Efficiency of Escherichia coli repair processes on uv-damaged transforming plasmid DNA

A comparison has been made of the efficiencies with which the dark repair processes of Escherichia coli act on ultraviolet irradiated bacterial chromosomal DNA and ultraviolet damaged transforming plasmid DNA. It is shown that postreplicational repair pathways act very inefficiently on transforming plasmid DNA, and that the majority of repair is carried out by excision repair pathways. However, even excision repair pathways act less efficiently on damaged plasmid DNA than they do on chromosomal DNA. The large effect of mutations in recB on plasmid survival suggests that the product of this gene may be essential for the excision repair pathways which act on plasmid DNA, but not for those which act on chromosomal DNA.     

DNA repair in organelles: Pathways, organization, regulation, relevance in disease and aging

Both endogenous processes and exogenous physical and chemical sources generate deoxyribonucleic acid (DNA) damage in the nucleus and organelles of living cells. To prevent deleterious effects, damage is balanced by repair pathways. DNA repair was first documented for the nuclear compartment but evidence was subsequently extended to the organelles. Mitochondria and chloroplasts possess their own repair processes. These share a number of factors with the nucleus but also rely on original mechanisms. Base excision repair remains the best characterized. Repair is organized with the other DNA metabolism pathways in the organelle membrane-associated nucleoids. DNA repair in mitochondria is a regulated, stress-responsive process. Organelle genomes do not encode DNA repair enzymes and translocation of nuclear-encoded repair proteins from the cytosol seems to be a major control mechanism. Finally, changes in the fidelity and efficiency of mitochondrial DNA repair are likely to be involved in DNA damage accumulation, disease and aging. The present review successively addresses these different issues.     

Repair-FunMap: a functional database of proteins of the DNA repair systems

Repair-FunMap is a functional database of the DNA repair systems. This database contains not only the proteins directly involved in DNA repair, but also the proteins that interact with the DNA repair proteins. A protein interaction network associated with the human DNA repair processes was established according to the functional relationship between proteins in the database. This network represents the current knowledge on the intrinsic signaling pathways related to DNA repair. The Repair-FunMap could become an essential resource center for cancer research, providing clues to understanding the inter-relationship between proteins in the network, and to building scientific models of the DNA repair processes. AVAILABILITY: http://astro.temple.edu/~feng/Servers/BioinformaticServers.htm     

Inhibition by metals of X-ray and ultraviolet-induced DNA repair in human cells

A number of metals have been shown to be involved in the etiology of animal and human neoplasms. The molecular mechanisms have not yet been determined, but the observed plethora of genetic effects observed following treatment of mammalian cells with metals clearly indicates the possibility that metals can exert their effects at least partially at the level of DNA metabolism. Several studies have suggested that metal treatment may inhibit normal DNA repair processes in procaryotic and eucaryotic cells but a systematic study of this question has not previously been conducted. The present study surveyed the ability of 15 metal salts to interfere with repair of X-ray or UV-induced DNA damage in HeLa cells. Hg⁺⁺, As⁺⁺⁺, Cu⁺⁺, Ni⁺⁺, Co⁺⁺, and Cd⁺⁺ were shown to inhibit the excision of pyrimidine dimers from DNA and to do so in a dose-dependent fashion. Inhibition of repair by only Ni⁺⁺ and Co⁺⁺ resulted in the accumulation of long-lived DNA strand breaks suggestive of a block in the gap-filling stage of repair. Ability to inhibit repair was not correlated with cytotoxicity. X-ray repair was sensitive to Hg⁺⁺, Ni⁺⁺, As⁺⁺⁺, Ga⁺⁺, Zn⁺⁺, and Mo(VI). All inhibitory metals inhibited closure of single strand DNA breaks. Ga⁺⁺ appeared, in addition, to inhibit a later step involving chromatin reconstitution. These findings support the notion that interference of DNA repair processes may be a consequence of exposure of mammalian cells to certain metals. This may be a factor in the etiology of metal-associated carcinogenesis.     

Hyperthermia can differentially modulate the repair of doxorubicin-damaged DNA in normal and cancer cells

Hyperthermia can modulate the action of many anticancer drugs, and DNA repair processes are temperature-dependent, but the character of this dependence in cancer and normal cells is largely unknown. This subject seems to be worth studying, because hyperthermia can assist cancer therapy. A 1-h incubation at 37 degrees C of normal human peripheral blood lymphocytes and human myelogenous leukemia cell line K562 with 0.5 microM doxorubicin gave significant level of DNA damage as assessed by the alkaline comet assay. The cells were then incubated in doxorubicin-free repair medium at 37 degrees C or 41 degrees C. The lymphocytes incubated at 37 degrees C needed about 60 min to remove completely the damage to their DNA, whereas at 41 degrees C the time required for complete repair was shortened to 30 min. There was also a difference between the repair kinetics at 37 degrees C and 41 degrees C in cancer cells. Moreover, the kinetics were different in doxorubicin-sensitive and resistant cells. Therefore, hyperthermia may significantly affect the kinetics of DNA repair in drug-treated cells, but the magnitude of the effect may be different in normal and cancer cells. These features may be exploited in cancer chemotherapy to increase the effectiveness of the treatment and reduce unwanted effects of anticancer drugs in normal cells and fight DNA repair-based drug resistance of cancer cells.     

