Osmotic shock induces G1 arrest through p53 phosphorylation at Ser33 by activated p38MAPK without phosphorylation at Ser15 and Ser20.

Osmotic shock induced transient stabilization of p53, possibly due to increased degradation of Mdm2. Stabilized p53 was activated by p38(MAPK), resulting in G(1) arrest through induction of p21(WAF1). Among the postulated phosphorylation sites involved in p53 stabilization or activation (Ser(15), Ser(20), Ser(33), and Ser(46)), only Ser(33) was phosphorylated. Furthermore, interaction of p53 with the transcriptional coactivator p300 was induced, and Lys(382) of p53 was acetylated. Although inhibition of p38(MAPK) did not prevent nuclear accumulation of p53, phosphorylation of Ser(33) was markedly suppressed by SB203580, a specific inhibitor of p38(MAPK). Under these conditions, acetylation of Lys(382) and induction of p21(WAF1) were also inhibited, and cells with elevated levels of p53 showed normal cell cycle progression. Activated p38(MAPK) phosphorylated endogenous p53 at Ser(33) in living cells. In stable transformants expressing dominant negative MKK6, an upstream protein kinase of p38(MAPK), p53 stabilization was induced normally following osmotic shock, but phosphorylation of Ser(33), acetylation of Lys(382), and induction of p21(WAF1) were almost completely inhibited. These results suggest that phosphorylation at Ser(33) by p38(MAPK) is critical for activation of p53 following osmotic shock. Phosphorylation of neither Ser(15) nor Ser(20) was needed in this activation.

Characterization and tumorigenicity of human ovarian surface epithelial cells immortalized by SV40 large T antigen.

OBJECTIVES: Epithelial ovarian cancers are considered to arise from neoplastic transformation of the ovarian surface epithelium (OSE). However, the earliest events in ovarian carcinogenesis have not been clearly defined because patients are often diagnosed in the advanced stages and useful in vivo and in vitro experimental systems using human OSE cells are lacking. We aimed to improve the availability of experimental models for the study of human ovarian carcinogenesis. METHODS: Subcultured human OSE cells were transfected with SV40 large T antigen. Resulting OSE cell lines were characterized using immunocytochemistry and tested tumorigenicity. RESULTS: Six immortalized OSE cell lines were obtained. All cell lines essentially retained the original morphological features of normal OSE cells and showed higher proliferation rates and saturation density. Although they were all nontumorigenic in athymic mice, OSE2b-2 sv cells, which were selected in soft agar from colonies of an SV40 large T antigen-expressing transfectant, OSE2b sv, produced tumors on the peritoneal surface, mesothelium, and diaphragm and induced ascites after being injected intraperitoneally. Solid tumors also grew when mice were inoculated subcutaneously. The tumor cells were formed in a solid sheet arrangement and no evidence of glandular or squamous differentiation was present. They were weakly immunostained with an antibody against cytokeratin, and intercellular junctions resembling attachment devices were ultrastructurally present between cells. The tumors were histologically diagnosed as undifferentiated carcinomas. CONCLUSIONS: The established cell lines may provide a model system to investigate the mechanisms of cytogenic and molecular changes from normal OSE cells through the various steps of transformation.

Xeroderma pigmentosum variant heterozygotes show reduced levels of recovery of replicative DNA synthesis in the presence of caffeine after ultraviolet irradiation.

Patients with xeroderma pigmentosum variant show clinical photosensitivity, skin neoplasias induced by ultraviolet light, and defective postreplication repair, but normal nucleotide excision repair. We recently reported an alternative, simple method for the diagnosis of xeroderma pigmentosum variant that measures by autoradiography three cellular markers for DNA repair after ultraviolet irradiation: unscheduled DNA synthesis, recovery of RNA synthesis, and recovery of replicative DNA synthesis. Among hereditary photosensitive disorders, including other xeroderma pigmentosum groups, Cockayne syndrome, and a newly established ultraviolet-sensitive syndrome, only xeroderma pigmentosum variant cells exhibited normal unscheduled DNA synthesis, normal recovery of RNA synthesis, but reduced recovery of replicative DNA synthesis (51 +/- 6% the rate relative to normal controls). This reduction of recovery of replicative DNA synthesis was enhanced in the presence of a nontoxic level of caffeine to 36 +/- 5%. In this study we assess the cellular markers in two independent families that included two photosensitive patients that were identified as xeroderma pigmentosum variant. Cells from heterozygotic parents showed normal levels of unscheduled DNA synthesis, recovery of RNA synthesis, and recovery of replicative DNA synthesis, but reduced rates of recovery of replicative DNA synthesis in the presence of 1 mM caffeine (53 +/- 8% relative to the normal control). Furthermore, with a colony-forming assay, the cells showed normal survival by ultraviolet without caffeine, but slightly reduced survival by ultraviolet with 1 mM caffeine present. In one family, we confirmed inheritance of two heterozygous mis-sense mutations. One mutation is an A-->G transition at nucleotide 1840 that generates a K535E mis-sense mutation. Another mutation is an A-->C transversion at nucleotide 2003 that generates a K589 mis-sense mutation. Each of these mutations were absent in 52 unrelated Japanese individuals. These results suggest that xeroderma pigmentosum variant heterozygotes can be identified by their sensitivity to ultraviolet irradiation in the presence of nontoxic levels of caffeine.

