Influence of physiological conditions on DNA repair and mutagenesis in higher plants

In barley ( Hordeum vulgare L.) and grass pea ( Lathyrus sativus L.), caffeine, an inhibitor of DNA repair activity, and Na₂ethylenediaminetetraacetate, an inhibitor of DNA-endonucleases, sharply decreased the excision repair of pyrimidine dimers induced in DNA by ultraviolet irradiation. An inhibitor of RNases, diethylpyro-carbonate, did not inhibit the process of excision, and in one experiment it even enhanced excision. Caffeine markedly increased the frequency of mutations and inhibited the growth of seedlings after UV-radiation. Such enhancement was greater with the higher UV fluence. Results of chemical inhibition were further confirmed by the suppression of repair by low temperatures: the frequency of chromatid aberrations induced with propyl methanesulfonate was increased more than 3 times and chromatid aberrations 1.5 times. Evidence for participation of repair enzymes in the modification of mutation processes was also obtained in the experiments which combined γ-irradiation and treatment with propyl methanesulfonate. Conditions favouring repair activity caused a drastic reduction in the frequency of aberrations, whereas with conditions preventing enzyme function the mutation frequency increased. In one of the experiments of this series we were able to demonstrate, with identical mutagenic treatment, that by changing post-mutagen conditions (wetting and drying of seeds, storage after mutagenic treatment) it was possible to alter the mutation frequency and to obtain below-additive, additive and synergistic mutational response.     

Identification of rat DDB1, a putative DNA repair protein,and functional correlation with its damaged-DNA recognition activity

Recognition and incision of UV-DNA adducts play key roles in the efficacy of nucleotide excision repair. Damaged-DNA recognition activity has been identified from primate cells as a complex of DDB1 (127-kD) and DDB2 (48-kD) subunits. However, the function of damaged-DNA binding proteins (DDBs) in damaged-DNA recognition is not well understood. To assess the functional correlation between DDBs and UV-damaged-DNA recognition activity, we identified UV-damaged-DNA recognition activities in rodent cell lines. There is a cell type-dependent expression of DDB1 and DDB2. Rodent cells had less abundant DDBs and lower UV-damaged-DNA recognition activity than did human tumor cells. Interestingly, the profusion of DDBs is associated with UV-damaged-DNA recognition activity in these cell lines. We also discovered tissue-dependent expression of DDBs and its functional correlation with UV-damaged-DNA recognition activity. cDNA (3850 nucleotides) from rat ddb1 was isolated. It contained the complete length of the open reading frame that encodes an 1140-amino-acid polypeptide with a predicted molecular weight of 126.8 kD. The predicted protein size from the rat ddb1 gene resembles that from human DDB1 (127 kD). Rat DDB1 shares highly conserved sequencing (greater than 98% similarity) with those of mouse, human, and monkey. Rat and fruit fly DDB1 exhibit 62.23% identity and 57.66% homology. The evolutionary conservation of the DDB1 sequence suggests that DDB1 may play a pivotal role in mammals as well as in other eukaryotes. However, overexpression of DDB1 did not augment UV-damaged-DNA recognition activity in human HeLa, hamster V79, or rat PC12 cells. In contrast, restricting DDB2 expression by antisense ddb2 partially inhibited UV-damaged-DNA recognition activity in cells, whereas overexpressing DDB2 through a recombinant ddb2 adenovirus partly restored the recognition activity of these cells. These findings support the notion that DDB abundance is functionally correlated with UV-damaged-DNA recognition activity. These results also suggest that the profusion of DDB2, but not DDB1, may moderate UV-damaged-DNA recognition activity.     

