The nucleotide excision repair pathway is required for UV-C-induced apoptosis in Caenorhabditis elegans

Ultraviolet (UV) radiation is a mutagen of major clinical importance in humans. UV-induced damage activates multiple signaling pathways, which initiate DNA repair, cell cycle arrest and apoptosis. To better understand these pathways, we studied the responses to UV-C light (254 nm) of germ cells in Caenorhabditis elegans. We found that UV activates the same cellular responses in worms as in mammalian cells. Both UV-induced apoptosis and cell cycle arrest were completely dependent on the p53 homolog CEP-1, the checkpoint proteins HUS-1 and CLK-2, and the checkpoint kinases CHK-2 and ATL-1 (the C. elegans homolog of ataxia telangiectasia and Rad3-related); ATM-1 (ataxia telangiectasia mutated-1) was also required, but only at low irradiation doses. Importantly, mutation of genes encoding nucleotide excision repair pathway components severely disrupted both apoptosis and cell cycle arrest, suggesting that these genes not only participate in repair, but also signal the presence of damage to downstream components of the UV response pathway that we delineate here. Our study suggests that whereas DNA damage response pathways are conserved in metazoans in their general outline, there is significant evolution in the relative importance of individual checkpoint genes in the response to specific types of DNA damage.     

Isolation and physiological characterization of mitomycin C-sensitive/UV-sensitive mutants in Bacteroides fragilis

Mutants of Bacteroides fragilis sensitive to mitomycin C were isolated after mutagenesis with ethyl methane sulphonate. One mutant (MTC25) was markedly sensitive to mitomycin C but was unaffected as regards UV sensitivity; another mutant (UVS9) was sensitive to UV radiation but was only moderately sensitive to mitomycin C. Caffeine decreased the survival after UV-irradiation of the wild-type, MTC25 and UVS9 strains by the same relative amount. Aerobic liquid holding recovery occurred in each of the three strains. The MTC25 and UVS9 mutants showed reduced host cell phage reactivation. The wild-type, MTC25 and UVS9 strains all showed UV- and H2O2-induced phage reactivation. The physiological characterization of the MTC25 and UVS9 mutants indicates that it is possible to differentiate between mechanisms for the repair of mitomycin C- and UV-induced DNA damage in B. fragilis.     

Non-essential UV-sensitive bacteriophage T4 mutants affecting early DNA synthesis: a third pathway of DNA repair.

Non-essential bacteriophage T4 mutants uvs58 and uvs79 showed a lower UV sensitivity than either the excision-repair mutant v am5 or the replication-dependent recombination-repair mutant y10. The UV sensitivity of double and triple mutants carrying one of the mutations uvs58 or uvs79, and v am 5 or (and) y10 was higher than the sum of the sensitivities of the single mutants. The uvs58 mutation was mapped to the early gene region, close to amN81 (gene 41). The unirradiated mutants uvs58 and uvs79 accumulated newly synthesized DNA at a slower rate than wild-type T4. Double mutants uvs58:am59 and uvs79:am59 showed DNA synthesis in E. coli B su- to be arrested at a 3--5 times lower level than that in am59-infected cells. Chloramphenicol, added 9--12 min after infection, suppressed arrests of DNA synthesis, the double mutants showing a lag of 8 min as compared with am59. Results from analysis of sucrose gradients of parental uvs58 and uvs79 DNA were in agreement with the suggestion of a mutation in an early function. The mutants uvs58 and uvs79 are suggested to be defective in a component of the DNA replication apparatus with a function in the adaptation to irregularities in the DNA structure. The third pathway of UV repair is tentatively designated as non-catalytic replication repair.     

DNA damage during G2 phase does not affect cell cycle progression of the green alga Scenedesmus quadricauda

DNA damage is a threat to genomic integrity in all living organisms. Plants and green algae are particularly susceptible to DNA damage especially that caused by UV light, due to their light dependency for photosynthesis. For survival of a plant, and other eukaryotic cells, it is essential for an organism to continuously check the integrity of its genetic material and, when damaged, to repair it immediately. Cells therefore utilize a DNA damage response pathway that is responsible for sensing, reacting to and repairing damaged DNA. We have studied the effect of 5-fluorodeoxyuridine, zeocin, caffeine and combinations of these on the cell cycle of the green alga Scenedesmus quadricauda. The cells delayed S phase and underwent a permanent G2 phase block if DNA metabolism was affected prior to S phase; the G2 phase block imposed by zeocin was partially abolished by caffeine. No cell cycle block was observed if the treatment with zeocin occurred in G2 phase and the cells divided normally. CDKA and CDKB kinases regulate mitosis in S. quadricauda; their kinase activities were inhibited by Wee1. CDKA, CDKB protein levels were stabilized in the presence of zeocin. In contrast, the protein level of Wee1 was unaffected by DNA perturbing treatments. Wee1 therefore does not appear to be involved in the DNA damage response in S. quadricauda. Our results imply a specific reaction to DNA damage in S. quadricauda, with no cell cycle arrest, after experiencing DNA damage during G2 phase.     