Replication protein A phosphorylation and the cellular response to DNA damage

Defects in cellular DNA metabolism have a direct role in many human disease processes. Impaired responses to DNA damage and basal DNA repair have been implicated as causal factors in diseases with DNA instability like cancer, Fragile X and Huntington's. Replication protein A (RPA) is essential for multiple processes in DNA metabolism including DNA replication, recombination and DNA repair pathways (including nucleotide excision, base excision and double-strand break repair). RPA is a single-stranded DNA-binding protein composed of subunits of 70-, 32- and 14-kDa. RPA binds ssDNA with high affinity and interacts specifically with multiple proteins. Cellular DNA damage causes the N-terminus of the 32-kDa subunit of human RPA to become hyper-phosphorylated. Current data indicates that hyper-phosphorylation causes a change in RPA conformation that down-regulates activity in DNA replication but does not affect DNA repair processes. This suggests that the role of RPA phosphorylation in the cellular response to DNA damage is to help regulate DNA metabolism and promote DNA repair.     

Combination of the mutation process with the sensitization and repair processes leading to increased frequencies of mutations in algal populations

The possibility of using a combination of the mutation process with the induction of the repair processes has been studied to increase the mutation frequencies in algal populations after UV-treatment. From this study it follows that the repair process induced by visible light is much more effective than the dark repair processes in the chlorococcal algae used. In these algae, visible light perhaps does not induce only those repair processes which affect their DNA, but probably also some recovery ones which affect their damaged structures and physiological functions. A suitable combination of the sensitization of algal cells by a DNA-base analogue before UV-treatment and the induction of the light repair and recovery processes resulted in a rather high increase of viable mutations in chlorococcal algae. These findings may be useful in the breeding of chlorococcal algae, which have no possibility of hybridization (except somatic).     

The dosage of chromatin proteins affects transcriptional silencing and DNA repair in Saccharomyces cerevisiae

Alterations in protein composition or dosage within chromatin may trigger changes in processes such as gene expression and DNA repair. Through transposon mutagenesis and targeted gene deletions in haploids and diploids of Saccharomyces cerevisiae, we identified mutations that affect telomeric silencing in genes encoding telomere-associated Sir4p and Yku80p and chromatin remodeling ATPases Ies2p and Rsc1p. We found that sir4/SIR4 heterozygous diploids efficiently silence the mating type locus HMR but not telomeres, and diploids heterozygous for yku80 and ies2 mutations are inefficient at DNA repair. In contrast, strains heterozygous for most chromatin remodeling ATPase mutations retain wild-type silencing and DNA repair levels. Thus, in diploids, chromatin structures required for DNA repair and telomeric silencing are sensitive to dosage changes.     

The effect of sexual harassment on lethal mutation rate in female Drosophila melanogaster

The rate by which new mutations are introduced into a population may have far-reaching implications for processes at the population level. Theory assumes that all individuals within a population have the same mutation rate, but this assumption may not be true. Compared with individuals in high condition, those in poor condition may have fewer resources available to invest in DNA repair, resulting in elevated mutation rates. Alternatively, environmentally induced stress can result in increased investment in DNA repair at the expense of reproduction. Here, we directly test whether sexual harassment by males, known to reduce female condition, affects female capacity to alleviate DNA damage in Drosophila melanogaster fruitflies. Female gametes can repair double-strand DNA breaks in sperm, which allows manipulating mutation rate independently from female condition. We show that male harassment strongly not only reduces female fecundity, but also reduces the yield of dominant lethal mutations, supporting the hypothesis that stressed organisms invest relatively more in repair mechanisms. We discuss our results in the light of previous research and suggest that social effects such as density and courtship can play an important and underappreciated role in mediating condition-dependent mutation rate.     

