Takako Takanami

Caenorhabditis elegans Chk2-like gene is essential for meiosis but dispensable for DNA repair

A Chk2‐like gene was identified in the genome of Caenorhabditis elegans. The putative gene product, termed Ce‐chk‐2 consists of 450 amino acid residues, and shows good homology with the Chk2/Cds1 gene family. The results of RNA‐mediated interference (RNAi) indicated that the F1 generation from dsRNA injected animals grew to adulthood, but approximately 95% of their eggs (F2) died during early embryogenesis. Among the few surviving progeny, males (XO animals) arose at an abnormally high frequency (30%). In addition, 12 univalents were observed in full grown oocytes of the F1, while six bivalents were normally observed in wild‐type oocytes. Ce‐chk‐2 gene expression increased in the adult stage, and their expression level decreased in the glp‐4 mutant, which is defective in germ line proliferation. The radiation sensitivity of F1 embryos carrying Ce‐chk‐2 RNAi was not significantly affected.

Characterization of Ce-atl-1, an ATM-like gene from Caenorhabditis elegans

Abstract An ATM-like gene was identified in the genome of Caenorhabditis elegans. The putative product of the gene, termed Ce-atl-1 (C. elegans ATM-like 1) consists of 2514 amino acid residues. The C-terminal sequence, which contains a PI-3 kinase-like domain, showed good homology with the products of the gene MEC1/ESR1 from budding yeast, the rad3+ gene of fission yeast and mammalian ATR (ataxia-telangiectasia and rad3+ related) genes. The results of RNA-mediated interference indicated that the major phenotype associated with repression of Ce-atl-1 was lethality (approximately 50–80%) during early embryogenesis. Among the surviving progeny, males (XO animals) arose at a high frequency (2–30%). In addition, 5% of oocyte chromosomes demonstrated aneuploidy due to a defect in pre-meiotic chromosomal segregation. Gene expression analyses indicated that Ce-atl-1 mRNA was expressed in all larval stages and that its level increased about fivefold in the adult stage. The adult expression level was decreased in the glp-4 mutant, which is defective in germ line proliferation. Ce-atl-1 was strongly expressed in both the mitotic and meiotic cells of adult gonads. In summary, Ce-atl-1 appears to be important for early embryogenesis, and loss of its function results in a defect in chromosome segregation, similar to what has been observed for AT-related proteins.

Localization of X-ray cross complementing gene 1 protein in the nuclear matrix is controlled by casein kinase II-dependent phosphorylation in response to oxidative damage

Base excision repair/single strand break repair (BER/SSBR) of damaged DNA is a highly efficient process. X-ray cross complementing protein 1 (XRCC1) functions as a key scaffold protein for BER/SSBR factors. Recent work has shown that XRCC1 forms dense foci at sites of DNA damage in a manner dependent on casein kinase II (CK2) phosphorylation. To investigate the mechanism underlying foci formation, we analyzed the subnuclear localization and phosphorylation status of XRCC1 during the repair process by biochemical fractionation of HeLa cellular proteins. The localization was also verified by in situ extraction of the fixed cells. In unchallenged cells, XRCC1 was primarily found in the chromatin fraction in a highly phosphorylated form; in addition, a minor population (10-15%) existed in the nuclear matrix (NM) with no or marginal phosphorylation. After hydrogen peroxide treatment, hyperphosphorylated XRCC1 appeared in the NM and accordingly, those in the chromatin fraction decreased. Foci formation and changes in XRCC1 distribution could be abolished by the knockdown of CK2, the expression of a non-phosphorylatable version of XRCC1, or the inhibition of poly-ADP ribosylation at the damage sites. Other BER factors, like DNA polymerase beta, were also found to accumulate in the NM after hydrogen peroxide-induced DNA damage, although its association with the NM seemed relatively weak. Our results suggest that the constitutive phosphorylation of XRCC1 in the chromatin and its DNA damage-induced recruitment to the NM are critical for foci formation, and that the core reactions of BER/SSBR may occur in the NM.

The effect of high strength static magnetic fields and ionizing radiation on gene expression and DNA damage in Caenorhabditis elegans.

Magnetic resonance imaging with high static magnetic fields (SMFs) has become widely used for medical imaging purposes because SMFs cause fewer genotoxic side effects than ionizing radiation (IR). However, the effect of exposure to high SMFs on global transcription is little understood. We demonstrate that genes involved in motor activity, actin binding, cell adhesion, and cuticles are transiently and specifically induced following exposure to 3 or 5 T SMF in the experimental model metazoan Caenorhabditis elegans. In addition, transient induction of hsp12 family genes was observed after SMF exposure. The small-heat shock protein gene hsp16 was also induced but to a much lesser extent, and the LacZ-stained population of hsp-16.1::lacZ transgenic worms did not significantly increase after exposure to SMFs with or without a second stressor, mild heat shock. Several genes encoding apoptotic cell-death activators and secreted surface proteins were upregulated after IR, but were not induced by SMFs. Real-time quantitative RT-PCR analyses for 12 of these genes confirmed these expression differences between worms exposed to SMFs and IR. In contrast to IR, exposure to high SMFs did not induce DNA double-strand breaks or germline cell apoptosis during meiosis. These results suggest that the response of C. elegans to high SMFs is unique and capable of adjustment during long exposure, and that this treatment may be less hazardous than other therapeutic tools.

Caenorhabditis elegans Ce-rdh-1/rad-51 functions after double-strand break formation of meiotic recombination.