Genetic control of the sensitivity of Aspergillus nidulans to mutagenic factors. VII. Inheritance of cross-sensitivity to different mutagenic factors by uvs-mutants]

To study the inheritance of the sensitivity to UV, X-rays, methylmethanesulphonate (MMS), nitrosoguanidine (NG) and nitrous acid (NA) in five uvs mutants of Aspergillus nidulans, having multiple sensitivity to these factors, the sensitivity of recombinants obtained from crossing uvs mutants with uvs+ strain, resistant to all the factors analysed, and uvs leads to uvs+ revertants is investigated. Four uvs mutants (15, 17, 19 and 26) are found to have a nomogenic control of sensitivity to different mutagens. In one mutant (uvs11) the sensitivity to five factors is controlled by two non-linked mutations, one of them determining the sensitivity to UV, NG, NA, and the other--to X-rays and MMC. Phenotypic manifestations of uvs mutations is modified by cell genotype, both chromosomal and cytoplasmic factors being responsible for the modification. Phenotypic modification of uvs mutation results in the change to some (but not to all) mutagenic factors. It suggests, that not the product of uvs gene, but some other components of the reparation complex are modified. Otherwise, reparation of different DNA damages can be carried out by a single enzyme acting in different reparation complexes.     

The G2/M DNA damage checkpoint inhibits mitosis through Tyr15 phosphorylation of p34cdc2 in Aspergillus nidulans.

It is possible to cause G2 arrest in Aspergillus nidulans by inactivating either p34cdc2 or NIMA. We therefore investigated the negative control of these two mitosis-promoting kinases after DNA damage. DNA damage caused rapid Tyr15 phosphorylation of p34cdc2 and transient cell cycle arrest but had little effect on the activity of NIMA. Dividing cells deficient in Tyr15 phosphorylation of p34cdc2 were sensitive to both MMS and UV irradiation and entered lethal premature mitosis with damaged DNA. However, non-dividing quiescent conidiospores of the Tyr15 mutant strain were not sensitive to DNA damage. The UV and MMS sensitivity of cells unable to tyrosine phosphorylate p34cdc2 is therefore caused by defects in DNA damage checkpoint regulation over mitosis. Both the nimA5 and nimT23 temperature-sensitive mutations cause an arrest in G2 at 42 degrees C. Addition of MMS to nimT23 G2-arrested cells caused a marked delay in their entry into mitosis upon downshift to 32 degrees C and this delay was correlated with a long delay in the dephosphorylation and activation of p34cdc2. Addition of MMS to nimA5 G2-arrested cells caused inactivation of the H1 kinase activity of p34cdc2 due to an increase in its Tyr15 phosphorylation level and delayed entry into mitosis upon return to 32 degrees C. However, if Tyr15 phosphorylation of p34cdc2 was prevented then its H1 kinase activity was not inactivated upon MMS addition to nimA5 G2-arrested cells and they rapidly progressed into a lethal mitosis upon release to 32 degrees C. Thus, Tyr15 phosphorylation of p34cdc2 in G2 arrests initiation of mitosis after DNA damage in A. nidulans.     

Revealing targeted therapeutic opportunities in triple-negative breast cancers: A new strategy

Nek6 is a recently identified NIMA-related kinase that is required for mitotic cell cycle progression. In the present study, we examined the role of Nek6 in the DNA damage response. We found that Nek6 is phosphorylated upon IR and UV irradiation through the DNA damage checkpoint in vivo. Nek6 is also directly phosphorylated by the checkpoint kinases Chk1 and Chk2 in vitro. Notably, Nek6 activation during mitosis is completely abolished by IR and UV irradiation. Moreover, the ectopic expression of Nek6 overrides DNA damage-induced G2/M arrest. These results suggest that Nek6 is a novel target of the DNA damage checkpoint and that the inhibition of Nek6 activity is required for proper cell cycle arrest in the G2/M phase upon DNA damage.     