Mitochondrial DNA Repair Pathways

It has long been held that there is no DNA repair in mitochondria. Early observations suggestedthat the reason for the observed accumulation of DNA damage in mitochondrial DNA is thatDNA lesions are not removed. This is in contrast to the very efficient repair that is seen inthe nuclear DNA. Mitochondrial DNA does not code for any DNA repair proteins, but it hasbeen observed that a number of repair factors can be found in mitochondrial extracts. Mostof these participate in the base excision DNA repair pathway which is responsible for theremoval of simple lesions in DNA. Recent work has shown that there is efficient base excisionrepair in mammalian mitochondria and there are also indications of the presence of morecomplex repair processes. Thus, an active field of mitochondrial DNA repair is emerging. Anunderstanding of the DNA repair processes in mammalian mitochondria is an important currentchallenge and it is likely to lead to clarification of the etiology of the common mutations anddeletions that are found in mitochondria, and which are thought to cause various humandisorders and to play a role in the aging phenotype.     

Untangling the crosstalk between BRCA1 and R-loops during DNA repair

R-loops are RNA:DNA hybrids assembled during biological processes but are also linked to genetic instability when formed out of their natural context. Emerging evidence suggests that the repair of DNA double-strand breaks requires the formation of a transient R-loop, which eventually must be removed to guarantee a correct repair process. The multifaceted BRCA1 protein has been shown to be recruited at this specific break-induced R-loop, and it facilitates mechanisms in order to regulate R-loop removal. In this review, we discuss the different potential roles of BRCA1 in R-loop homeostasis during DNA repair and how these processes ensure faithful DSB repair.     

Main repair pathways of double-strand breaks in the genomic DNA and interactions between them

Double-strand DNA breaks (DSBs) resulting from metabolic cellular processes and external factors pose a serious threat to the stability of the genome, but the cells have molecular mechanisms for the efficient repair of this type of damage. In this review, we examine two main biochemical pathways of repairing the double-strand DNA breaks in eukaryotic cells—DNA strands nonhomologous end joining and homologous recombination between sister chromatids or chromatids of homologous chromosomes. Numerous data obtained recently for various eukaryotic cells suggest that there is a complex interplay between the main DSB repair pathways, which normally facilitates efficient repair and maintenance of the structural and functional integrity of the genome, but which, at the same time, under conditions of exposure to genotoxic factors may induce increased genomic instability.     

The role of DNA damage repair in aging of adult stem cells

DNA repair maintains genomic stability and the loss of DNA repair capacity results in genetic instability that may lead to a decline of cellular function. Adult stem cells are extremely important in the long-term maintenance of tissues throughout life. They regenerate and renew tissues in response to damage and replace senescent terminally differentiated cells that no longer function. Oxidative stress, toxic byproducts, reduced mitochondrial function and external exposures all damage DNA through base modification or mis-incorporation and result in DNA damage. As in most cells, this damage may limit the survival of the stem cell population affecting tissue regeneration and even longevity. This review examines the hypothesis that an age-related loss of DNA damage repair pathways poses a significant threat to stem cell survival and longevity. Normal stem cells appear to have strict control of gene expression and DNA replication whereas stem cells with loss of DNA repair may have altered patterns of proliferation, quiescence and differentiation. Furthermore, stem cells with loss of DNA repair may be susceptible to malignant transformation either directly or through the emergence of cancer-prone stem cells. Human diseases and animal models of loss of DNA repair provide longitudinal analysis of DNA repair processes in stem cell populations and may provide links to the physiology of aging.     

Light and dark in chromatin repair: repair of UV-induced DNA lesions by photolyase and nucleotide excision repair

Nucleotide excision repair (NER) and DNA repair by photolyase in the presence of light (photoreactivation) are the major pathways to remove UV-induced DNA lesions from the genome, thereby preventing mutagenesis and cell death. Photoreactivation was found in many prokaryotic and eukaryotic organisms, but not in mammals, while NER seems to be universally distributed. Since packaging of eukaryotic DNA in nucleosomes and higher order chromatin structures affects DNA structure and accessibility, damage formation and repair are coupled intimately to structural and dynamic properties of chromatin. Here, I review recent progress in the study of repair of chromatin and transcribed genes. Photoreactivation and NER are discussed as examples of how an individual enzyme and a complex repair pathway, respectively, access DNA lesions in chromatin and how these two repair processes fulfil complementary roles in removal of UV lesions. These repair pathways provide insight into the structural and dynamic properties of chromatin and suggest how other DNA repair processes could work in chromatin.     

