DNA Lesions Induced by Replication Stress Trigger Mitotic Aberration and Tetraploidy Development

During tumorigenesis, cells acquire immortality in association with the development of genomic instability. However, it is still elusive how genomic instability spontaneously generates during the process of tumorigenesis. Here, we show that precancerous DNA lesions induced by oncogene acceleration, which induce situations identical to the initial stages of cancer development, trigger tetraploidy/aneuploidy generation in association with mitotic aberration. Although oncogene acceleration primarily induces DNA replication stress and the resulting lesions in the S phase, these lesions are carried over into the M phase and cause cytokinesis failure and genomic instability. Unlike directly induced DNA double-strand breaks, DNA replication stress-associated lesions are cryptogenic and pass through cell-cycle checkpoints due to limited and ineffective activation of checkpoint factors. Furthermore, since damaged M-phase cells still progress in mitotic steps, these cells result in chromosomal mis-segregation, cytokinesis failure and the resulting tetraploidy generation. Thus, our results reveal a process of genomic instability generation triggered by precancerous DNA replication stress.     

Characterization of cysteine protease induced by oxidative stress in cells of Chlamydomonas sp. strain W80

Unlike known Chlamydomonas species, Chlamydomonas sp. strain W80, which was isolated from seawater, shows tolerance to salt and cadmium. In this study, we purified and characterized cysteine protease from Chlamydomonas sp. strain W80 cells and also investigated their response to oxidative stress. The protease was purified 2760-fold with a yield of 2.6% by five steps of successive chromatography. This protease had a pH optimum of 8.0 and was specific only for tert -butoxycarbonyl (Boc)-Leu-Arg-Arg-4-methylcoumaryl-7-amide (MCA) (Boc-LRR-MCA) and Boc-Val-Leu-Lys-MCA as substrates among eight fluorogenic peptides tested. The K _m value was estimated to be 44.4 μ M for Boc-LRR-MCA. The molecular weight of the protease was determined to be approximately 102 kDa by Superdex 200 gel filtration and 60 kDa by SDS–PAGE, suggesting that this enzyme is a dimer. This enzyme was inhibited by the cysteine protease inhibitors leupeptin and N-ethylmaleimide but neither inhibited by phenylmethylsulfonyl fluoride or ethylenediaminetetraacetic acid nor activated by metal cations. These findings indicate that this enzyme is likely a cysteine protease. When strain W80 was grown under oxidative stress in the presence of methyl viologen and cadmium chloride, cysteine protease activity was about 30–90% higher than normal, whereas no changes were observed in carbon enrichment or senescence. It is likely that this protease is upregulated in response to oxidative stress and plays a role in the maintenance of cell metabolism under oxidative stress conditions.     

A rice dihydrosphingosine C4 hydroxylase (DSH1) gene, which is abundantly expressed in the stigmas, vascular cells and apical meristem, may be involved in fertility

Dihydrosphingosine C4 hydroxylase is a key enzyme in the biosynthesis of phytosphingosine, a major constituent of sphingolipids in plants and yeasts. The rice genome contains five homologue genes for dihydrosphingosine C4 hydroxylase, DSH1-DSH5, whose gene products show high degrees of homology to the yeast counterpart, SUR2. Among them, expression of DSH1, DSH2 and DSH4 was detected, and DSH1 and DSH4 complement the yeast sur2 mutation. The DSH1 gene was specifically and abundantly expressed in vascular bundles and apical meristems. In particular, very strong expression was detected in the stigmas of flowers. Repression of DSH1 expression by the antisense gene or RNA interference (RNAi) resulted in a severe reduction of fertility. In the transformants in which DSH1 expression was suppressed, significantly increased expression of DSH2 was found in leaves but not in pistils, suggesting that there was tissue-specific correlation between DSH1 and DSH2 expression. Our results indicate that the product of DSH1 may be involved in plant viability or reproductive processes, and that the phenotype of sterility is apparently caused by loss of function of DSH1 in the stigma. It is also suggested that there is a complex mechanism controlling the tissue-specific expression of the DSH1 gene.     