Study of selected characteristics of theChlamydomonas reinhardii strains with altered sensitivity to UV radiation

Selected characteristics and streptomycin resistance were studied in a UV radiation sensitive (UVS1) and a UV radiation resistant (UVR1) strains, and the data were compared with results obtained with an original type strain. A partial prolongation of the cell cycle in the UVR1 strain as compared with the original type strain could be observed in studying cell volume growth, cell numbers, DNA, RNA and protein synthesis during the synchronous cycle. Under these conditions, the UVS1 strain behaved as a temperature sensitive cell cycle mutant. In inducing streptomycin resistant mutants, the highest frequencies in various doses were recorded in the UVS1 strain.     

Cell cycle-related variations in UV damage and repair capacity in chinese hamster (CHO-K1) cells

UV damage to CHO cell DNA, measured by formation of thymine-containing dimers, increases from mitosis to early S phase. Computer simulation of UV absorption by the DNA of an idealized CHO cell at different stages in the cell cycle resembles the cycle dependence of UV damage. Incision at UV damage sites, measured by the accumulation of breaks in preexisting DNA during 30 minutes' post-irradiation incubation with the DNA synthesis inhibitors 1-β-D arabinofuranosylcytosine and hydroxyurea, increases from mitosis to interphase. Analysis of the dose dependence of DNA break accumulation indicates that both the affinity of the endonuclease for dimer sites and the maximum enzyme activity at saturating levels of dimers are significantly lower in mitosis than in interphase. The killing of CHO cells by UV is enhanced if repair is temporarily inhibited by ara C. The DNA gyrase inhibitor novobiocin prevents UV-induced incision.     

RAD29 and RAD31--new genes from Saccharomyces cerevisiae yeasts, participating in control of DNA repair. Isolation and genetic study of mutants

Base excision repair (BER) and nucleotide excision repair (NER) are two main cellular responses to DNA damage induced by various physical and chemical factors. After exposure of the strain that carries the NER-blocking rad2 mutation to UV light, several mutants hypersensitive to the UV light lethal action and simultaneously sensitive to methylmethanesulphonate (MMS) were isolated. Two of these mutants (Uvs64 and Uvs212) were examined in detail. The mutants were found to carry recessive, monogenically inherited lesions that had pleiotropic, though different, phenotypes: both mutants were also sensitive to nitrous acid (HNO2), whereas Uvs212 was sensitive to hydrogen peroxide as well. Moreover, the homozygote for the uvs212 mutation, but not for uvs64, blocks the sporulation. Since the mutations examined were not allelic to any of the known rad mutations that cause MMS sensitivity or to each other, it is concluded that two new genes involved in the control of yeast DNA repair were detected. Furthermore, these genes were mapped to different regions of the right arm of chromosome 2 where repair genes were not found. Thus, two new genes, designated RAD29(UVS64) and RAD31(UVS212) and probably involved in base excision repair, were identified.     

Inactivation of the cyclin-dependent kinase Cdc28 abrogates cell cycle arrest induced by DNA damage and disassembly of mitotic spindles in Saccharomyces cerevisiae.

Eukaryotic cells may halt cell cycle progression following exposure to certain exogenous agents that damage cellular structures such as DNA or microtubules. This phenomenon has been attributed to functions of cellular control mechanisms termed checkpoints. Studies with the fission yeast Schizosaccharomyces pombe and mammalian cells have led to the conclusion that cell cycle arrest in response to inhibition of DNA replication or DNA damage is a result of down-regulation of the cyclin-dependent kinases (CDKs). Based on these studies, it has been proposed that inhibition of the CDK activity may constitute a general mechanism for checkpoint controls. Observations made with the budding yeast Saccharomyces cerevisiae, however, appear to disagree with this model. It has been shown that high levels of mitotic CDK activity are present in the budding yeast cells arrested in G2/mitosis as the result of DNA damage or replication inhibition. In this report, we show that a novel mutant allele of the CDC28 gene, encoding the budding yeast CDK, allowed cell cycle passage through mitosis and nuclear division in the presence of DNA damage and the microtubule toxin nocodazole at a restrictive temperature. Unlike the checkpoint-defective mutations in CDKs of fission yeast and mammalian cells, the cdc28 mutation that we identified was recessive and resulted in a loss of the CDK activity, including the Clb2-, Clb5-, and Clb6-associated, but not the Clb3-associated, CDK activities. Examination of several known alleles of cdc28 revealed that they were also, albeit partially, defective in cell cycle arrest in response to UV-generated DNA damage. These findings suggest that Cdc28 kinase in budding yeast may be required for cell cycle arrest resulting from DNA damage and disassembly of mitotic spindles.     