During meiotic prophase 1, homologous recombination is accompanied by dynamic chromosomal changes. The Ce-rdh-1/rad-51 gene is the only bacterial recA-like gene in the nematode C. elegans genome. Upon depletion of Ce-rdh-1/rad-51 using the RNA interference method, abnormal ‘kinked’ chromosomes can be observed in mature oocytes at diakinesis, whereas synapsis between homologous chromosomes during the pachytene stage is normal. Following fertilization, Ce-rdh-1/rad-51-depleted embryos die early in embryogenesis, and their nuclei exhibit abnormal chromosome fragments and bridges. From epistasis analyses with Ce-spo-11 defective mutant and ionizing radiation, it is indicated that Ce-rdh-1/rad-51 functions after double-strand break (DSB) formation of meiotic recombination. Under the Ce-chk-2 defective condition, whose meiotic synapsis and meiotic recombination between homologous chromosomes are completely inhibited, the Ce-rdh-1/rad51 is normally expressed in the gonadal cells. Moreover, it seems that exogenous DSBs in the Ce-chk-2 defective nuclei at the pachytene stage can be repaired between sister chromatids in a Ce-rdh-1/rad-51-dependent manner. These results indicate that Ce-rdh-1/rad51 functions after both endogenous and exogenous DSB formation during meiosis, but not as ‘pairing centers’ for meiotic synapsis.

Maintenance of Mitochondrial DNA by the Caenorhabditis elegans ATR Checkpoint Protein ATL-1

Here we show that inactivation of the ATR-related kinase ATL-1 results in a significant reduction in mitochondrial DNA (mtDNA) copy numbers in Caenorhabditis elegans. Although ribonucleotide reductase (RNR) expression and the ATP/dATP ratio remained unaltered in atl-1 deletion mutants, inhibition of RNR by RNAi or hydroxyurea treatment caused further reductions in mtDNA copy number. These results suggest that ATL-1 functions to maintain mtDNA independently of RNR.

Caenorhabditis elegans ATR checkpoint kinase ATL-1 influences life span through mitochondrial maintenance.

ATR is highly conserved in all eukaryotes and functions as a cell-cycle nuclear checkpoint kinase. In mammals, ATR is essential whose complete absence results in early embryonic lethality and its hypomorphic mutation causes a complex disease known as Seckel syndrome. However, molecular mechanisms that cause a wide variety of symptoms including accelerated aging have remained unclear. Similarly, in the nematode Caenorhabditis elegans, a deletion mutant of ATR ortholog atl-1 appears to develop into normal adults, but their eggs do not hatch and die at early embryogenesis. Here we show that the parental worms of atl-1 defective mutant achieved longevity. Transcription levels of certain superoxide dismutase genes, sod-3 and -5 and enzymatic activity of superoxide dismutases significantly increased in the mutant. Furthermore, lipid peroxidation such as a formation of malondialdehyde was attenuated. Expressions of other genes regulated by DAF-16/FOXO transcription factor were also altered. In contrast, the mutant became hypersensitive to rotenone and ethidium bromide. Compared with the wild type the mitochondrial DNA copy number in the mutant was lesser and its proliferation is more severely inhibited in the presence of rotenone. These results suggest that C. elegans ATL-1 is involved not only in the nuclear checkpoint control but also in the mitochondrial maintenance, and its dysfunction activates mild oxidative stress response, resulting in an alteration of life span.

Over‐expression of ATR causes autophagic cell death

ATR is highly conserved in all eukaryotes and functions as a cell‐cycle checkpoint kinase to stabilize the nuclear genome. In addition, knockout mouse models indicate that ATR is essential for viability. Here, it is shown that moderate overproduction of ATR, but not of the other phosphatidylinositol 3′ kinase‐related kinases, ataxia‐telangiectasia‐mutated, mTOR and SMG‐1, and a downstream target p53, resulted in cell death. ATR over‐expression induced cellular vacuolization from 12 to 48 h after transfection, before cell death progression. A series of deletion analyses showed that overproduction of the N‐terminal HEAT repeat segments of ATR was sufficient for the induction of the vacuolization. Moreover, post‐transcriptional modification of LC3, a marker of autophagy, and autophagosomes with double membranes were evident in ATR‐overproducing cells. The vacuolization was also suppressed in autophagy‐deficient MCF7 cells. In addition, both cellular vacuolization and cell death were reduced by inhibition of Ras activity using farnesyl thiosalicylic acid. Conversely, neither inhibition of mTOR nor activation of the checkpoint system could be observed in the vacuolated cells. These results suggest that the Ras signaling pathway is involved in the autophagic response caused by ATR overproduction, and tight regulation of ATR protein expression is crucial for cell viability.

Innate Immune Genes Including a Mucin-Like Gene, mul-1, Induced by Ionizing Radiation in Caenorhabditis elegans

The effect of radiation on the intestine has been studied for more than one hundred years. It remains unclear, however, whether this organ uses specific defensive mechanisms against ionizing radiation. The infection with Pseudomonas aeruginosa (PA14) in Caenorhabditis elegans induces up-regulation of innate immune response genes. Here, we found that exposure to ionizing radiation also induces certain innate immune response genes such as F49F1.6 (termed mul-1), clec-4, clec-67, lys-1 and lys-2 in the intestine. Moreover, pre-treatment with ionizing radiation before seeding on PA14 lawn plate significantly increased survival rate in the nematode. We also studied transcription pathway of the mul-1 in response to ionizing radiation. Induction of mul-1 gene was highly dependent on the ELT-2 transcription factor and p38 MAPK. Moreover, the insulin/IGF-1 signal pathway works to enhance induction of this gene. The mul-1 gene showed a different induction pattern from the DNA damage response gene, ced-13, which implies that the expression of this gene might be triggered as an indirect effect of radiation. Silencing of the mul-1 gene led to growth retardation after treatment with ionizing radiation. We describe the cross-tolerance between the response to radiation exposure and the innate immune system.