IL-28 elicits antitumor responses against murine fibrosarcoma

IL-28 is a recently described antiviral cytokine. In this study, we investigated the biological effects of IL-28 on tumor growth to evaluate its antitumor activity. IL-28 or retroviral transduction of the IL-28 gene into MCA205 cells did not affect in vitro growth, whereas in vivo growth of MCA205IL-28 was markedly suppressed along with survival advantages when compared with that of controls. When the metastatic ability of IL-28-secreting MCA205 cells was compared with that of controls, the expression of IL-28 resulted in a potent inhibition of metastases formation in the lungs. IL-28-mediated suppression of tumor growth was mostly abolished in irradiated mice, indicating that irradiation-sensitive cells, presumably immune cells, are primarily involved in the IL-28-induced suppression of tumor growth. In vivo cell depletion experiments displayed that polymorphonuclear neutrophils, NK cells, and CD8 T cells, but not CD4 T cells, play an equal role in the IL-28-mediated inhibition of in vivo tumor growth. Consistent with these findings, inoculation of MCA205IL-28 into mice evoked enhanced IFN-gamma production and cytotoxic T cell activity in spleen cells. Antitumor action of IL-28 is partially dependent on IFN-gamma and is independent of IL-12, IL-17, and IL-23. IL-28 increased the total number of splenic NK cells in SCID mice and enhanced IL-12-induced IFN-gamma production in vivo and expanded spleen cells in C57BL/6 mice. Moreover, IL-12 augmented IL-28-mediated antitumor activity in the presence or absence of IFN-gamma. These findings indicate that IL-28 has bioactivities that induce innate and adaptive immune responses against tumors.     

Discoidin domain of Del1 protein contributes to its deposition in the extracellular matrix

The extracellular matrix (ECM) acts as a critical factor during morphogenesis. Because the organization of the ECM directly influences the structure of tissues and organs, a determination of the way that ECM organization is regulated should help to clarify morphogenesis. We have analyzed the assembly of Del1, an ECM protein produced by endothelial cells in embryos, in the ECM. Del1 consists of three epidermal growth factor repeats (E1–E3) at its N-terminus and two discoidin domains (C1, C2) at its C-terminus. Experiments with various deletion mutants of Del1 have revealed that fragments containing the C-terminus of C1, which has a lectin-like structure, direct deposition in the ECM. The efficiency of deposition varies according to the presence of other domains in Del1. A fragment containing E3 and C1 has the strongest deposition activity, whereas fragments containing C2, which is highly homologous to C1, have low deposition activity. Digestion of ECM with hyaluronidase from bovine testis releases Del1 from the ECM, suggesting that glycosaminoglycans are involved in the deposition of Del1. In vivo gene transfer experiments have shown that fusion with the deposition domain of Del1 dramatically alters the distribution of exogenous proteins in mice. Thus, the extent of Del1 deposition may modify the organization of the ECM.     

Crucial structural factors and mode of action of polyene amides as inhibitors for mitochondrial NADH-ubiquinone oxidoreductase (complex I)

Natural antibiotic polyene amides such as myxalamides are potent inhibitors of mitochondrial complex I. Because of the significant instability of this series of compounds due to an extended pi-conjugation skeleton, a detailed characterization of their inhibitory action has not been performed. To elucidate the action mechanism as well as binding manner of polyene amides with complex I, identification of the roles of each functional group in the inhibitory action is needed. We here synthesized a series of amide analogues and carried out structure-activity studies with bovine heart mitochondrial complex I. With respect to the left-hand portion, the natural pi-conjugation skeleton common to many natural products is not required for the inhibition and can be substituted with a simpler substructure such as a conjugated diene. The geometry and shape of the left-hand portion were shown to be important for the inhibition, suggesting that this portion may bind to a narrow hydrophobic pocket in the enzyme rather than merely partitioning into the lipid membrane phase. Concerning the right-hand portion of the inhibitor, the presence of the 2-methyl, amide NH, and (S)-1'-methyl groups was crucial for the activity, suggesting that both methyl groups neighboring the amide group finely adjust the hydrogen-bonding ability of the amide group. In contrast, modifications of the 2'-OH group did not significantly influence the activity, suggesting that the role of this functional group is not to serve as a hydrogen bond donor to the enzyme but to act as a hydrophilic anchor directing the right-hand portion at or near the membrane surface. Detailed characterization of the action mechanism indicated that the polyene amides share a common binding domain with other complex I inhibitors, though their binding position (or manner) within the domain may differ considerably from that of other inhibitors.