CPI大部分缺失影响莱茵衣藻光能转换特性的研究

用紫外光处理野生型莱菌衣藻（Chlamydomonas reinhardtii）CC－125得到突变体CC－1047。电泳检测证明：突变型衣藻CC－1047缺失了绝大部分色素蛋白复合体I（CPI）。进而详细地研究了CPI的部分缺失对突变型衣藻的光物理和光化学反应的影响。野生型衣藻的低温荧光峰有两个,分别在691nm和717nm左右;突变型CC－1047的低温荧光峰只有一个,在709nm左右,且荧光强度增加了3－4倍。709nm的峰被认为是光系统I捕光天线色素所发出的。在突变体中出现的这个峰,说明天线色素吸收的光能未能传递到光系统I的反应中心,再进行电荷分离;而是以荧光的形式也发生了改变,野生型和突变型的荧光在开启作用光后都很快上升,但随后野生型的逐渐下降,而突变型CC－1047的基本上不下降;与野生型相比,突变型衣藻CC－1047的光系统I反应中心色系P700的氧化还原活性降低80％以上,表明突变型衣藻细胞内与PSI相关的电子传递已不能正常运转。     

Survival of human metallothionein-2 transplastomic Chlamydomonas reinhardtii to ultraviolet B exposure

Solar ultraviolet (UV) radiation has a great influence on green organisms,especially planktonlike Chlamydomonas.A human metallothionein-2 gene,which is generally considered to have an anti-radiationfunction by its coding product,was transferred into the chloroplast genome of Chlamydomonas reinhardtii.To dynamically measure the UV effects on Chlamydomonas cells grown in liquid tris-acetate-phosphatemedium,a new method was developed based on the relationship between the chlorophyll content of an algalculture and its absorbance at 570 nm after the 3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyltetrazolium bromideassay.In this experiment,both the wild-type and the transplastomic C.reinhardtii ceils were cultivated in 96-well microplates containing liquid tris-acetate-phosphate medium in the absence or presence of zinc,copper,cadmium and cysteine.The transgenic C.reinhardtii showed a higher resistance than wild-type to UV-Bexposure under all the examined conditions.Metals in the medium had positive impacts on both types of cells,but had significant influence only on the transplastomic cells.However,the high cell viability of the trans-genie alga at the end of the 8 h UV-B treatment disappeared after a 20-h recovery culture.Cysteine did notprotect cells from UV-B damage,but clearly enhanced the growth of both wild-type and transgenic C.reinhardtii.     

Intracellular carbonic anhydrase is essential to photosynthesis in Chlamydomonas reinhardtii at atmospheric levels of CO2. Demonstration via genomic complementation of the high-CO2-requiring mutant ca-1.

Genomic complementation of the high-CO2-requiring mutant ca-1-12-1C of Chlamydomonas reinhardtii was achieved by transformation with DNA pools from an indexed cosmid library of wild-type genomic DNA. Transformation of mutant cells with cosmid DNA from two microtiter plates in the library produced colonies that grew phototrophically at atmospheric CO2 levels. Transformations with cosmid DNA from each of the rows and files of the two plates pinpointed one well in each plate with a cosmid bearing the targeted gene. Sequencing of cosmid subclones revealed a gene encoding a recently identified C. reinhardtii chloroplast carbonic anhydrase (CAH3). Transformations with chimeric constructs combining different portions of the wild-type and mutant genes indicated the presence of a mutation in the 5'-half of the gene. Comparison of mutant and wild-type gene sequences in this region revealed a G-to-A substitution in the mutant gene, which produced a nonsense codon. The data presented demonstrate that the carbonic anhydrase produced from the CAH3 gene is essential to the inorganic carbon-concentrating mechanism in C. reinhardtii and that genomic complementation can be a facile and efficient means for isolating genes associated with defects affecting photosynthesis and other physiological processes in this eukaryotic green alga.     