Dysfunction of human Rad18 results in defective postreplication repair and hypersensitivity to multiple mutagens.

Postreplication repair functions in gap-filling of a daughter strand on replication of damaged DNA. The yeast Saccharomyces cerevisiae Rad18 protein plays a pivotal role in the process together with the Rad6 protein. Here, we have cloned a human homologue of RAD18, hRAD18. It maps on chromosome 3p24-25, where deletions are often found in lung, breast, ovary, and testis cancers. In vivo, hRad18 protein binds to hHR6 protein through a conserved ring-finger motif. Stable transformants with hRad18 mutated in this motif become sensitive to UV, methyl methanesulfonate, and mitomycin C, and are defective in the replication of UV-damaged DNA. Thus, hRAD18 is a functional homologue of RAD18.

Reinvestigation of the classification of five cell strains of xeroderma pigmentosum group E with reclassification of three of them.

Xeroderma pigmentosum is a photosensitive syndrome caused by a defect in nucleotide excision repair or postreplication repair. Individuals of xeroderma pigmentosum group E (xeroderma pigmentosum E) have a mild clinical form of the disease and their cells exhibit a high level of nucleotide excision repair as measured by unscheduled DNA synthesis, as well as biochemical heterogeneity. Cell strains from one group of xeroderma pigmentosum E patients have normal damage-specific DNA binding activity (Ddb+), whereas others do not (Ddb-). Using a refinement of a previously reported cell fusion complementation assay, the previously assigned Ddb+ xeroderma pigmentosum E strains, XP89TO, XP43TO, and XP24KO, with various phenotypes in DNA repair markers, were reassigned to xeroderma pigmentosum group F, xeroderma pigmentosum variant, and ultraviolet-sensitive syndrome, respectively. The Ddb- xeroderma pigmentosum E strains, XP82TO, and GM02415B, which showed almost normal cellular phenotypes in DNA repair markers, however, remained assigned to xeroderma pigmentosum group E. With the exception of the Ddb+ strain XP89TO, which demonstrated defective nucleotide excision repair, both Ddb- and Ddb+ xeroderma pigmentosum E cells exhibited the same levels of variation in unscheduled DNA synthesis that were seen in normal control cells. By genome DNA sequencing, the two Ddb- xeroderma pigmentosum E strains were shown to have mutations in the DDB2 gene, confirming previous reports for XP82TO and GM02415B, and validating the classification of both cells. As only the Ddb- strains investigated remain classified in the xeroderma pigmentosum E complementation group, it is feasible that only Ddb- cells are xeroderma pigmentosum E and that mutations in the DDB2 gene are solely responsible for the xeroderma pigmentosum E group.

Human damage-specific DNA-binding protein p48. Characterization of XPE mutations and regulation following UV irradiation.

Damage-specific DNA binding (DDB) activity purifies from HeLa cells as a heterodimer (p127 and p48) and is absent from cells of a subset (Ddb(-)) of xeroderma pigmentosum Group E (XPE) patients. Each subunit was overexpressed in insect cells and purified. Both must be present for the damaged DNA band shift characteristic of the HeLa heterodimer. However, overexpressed p48 peptides containing the mutations found in three Ddb(-) XPE strains are inactive, and wild type p48 restores DDB activity to extracts from a fourth XPE Ddb(-) strain, GM01389, in which compound heterozygous mutations in DDB2 (p48) lead to a L350P change from one allele and a Asn-349 deletion from the other. Although these results indicate that these mutations are each responsible for the loss of DDB activity, they do not affect nuclear localization of p48. In normal fibroblasts, a 4-fold increase in p48 mRNA amount was observed 38 h after UV irradiation, preceding a similar elevation in p48 protein and DDB activity at 48 h, implying that p48 limits DDB activity in vivo. Because DNA repair is virtually complete before 48 h, a role for DDB other than DNA repair is suggested.

