Differentiated embryo chondrocyte plays a crucial role in DNA damage response via transcriptional regulation under hypoxic conditions (original) (raw)
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Regulation of DNA repair in hypoxic cancer cells
Cancer and Metastasis Reviews, 2007
Emerging evidence indicates that the tumor microenvironmental stress of hypoxia can induce genetic instability in cancer cells. We and others have found that the expression levels of key genes within the DNA mismatch repair (MMR) and homologous recombination (HR) pathways are coordinately repressed by hypoxia. These decreases are associated with functional impairments in both MMR and HR repair under hypoxic conditions, and thus they represent a possible mechanistic explanation for the observed phenomenon of hypoxia-induced genetic instability. In parallel, studies also indicate that several DNA damage response factors are activated in response to hypoxia and subsequent reoxygenation, including ATM/ATR, Chkl/Chk2 and BRCA1. Taken together, these findings reveal that hypoxia induces a unique cellular stress response involving an initial, acute DNA damage response to hypoxia and reoxygenation, followed by a chronic response to prolonged hypoxia in which selected DNA repair pathways are coordinately suppressed. In this review, we discuss these pathways and the possible mechanisms involved, as well as the consequences for genetic instability and tumor progression within the tumor microenvironment.
Annals of the New York Academy of Sciences, 2005
Hypoxia is a common feature of solid tumors and is associated with genetic instability and tumor progression. It has been shown previously that alterations in the expression of DNA repair genes in response to hypoxic stress may account for a proportion of such genetic instability. Here, we demonstrate that the expression of RAD51, a critical mediator of homologous recombination (HR), is repressed by hypoxia in numerous cell lines derived from a wide range of tissues. Repression of this gene by hypoxia occurs in a cell cycle-and hypoxiainducible factor (HIF)-independent manner, and decreased RAD51 expression was observed to persist during the post-hypoxic period. In addition, decreases in Rad51 expression were correlated with functional impairments in HR repair in hypoxic and post-hypoxic cells. Based on these data, we propose a novel mechanism of hypoxia-induced genetic instability via suppression of the HR pathway in cancer cells within the tumor microenvironment.
Regulation of the cell fate by DNA damage and hypoxia
World Journal of Medical Genetics, 2013
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Chronic hypoxia compromises repair of DNA double-strand breaks to drive genetic instability
Journal of Cell Science, 2012
Hypoxic cells have been linked to genetic instability and tumor progression. However, little is known about the exact relationship between DNA repair and genetic instability in hypoxic cells. We therefore tested whether the sensing and repair of DNA double-strand breaks (DNA-dsbs) is altered in irradiated cells kept under continual oxic, hypoxic or anoxic conditions. Synchronized G0-G1 human fibroblasts were irradiated (0-10 Gy) after initial gassing with 0% O 2 (anoxia), 0.2% O 2 (hypoxia) or 21% O 2 (oxia) for 16 hours. The response of phosphorylated histone H2AX (c-H2AX), phosphorylated ataxia telangiectasia mutated [ATM(Ser1981)], and the p53 binding protein 1 (53BP1) was quantified by intranuclear DNA repair foci and western blotting. At 24 hours following DNA damage, residual c-H2AX, ATM(Ser1981) and 53BP1 foci were observed in hypoxic cells. This increase in residual DNA-dsbs under hypoxic conditions was confirmed using neutral comet assays. Clonogenic survival was also reduced in chronically hypoxic cells, which is consistent with the observation of elevated G1-associated residual DNA-dsbs. We also observed an increase in the frequency of chromosomal aberrations in chronically hypoxic cells. We conclude that DNA repair under continued hypoxia leads to decreased repair of G1-associated DNA-dsbs, resulting in increased chromosomal instability. Our findings suggest that aberrant DNA-dsb repair under hypoxia is a potential factor in hypoxia-mediated genetic instability.
Multifaceted control of DNA repair pathways by the hypoxic tumor microenvironment
DNA Repair, 2015
Hypoxia, as a pervasive feature in the microenvironment of solid tumors, plays a significant role in cancer progression, metastasis, and ultimately clinical outcome. One key cellular consequence of hypoxic stress is the regulation of DNA repair pathways, which contributes to the genomic instability and mutator phenotype observed in human cancers. Tumor hypoxia can vary in severity and duration, ranging from acute fluctuating hypoxia arising from temporary blockages in the immature microvasculature, to chronic moderate hypoxia due to sparse vasculature, to complete anoxia at distances more than 150 μM from the nearest blood vessel. Paralleling the intra-tumor heterogeneity of hypoxia, the effects of hypoxia on DNA repair occur through diverse mechanisms. Acutely, hypoxia activates DNA damage signaling pathways, primarily via posttranslational modifications. On a longer timescale, hypoxia leads to transcriptional and/or translational downregulation of most DNA repair pathways including DNA double-strand break repair, mismatch repair, and nucleotide excision repair. Furthermore, extended hypoxia can lead to long-term persistent silencing of certain DNA repair genes, including BRCA1 and MLH1, revealing a mechanism by which tumor suppressor genes can be inactivated. The discoveries of the hypoxic modulation of DNA repair pathways have highlighted many potential ways to target susceptibilities of hypoxic cancer cells. In this review, we will discuss the multifaceted hypoxic control of DNA repair at the transcriptional, post-transcriptional, and epigenetic levels, and we will offer perspective on the future of its clinical implications.