Cdk1-dependent regulation of the Mre11 complex couples DNA repair pathways to cell cycle progression

Homologous recombination (HR) and non-homologous end joining (NHEJ) are the main pathways ensuring the repair of DNA double-stranded breaks (DSBs) in eukaryotes. It has long been known that cell cycle stage is a major determinant of the type of pathway used to repair DSBs in vivo. However, the mechanistic basis for the cell cycle regulation of the DNA damage response is still unclear. Here we show that a major DSB sensor, the Mre11–Rad50–Xrs2 (MRX) complex, is regulated by cell cycle-dependent phosphorylation specifically in mitosis. This modification depends on the cyclin-dependent kinase Cdc28/Cdk1, and abrogation of Xrs2 and Mre11 phosphorylation results in a marked preference for DSB repair through NHEJ. Importantly, we show that phosphorylation of the MRX complex after DNA damage and during mitosis are regulated independently of each other by Tel1/ATM and Cdc28/Cdk1 kinases. Collectively, our results unravel an intricate network of phosphoregulatory mechanisms that act through the MRX complex to modulate DSB repair efficiency during mitosis.     

Inhibition of Polo-like kinase-1 by DNA damage occurs in an ATM- or ATR-dependent fashion

Polo-like kinases play multiple roles in different phases of mitosis. We have recently shown that the mammalian polo-like kinase, Plk1, is inhibited in response to DNA damage and that this inhibition may lead to cell cycle arrests at multiple points in mitosis. Here we have investigated the role of the checkpoint kinases ATM (ataxia telangiectasia mutated) and ATR (ATM- and Rad3-related) in DNA damage-induced inhibition of Plk1. We show that inhibition of Plk1 kinase activity is efficiently blocked by the radio-sensitizing agent caffeine. Using ATM(-/-) cells we show that under certain circumstances, inhibition of Plk1 by DNA-damaging agents critically depends on ATM. In addition, we show that UV radiation also causes inhibition of Plk1, and we present evidence that this inhibition is mediated by ATR. Taken together, our data demonstrate that ATM and ATR can regulate Plk1 kinase activity in response to a variety of DNA-damaging agents.     

Genetic analysis of DNA repair in Aspergillus: evidence for different types of MMS-sensitive hyperrec mutants

To identify genes which affect DNA repair and possibly recombination in Aspergillus nidulans, mutants hypersensitive to methyl methanesulphonate (MMS) were induced with ultraviolet light (UV) or gamma-rays. About half of them contained associated translocations and many were hypersensitive to UV and/or defective in meiosis. Two are alleles of the known uvsB gene while most others define new genes. In addition, among available uvs mutants many were found to be MMS-sensitive. Some of the various uncharacterized ones were identified as alleles of known uvs, but 5 of them were mapped in 2 new genes, uvsH and uvsJ. To identify functional and epistatic groups, mutants from each uvs gene were tested for effects on recombination and mutation, and double mutant uvs strains were compared for UV survival to their component single mutant strains. 3 epistatic pairs were identified, (1) uvsF and H, (2) uvsB and D, and (3) uvsC and E. Conclusive interpair tests were difficult, because such double mutant combinations were frequently lethal or nearly so. The first pair, uvsF and H, shared some of the properties of excision-defective mutants, both uvs being very highly sensitive to UV for mutation as well as survival. But unlike such mutants, uvsH was also sensitive to gamma-rays and defective in meiosis. Both uvs showed normal levels of meiotic recombination, but greatly increased spontaneous mitotic crossing-over, being the most "hyperrec" types among all uvs. The second pair, uvsB and uvsC, which was similarly hyperrec showed only slight increases of UV-induced mutation (less than 2-fold). As a main effect, these uvs caused very high frequencies of unbalanced, unstable segregants from diploid conidia (30 X), but few of these were recognizable aneuploids. The third pair, uvsC and E, which are known to be rec- for gene conversion, caused reduced mitotic crossing-over in diploids and increased levels of haploid segregants. These mutants are spontaneous mutators, but showed less UV-induced mutation than wild-type controls.     

The role of Cdc25 phosphatases in cell cycle checkpoints

Summary The major driving forces in the eukaryotic cell cycle are the cyclin-dependent kinases (Cdk). Cdks can be activated through dephosphorylation of inhibitory phosphorylations catalyzed by the Cdc25 phosphatase family. In higher-eukaryotic cells, there exist three Cdc25 family members, Cdc25A, Cdc25B, and Cdc25C. While Cdc25A plays a major role at the G₁-to-S phase transition, Cdc25B and C are required for entry into mitosis. The regulation of Cdc25C is crucial for the operation of the DNA-damage checkpoint. Two protein kinases, Chk1 and Cds1, can be activated in response to DNA damage or in the presence of unreplicated DNA. Chk1 and Cds1 may phosphorylate Cdc25C to prevent entry into mitosis through inhibition of Cdc2 (Cdk1) dephosphorylation.