Simulated microgravity decreases DNA repair capacity and induces DNA damage in human lymphocytes

The effect of simulated microgravity on DNA damage and apoptosis is still controversial. The objective of this study was to test whether simulated microgravity conditions affect the expression of genes for DNA repair and apoptosis. To achieve this objective, human lymphocyte cells were grown in a NASA‐developed rotating wall vessel (RWV) bioreactor that simulates microgravity. The same cell line was grown in parallel under normal gravitational conditions in culture flasks. The effect of microgravity on the expression of genes was measured by quantitative real‐time PCR while DNA damage was examined by comet assay. The result of this study revealed that exposure to simulated microgravity condition decreases the expression of DNA repair genes. Mismatch repair (MMR) class of DNA repair pathway were more susceptible to microgravity condition‐induced gene expression changes than base excision repair (BER) and nucleotide excision repair (NER) class of DNA repair genes. Downregulation of genes involved in cell proliferation (CyclinD1 and PCNA) and apoptosis (Bax) was also observed. Microgravity‐induced changes in the expression of some of these genes were further verified at the protein level by Western blot analysis. The findings of this study suggest that microgravity may induce alterations in the expression of these DNA repair genes resulting in accumulation of DNA damage. Reduced expression of cell‐cycle genes suggests that microgravity may cause a reduction in cell growth. Downregulation of pro‐apoptotic genes further suggests that extended exposure to microgravity may result in a reduction in the cells' ability to undergo apoptosis. Any resistance to apoptosis seen in cells with damaged DNA may eventually lead to malignant transformation of those cells. J. Cell. Biochem. 107: 723–731, 2009. © 2009 Wiley‐Liss, Inc.     

Bufalin influences the repair of X-ray-induced DNA breaks in Chinese hamster cells

The bufadienolide bufalin, a component of the Chinese medicine chan'su, has been reported to selectively inhibit the growth of various lines of human cancer cells, due at least in part to its specific effect on topoisomerase (topo) II. We have treated Chinese hamster ovary (CHO) cells with doses of bufalin that result in a dramatic reduction in both the level and catalytic activity of topo II without any concomitant induction of DNA damage, as assessed by the comet assay. When cells were pre-treated with bufalin and then irradiated with X-rays, a follow-up study revealed that the kinetics of DNA repair was clearly affected, with a general delay in the restoration of DNA to the situation observed in non-irradiated controls. The possible involvement of topo II in radiation damage repair is discussed.     

Analysis of the distribution of DNA repair patches in the DNA-nuclear matrix complex from human cells

The distribution of ultraviolet-induced repair patches along DNA loops attached to the nuclear matrix, was investigated by digestion with DNA-degrading enzymes and neutral sucrose gradient centrifugation. When DNA was gradually removed by DNAase 1, pulse label incorporated by ultraviolet-irradiated cells during 10 min in the presence of hydroxyurea or hydroxyurea/arabinosylcytosine showed similar degradation kinetics as prelabelled DNA. No preferential association of pulse label with the nuclear matrix was observed, neither within 30 min nor 13 h after irradiation. When the pulse label was incorporated by replicative synthesis under the same conditions, a preferential association of newly-synthesized DNA with the nuclear matrix was observed. Single-strand specific digestion with nuclease S₁ of nuclear lysates from ultraviolet-irradiated cells, pulse labelled in the presence of hydroxyurea/arabinosylcytosine, caused a release of about 70% of the prelabelled DNA and 90% of the pulse-labelled DNA from the rapidly sedimenting material in sucrose gradients. The results suggest no specific involvement of the nuclear matrix in repair synthesis, a random distribution of repair patches along the DNA loops, and simultaneously multiple incision events per DNA loop.     

DNA repair of clustered uracils in HeLa cells

Two or more base damages, abasic sites or single-strand breaks (SSBs) within two helical turns of the DNA form a multiply damaged site (MDS) or clustered lesion. Studies in vitro and in bacteria indicate that attempts to repair two closely opposed base lesions can potentially form a lethal double-strand break (DSB). Ionizing radiation and chemotherapeutic agents introduce complex lesions, and the inability of a cell to repair MDSs is believed to contribute to the lethality of these treatments. The goal of this work was to extend the in vitro studies by examining MDS repair in mammalian cells under physiological conditions. Here, two opposing uracil residues separated by 3, 5, 7, 13 or 29 base-pairs were chosen as model DNA lesions. Double-stranded oligonucleotides containing no damage, a single uracil residue or the MDS were introduced into a non-replicating mammalian construct within the firefly luciferase open reading frame, or at the 5' or 3' end of the luciferase expression cassette. Following transient transfection into HeLa cells, luciferase activity was measured or plasmid DNA was re-isolated from the cells. Formation of a DSB was expected to decrease luciferase expression. However, certain single uracil residues as well as the MDSs decreased luciferase activity, which suggested that the reduction in activity was not due to DSB formation. In fact, Southern analysis of the re-isolated plasmid did not show the presence of linear DNA and demonstrated that none of the constructs was destroyed during repair. Further analysis of the re-isolated DNA demonstrated that only a small percentage of molecules originally carrying a single lesion or an MDS contained deletions. This work indicates that the majority of the clustered lesions were not converted to DSBs and that repair systems in mammalian cells may have established mechanisms to avoid the accumulation of SSB-repair intermediates.     