Controlled DNA "damage" and repair in hypoxic signaling
2010
Hypoxia, a fundamental stimulus in biology and medicine, uses reactive oxygen species (ROS) as second messengers. A surprising target of hypoxia-generated ROS is specific bases within hypoxic response elements (HREs) of the VEGF and other hypoxia-inducible genes. Oxidative modifications coincide with the onset of mRNA accumulation and are localized to transcriptionally active mono-nucleosomes. The oxidative base modifications are removed by the base excision DNA repair pathway for which one of its components, the bifunctional transcriptional co-activator and DNA endonuclease Ref-1/Ape1, is critical for transcription complex assembly. Mimicking the effect of hypoxia by introducing an abasic site in an oligonucleotide model of the VEGF HRE, altered transcription factor binding, enhanced sequence flexibility, and engendered more robust reporter gene expression. These observations suggest that controlled DNA "damage" and repair, mediated by ROS used as second messengers and critically involving the base excision pathway of DNA repair, respectively, are important for hypoxiainduced transcriptional activation.
The Yale journal of biology and medicine, 2013
Hypoxia is a characteristic feature of solid tumors and occurs very early in neoplastic development. Hypoxia transforms cell physiology in multiple ways, with profound changes in cell metabolism, cell growth, susceptibility to apoptosis, induction of angiogenesis, and increased motility. Over the past 20 years, our lab has determined that hypoxia also induces genetic instability. We have conducted a large series of experiments revealing that this instability occurs through the alteration of DNA repair pathways, including nucleotide excision repair, DNA mismatch repair, and homology dependent repair. Our work suggests that hypoxia, as a key component of solid tumors, can drive cancer progression through its impact on genomic integrity. However, the acquired changes in DNA repair that are induced by hypoxia may also render hypoxic cancer cells vulnerable to tailored strategies designed to exploit these changes.
Impact of hypoxia on DNA repair and genome integrity
Mutagenesis, 2019
Hypoxia is a hallmark of the tumour microenvironment with profound effects on tumour biology, influencing cancer progression, the development of metastasis and patient outcome. Hypoxia also contributes to genomic instability and mutation frequency by inhibiting DNA repair pathways. This review summarises the diverse mechanisms by which hypoxia affects DNA repair, including suppression of homology-directed repair, mismatch repair and base excision repair. We also discuss the effects of hypoxia mimetics and agents that induce hypoxia on DNA repair, and we highlight areas of potential clinical relevance as well as future directions.
Tumor hypoxia as a driving force in genetic instability
Genome Integrity, 2013
Sub-regions of hypoxia exist within all tumors and the presence of intratumoral hypoxia has an adverse impact on patient prognosis. Tumor hypoxia can increase metastatic capacity and lead to resistance to chemotherapy and radiotherapy. Hypoxia also leads to altered transcription and translation of a number of DNA damage response and repair genes. This can lead to inhibition of recombination-mediated repair of DNA double-strand breaks. Hypoxia can also increase the rate of mutation. Therefore, tumor cell adaptation to the hypoxic microenvironment can drive genetic instability and malignant progression. In this review, we focus on hypoxia-mediated genetic instability in the context of aberrant DNA damage signaling and DNA repair. Additionally, we discuss potential therapeutic approaches to specifically target repair-deficient hypoxic tumor cells.
Hypoxia-induced genetic instability—a calculated mechanism underlying tumor progression
Journal of Molecular Medicine, 2007
The cause of human cancers is imputed to the genetic alterations at nucleotide and chromosomal levels of ill-fated cells. It has long been recognized that genetic instability-the hallmark of human cancers-is responsible for the cellular changes that confer progressive transformation on cancerous cells. How cancer cells acquire genetic instability, however, is unclear. We propose that tumor development is a result of expansion and progression-two complementary aspects that collaborate with the tumor microenvironment-hypoxia in particular, on genetic alterations through the induction of genetic instability. In this article, we review the recent literature regarding how hypoxia functionally impairs various DNA repair pathways resulting in genetic instability and discuss the biomedical implications in cancer biology and treatment.