New tricks for old drugs: the anticarcinogenic potential of DNA repair inhibitors

Defective or abortive repair of DNA lesions has been associated with carcinogenesis. Therefore it is imperative for a cell to accurately repair its DNA after damage if it is to return to a normal cellular phenotype. In certain circumstances, if DNA damage cannot be repaired completely and with high fidelity, it is more advantageous for an organism to have some of its more severely damaged cells die rather than survive as neoplastic transformants. A number of DNA repair inhibitors have the potential to act as anticarcinogenic compounds. These drugs are capable of modulating DNA repair, thus promoting cell death rather than repair of potentially carcinogenic DNA damage mediated by error-prone DNA repair processes. In theory, exposure to a DNA repair inhibitor during, or immediately after, carcinogenic exposure should decrease or prevent tumorigenesis. However, the ability of DNA repair inhibitors to prevent cancer development is difficult to interpret depending upon the system used and the type of genotoxic stress. Inhibitors may act on multiple aspects of DNA repair as well as the cellular signaling pathways activated in response to the initial damage. In this review, we summarize basic DNA repair mechanisms and explore the effects of a number of DNA repair inhibitors that not only potentiate DNA-damaging agents but also decrease carcinogenicity. In particular, we focus on a novel anti-tumor agent, β-lapachone, and its potential to block transformation by modulating poly(ADP-ribose) polymerase-1.     

Enhanced sensitivity and long-term G2 arrest in hydrogen peroxide-treated Ku80-null cells are unrelated to DNA repair defects

While the Ku complex, comprised of Ku70 and Ku80, is primarily involved in the repair of DNA double-strand breaks, it is also believed to participate in additional cellular processes. Here, treatment of embryo fibroblasts (MEFs) derived from either wild-type or Ku80-null (Ku80(-/-)) mice with various stress agents revealed that hydrogen peroxide (H(2)O(2)) was markedly more cytotoxic for Ku80(-/-) MEFs and led to their long-term accumulation in the G2 phase. This differential response was not due to differences in DNA repair, since H(2)O(2)-triggered DNA damage was repaired with comparable efficiency in both Wt and Ku80(-/-) MEFs, but was associated with differences in the expression of important cell cycle regulatory genes. Our results support the notion that Ku80-mediated cytoprotection and G2-progression are not only dependent on the cell's DNA repair but also may reflect Ku80's influence on additional cellular processes such as gene expression.     

Senescing human cells and ageing mice accumulate DNA lesions with unrepairable double-strand breaks

Humans and animals undergo ageing, and although their primary cells undergo cellular senescence in culture, the relationship between these two processes is unclear. Here we show that gamma-H2AX foci (gamma-foci), which reveal DNA double-strand breaks (DSBs), accumulate in senescing human cell cultures and in ageing mice. They colocalize with DSB repair factors, but not significantly with telomeres. These cryptogenic gamma-foci remain after repair of radiation-induced gamma-foci, suggesting that they may represent DNA lesions with unrepairable DSBs. Thus, we conclude that accumulation of unrepairable DSBs may have a causal role in mammalian ageing.     

DNA damage alters nuclear mechanics through chromatin reorganization

DNA double-strand breaks drive genomic instability. However, it remains unknown how these processes may affect the biomechanical properties of the nucleus and what role nuclear mechanics play in DNA damage and repair efficiency. Here, we have used Atomic Force Microscopy to investigate nuclear mechanical changes, arising from externally induced DNA damage. We found that nuclear stiffness is significantly reduced after cisplatin treatment, as a consequence of DNA damage signalling. This softening was linked to global chromatin decondensation, which improves molecular diffusion within the organelle. We propose that this can increase recruitment for repair factors. Interestingly, we also found that reduction of nuclear tension, through cytoskeletal relaxation, has a protective role to the cell and reduces accumulation of DNA damage. Overall, these changes protect against further genomic instability and promote DNA repair. We propose that these processes may underpin the development of drug resistance.     

Why do Neurons Enter the Cell Cycle?

Increasing evidence indicates that postmitotic, terminally differentiated neurons activate the cell cycle before death. The purpose of this cell cycle activation, however, remains elusive. In proliferating cells, cell cycle machinery is a major contributor to the DNA damage response, which is comprised of growth arrest. In quiescent cells such as terminally differentiated neurons, cell cycle-associated events may also be part of the DNA damage response. A link between DNA damage and repair, cell cycle regulation and cell death is becoming increasingly recognized for cycling cells but remains elusive for quiescent cells. Neurons are particularly susceptible to oxidative stress due to the high rate of oxidative metabolism in the brain and the low level of antioxidant enzymes compared to other somatic tissues. This is supported by fact that the intracellular end point of many neurotoxic stimuli is oxidative stress, which also represents a major cause of the neuropathology underlying a variety of neurodegenerative diseases. DNA is perhaps the major target of oxyradicals. Thus, oxidative stress may cause DNA damage, which is countered by a complex defense mechanism, the DNA damage response, which involves not only the elimination of DNA damage, but its coordination with other cellular processes such as cell-cycle progression, together directing to preserve genomic integrity. The function of such response is the removal of DNA damage by DNA repair pathways, or the elimination of damaged cells via apoptosis. The present review discusses the idea that the cell cycle machinery is a critical element of the DNA damage response not only in cycling, but also quiescent cells, and may bear the same function: to repair the damage or initiate apoptosis if the damage is too extensive to be repaired.