SUMO化修饰与DNA损伤修复

由于体内外因素的影响,DNA损伤是生物生命周期中的常见现象,如果得不到及时的修复,DNA损伤的积累将导致基因组的不稳定及染色质的异常,并可能导致肿瘤的发生发展。SUMO化修饰是体内一个重要的蛋白质翻译后修饰,越来越多的研究发现SUMO化修饰与多个参与DNA损伤反应、维持基因组稳定的蛋白质相关,有可能参与肿瘤的发生。本文将阐述SUMO化修饰与DNA损伤修复的关系。     

DNA repair in hybrid fish of the genus Xiphophorus

The genus Xiphophorus is an important vertebrate model for investigating the etiology and genetics of both spontaneous and induced cancers. Xiphophorus are comprised of 23 species most of which can be crossed to produce fertile interspecies hybrid progeny. The Xiphophorus gene map is well developed and allows genetic associations to be studied among cohorts of progeny derived from backcrossing interspecies hybrid animals to one of the parental strains. In interspecies cross-progeny from select Xiphophorus backcrosses, ionizing radiation, ultraviolet light (UVB), and exposure to methylnitrosourea (MNU) have all been shown to induce tumors. Induced tumor types represented in various models include melanoma, fibrosarcoma, schwannoma, retinoblastoma, etc. The well-established backcross hybrid genetics make Xiphophorus fish an excellent system to study the contribution of DNA repair capability to induced tumorigenesis. DNA repair pathways represent multigenic traits that must be tightly regulated to insure genome fidelity. Herein we review initial DNA repair studies that assess repair capacities among different Xiphophorus species and interspecies hybrids. Assessment of both base excision repair (BER) and nucleotide excision repair (NER) have yielded consistent results indicating reduced DNA repair function in hybrid fish tissues. These data provide molecular support for potential reduced fitness in hybrid fish under conditions of environmental stress and may present a plausible explanation for absence of interspecies hybridization in sympatric environments. In addition, they support the role of direct DNA damage and its repair in the initiation of tumors in Xiphophorus hybrids.     

Direct involvement of p53 in the base excision repair pathway of the DNA repair machinery

The p53 tumor suppressor that plays a central role in the cellular response to genotoxic stress was suggested to be associated with the DNA repair machinery which mostly involves nucleotide excision repair (NER). In the present study we show for the first time that p53 is also directly involved in base excision repair (BER). These experiments were performed with p53 temperature-sensitive (ts) mutants that were previously studied in in vivo experimental models. We report here that p53 ts mutants can also acquire wild-type activity under in vitro conditions. Using ts mutants of murine and human origin, it was observed that cell extracts overexpressing p53 exhibited an augmented BER activity measured in an in vitro assay. Depletion of p53 from the nuclear extracts abolished this enhanced activity. Together, this suggests that p53 is involved in more than one DNA repair pathway.     

Crosstalk between autophagy and DNA repair systems

Autophagy and DNA repair are two essential biological mechanisms that maintain cellular homeostasis. Impairment of these mechanisms was associated with several pathologies such as premature aging, neurodegenerative diseases, and cancer. Intrinsic or extrinsic stress stimuli (e.g., reactive oxygen species or ionizing radiation) cause DNA damage. As a biological stress response, autophagy is activated following insults that threaten DNA integrity. Hence, in collaboration with DNA damage repair and response mechanisms, autophagy contributes to the maintenance of genomic stability and integrity. Yet, connections and interactions between these two systems are not fully understood. In this review article, current status of the associations and crosstalk between autophagy and DNA repair systems is documented and discussed.     

