→T:A transversions, a signature mutation of oxidative DNA damage. Ercc1 −/m mice, with their short lifespan of 6 months and severe symptoms of premature aging, especially in liver and kidney, displayed an even faster lacZ-mutant accumulation in liver. In this case, the excess mutations were mostly genome rearrangements. Csb −/− mice, with mild premature aging features and no reduction in lifespan, and Xpd m/m mice, exhibiting prominent premature aging features and about 20% reduction in lifespan, did not have elevated lacZ-mutant frequencies. It is concluded that while increased genomic instability could play a causal role in the mildly accelerated aging phenotype in the Xpa-null mice or in the severe progeroid symptoms of the Ercc1-mutant mice, shortened lifespan in mice with defects in transcription-related repair do not depend upon increased mutation accumulation. [Copyright &y& Elsevier]

Published

2006

34. Accelerated aging pathology in ad libitum fed Xpd TTD mice is accompanied by features suggestive of caloric restriction

Author

Wijnhoven, Susan W.P., Beems, Rudolf B., Roodbergen, Marianne, van den Berg, Jolanda, Lohman, Paul H.M., Diderich, Karin, van der Horst, Gijsbertus T.J., Vijg, Jan, Hoeijmakers, Jan H.J., and van Steeg, Harry

Subjects

*GENETIC mutation, *DNA repair, *PATHOLOGY, *LOW-calorie diet, *CELL death

Abstract

Abstract: Trichothiodystrophy (TTD) patients with a mutation in the XPD gene of nucleotide excision repair (NER) have a short life span and show various features of premature aging, thereby linking DNA damage to the aging process. Xpd TTD mutant mice share many features with TTD patients, including a shorter life span, accompanied by a segmental progeroid phenotype. Here we report new pathology features supportive to the premature aging phenotype of Xpd TTD mice. Strikingly, accelerated aging pathology is accompanied by signs suggestive of caloric restriction (CR), a condition usually linked to retardation of age-related pathology and life extension. Accelerated aging symptoms in Xpd TTD mice are most likely due to accumulation of endogenously generated DNA damage and compromised transcription leading to cell death, whereas CR symptoms may reflect the need of Xpd TTD mice to reduce metabolism (ROS production) in an attempt to extend their life span. Our current findings in Xpd TTD mice further strengthen the link between DNA damage, repair and aging. [Copyright &y& Elsevier]

Published

2005