紫外线-B辐射对植物DNA及蛋白质的影响

大气平流层中的臭氧衰减,导致太阳辐射中的紫外辐射量有明显的增加,其中UV-B辐射对植物会产生不同程度的影响。分子生态学理论认为,UV-B辐射对植物造成的损伤,首先伤害植物的生物大分子,即进行光化学修饰。本文就臭氧衰减对生态环境和植物的影响途径进行了讨论,重点论述了UV-B辐射对植物蛋白质合成的抑制和DNA的损伤修复途径。并应用分子生物学技术研究植物对UV-B辐射的抗性机理和DNA修复技术的前景进行了展望。     

The repair rate of radiation-induced DNA damage: a stochastic interpretation based on the gamma function

There is a large body of evidence that stress-induced DNA damage may be responsible for cell lethality, cancer proneness and/or immune reaction. However, statistical features of their repair rate remain poorly documented. In order to interpret the shape of the radiation-induced DNA damage repair curves with a minimum of biological assumptions, we introduced the concept of repair probability, specific to any individual radiation-induced DNA damage, whatever its biochemical type. We strengthened the apparent paradox that the repair rate of a population of DNA damage is time-dependent even if the repair rate of the individual DNA damage is constant. Hence, the existing models, based on a dual approach of the DNA repair may be insufficient for describing the DNA repair rate over a large range of repair times. Since the repair probability of DNA damage cannot be assessed individually, the measurement of the DNA repair rate is assumed to consist in determining the instantaneous mean of all repair probabilities. The relevance of this model was examined with different endpoints: cell species, genotypes, radiation type and chromatin condensation. The Euler's Gamma function was shown to provide the distribution the most consistent with such hypotheses. Furthermore, formulas, deduced from the Gamma distribution, were found to be compatible with our previous model, empirically defined but based on a variable repair half-time.     

Comments on the present situation of DNA systematics in higher plants

Short comments were made to the present situation of DNA systematics in higher plants, particularily on intraspecific variations in chloroplast DNA. Comments were also extended to DNA plant geography.     

A brief history of the DNA repair field

The history of the repair of damaged DNA can be traced to the mid-1930s. Since then multiple DNA repair mechanisms, as well as other biological responses to DNA damage, have been discovered and their regulation has been studied. This article briefly recounts the early history of this field.     

The repair of DNA damage: Recent developments and new insights

This brief review presents the salient features of new developments in the enzymatic repair of base damage to DNA. DNA glycosylases and apurinic/ apyrimidinic (AP) endonucleases are reviewed and evidence is presented that in at least two prokaryote systems incision of UV-irradiated DNA occurs by the sequential action of these two classes of enzymes. In contradistinction, the uvrA, uvrB, and uvrC gene products of E coli appear to function as a multiprotein complex that catalyzes hydrolysis of phosphodiester bonds in damaged DNA directly. The inducible rapid repair of O⁶- methylguanine in E coli is also reviewed.     

Characterization of the plant homolog of Nijmegen breakage syndrome 1: Involvement in DNA repair and recombination

The Nbs1 gene is known to code for a protein involved in the hereditary cancer-prone disease, Nijmegen breakage syndrome. This gene is conserved in animals and fungi, but no plant homolog is known. The work reported here describes a homolog of Nbs1 isolated from higher plants. The Nbs1 proteins from both Arabidopsis thaliana and Oryza sativa are smaller in size than animal or yeast Nbs1, but both contain the conserved Nbs1 domains such as the FHA/BRCT domain, the Mre11-binding domain, and the Atm-interacting domain in orientations similar to what is seen in animal Nbs1. The OsNbs1 protein interacted not only with plant Mre11, but also with animal Mre11. In plants, OsNbs1 mRNA expression was found to be higher in the shoot apex and young flower, and AtNbs1 expression increased when plants were exposed to 100 Gy of X-rays. These results suggest that plant Nbs1 could participate in a Rad50/Mre11/Nbs1 complex, and could be essential for the regulation of DNA recombination and DNA damage responses.     

Molecular response to climate change: temperature dependence of UV-induced DNA damage and repair in the freshwater crustacean Daphnia pulicaria

In temperate lakes, asynchronous cycles in surface water temperatures and incident ultraviolet (UV) radiation expose aquatic organisms to damaging UV radiation at different temperatures. The enzyme systems that repair UV‐induced DNA damage are temperature dependent, and thus potentially less effective at repairing DNA damage at lower temperatures. This hypothesis was tested by examining the levels of UV‐induced DNA damage in the freshwater crustacean Daphnia pulicaria in the presence and absence of longer‐wavelength photoreactivating radiation (PRR) that induces photoenzymatic repair (PER) of DNA damage. By exposing both live and dead (freeze‐killed) Daphnia as well as raw DNA to UV‐B in the presence and absence of PRR, we were able to estimate the relative importance and temperature dependence of PER (light repair), nucleotide excision repair (NER, dark repair), and photoprotection (PP). Total DNA damage increased with increasing temperature. However, the even greater increase in DNA repair rates at higher temperatures led net DNA damage (total DNA damage minus repair) to be greater at lower temperatures. Photoprotection accounted for a much greater proportion of the reduction in DNA damage than did repair. Experiments that looked at survival rates following UV exposure demonstrated that PER increased survival rates. The important implication is that aquatic organisms that depend heavily on DNA repair processes may be less able to survive high UV exposure in low temperature environments. Photoprotection may be more effective under the low temperature, high UV conditions such as are found in early spring or at high elevations.     

Acclimation and repair of DNA damage in recombinant bioluminescent Escherichia coli

AIMS: The aim of this study is to understand different adaptive responses in bacteria caused by three different mutagens, namely, an intercalating agent, an alkylating agent and a hydroxylating agent, and the repair systems according to the type of DNA damage, that is, DNA cross-linking and delayed DNA synthesis, alkylation and hydroxylation of DNA. A recombinant bioluminescent Escherichia coli, DPD2794 with the recA promoter fused to luxCDABE originating from Vibrio fischeri, was used in this study. METHODS AND RESULTS: The recombinant bioluminescent E. coli strain DPD2794, containing a recA promoter fused to luxCDABE from V. fischeri, was used to detect adaptive and repair responses to DNA damage caused by mitomycin C (MMC), and these responses were compared with those when the cells were induced with N-methyl-N-nitro-N-nitrosoguanidine (MNNG) and hydrogen peroxide (H2O2). The response ratio between the induced samples and that of the controls decreased suddenly when the induced culture was used in further inductions, indicating a possible adaptive response to DNA damage. DNA damage, or the proteins produced, because of MMC addition does not appear to be completely resolved until the seventh sub-culture after the initial induction, whereas simple damage, such as the base modification caused by MNNG and H2O2, appears to be repaired rapidly as evidenced by the quick recovery of sensitivity. CONCLUSIONS: These results suggest that it takes more time to completely repair DNA damage caused by MMC, as compared with a simple repair such as that required for the damage caused by MNNG and H2O2. Therefore, repair of the damage caused by these three mutagens is controlled by different regulons, even though they all induced the recA promoter. SIGNIFICANCE AND IMPACT OF THE STUDY: Using a bioluminescent E. coli harbouring a recA promoter-lux fusion, it was found that different adaptive responses and repair systems for DNA damage caused by several mutagens exists in E. coli.     

白念珠菌DNA损伤与修复

内外环境中各种因素如电离辐射、紫外辐射、氧化剂、烷化剂等都可以造成白念珠菌DNA的损伤。如果DNA的损伤得不到有效的修复,便会造成突变。白念珠菌的突变率很高,但并不是所有DNA受损伤的细胞都会表现出突变型性状,这跟其自身的修复系统有很大关系,主要包括切除修复、错配修复及双链断裂修复等途径,使得绝大多数损伤能够及时修复,从而维持DNA的完整性与稳定性。白念珠菌DNA的损伤修复可能影响其适应性、药物敏感性等表型,从而给临床感染患者的治疗增加难度。本文主要从白念珠菌DNA损伤的产生,损伤信号的传导识别及损伤修复三方面综述目前的研究进展。