UVs syndrome: establishment and characterization of fibroblastic cell lines transformed with simian virus 40 DNA.

Ultraviolet-sensitive syndrome (UVsS) is a newly established photosensitive disorder. Patients with UVsS showed mild clinical manifestations similar to classical types of xeroderma pigmentosum, and had biochemical phenotypes of Cockayne syndrome but not those of xeroderma pigmentosum. Fibroblasts from a UVsS patient were treated with simian virus 40 DNA containing the large T antigen with a defective origin of DNA replication to establish a transformed cell line. We obtained two independent transformed cell lines (Kps3SVY and Kps3SVI3) and report their initial characterization. These cells showed the same pattern in variable number of tandem repeat analyses as a primary fibroblast cell strain, Kps3, and retain the UVsS phenotype as demonstrated by increased UV sensitivity (three to four times more sensitive to UV than normal cells) and by reduced recovery of RNA synthesis after UV irradiation (20% - 30% of that of normal cells). These cells, however, showed different phenotypes as regards plating efficiency, doubling time, and transfection efficiency in spite of the fact that the same method was used to transform the cells. Kps3SVY cells were closer in phenotype to Kps3 cells than Kps3SVI3 cells. As a variable number of tandem repeat analyses also showed that Kps3SVI3 cells have lost one of the two alleles in some chromosomes, this may explain the different phenotypes between Kps3SVY and Kps3SVI3 cells. Moreover, these cells were distinct from cells with Cockayne syndrome group A or B. Thus, these cell lines provide the opportunity to conduct transfection studies on cells with the UVsS defect in DNA repair and transcription.

A newly identified patient with clinical xeroderma pigmentosum phenotype has a non-sense mutation in the DDB2 gene and incomplete repair in (6-4) photoproducts.

We report here a patient (Ops1) with clinical photosensitivity, including pigmented or depigmented macules and patches, and multiple skin neoplasias (malignant melanomas, basal cell carcinomas, and squamous cell carcinomas in situ) in sun-exposed areas. These clinical features are reminiscent of xeroderma pigmentosum. As cells from Ops1 showed normal levels in DNA repair synthesis in vivo (unscheduled DNA synthesis and recovery of RNA synthesis after ultraviolet irradiation), we performed a postreplication repair assay and recovery of replicative DNA synthesis after ultraviolet irradiation to investigate if Ops1 cells belonged to a xeroderma pigmentosum variant pattern. Ops1 cells were normal, but there was an incomplete pattern repair in (6-4) photoproducts in contrast to a normal pattern repair in cis-syn cyclobutane pyrimidine dimers by repair kinetics using the enzyme-linked immunosorbent assay. Moreover, Ops1 cells were defective in a damage-specific DNA binding protein and carried a non-sense mutation in the DDB2 gene. These results suggest that (i) the DDB2 gene is somewhat related to skin carcinogenesis, photoaging skin, and the removal of (6-4) photoproducts; (ii) although it is believed that cyclobutane pyrimidine dimers are the principal mutagenic lesion and (6-4) photoproducts are less likely to contribute to ultraviolet-induced mutations in mammals, Ops1 is one of the ultraviolet-induced mutagenic models induced by (6-4) photoproducts.

Topostatin, a novel inhibitor of topoisomerases I and II produced by Thermomonospora alba strain No. 1520. III. Inhibitory properties.

A novel inhibitor of topoisomerases designated as topostatin was isolated from the culture filtrate of Thermomonospora alba strain No. 1520. The inhibitory activity of topostatin was shown to be pH- and temperature-dependent with a maximum around at pH 6 and 28 degrees C. The stability of topostatin decreased with decreasing pH and rising temperature. Topostatin inhibited topoisomerases I and II in a competitive manner with respect to DNA. The inhibitor also inhibited some restriction endonucleases such as Sca I, Hind III and Pst I, but not Alu I, Bam HI, Eco RI, RNase A, DNase I, DNase II and DNA ligase. Topostatin did not induce the nuclear accumulation of p53 protein by DNA damage in the normal human cells.

Requirement of ATM in phosphorylation of the human p53 protein at serine 15 following DNA double-strand breaks.

Microinjection of the restriction endonuclease HaeIII, which causes DNA double-strand breaks with blunt ends, induces nuclear accumulation of p53 protein in normal and xeroderma pigmentosum (XP) primary fibroblasts. In contrast, this induction of p53 accumulation is not observed in ataxia telangiectasia (AT) fibroblasts. HaeIII-induced p53 protein in normal fibroblasts is phosphorylated at serine 15, as determined by immunostaining with an antibody specific for phosphorylated serine 15 of p53. This phosphorylation correlates well with p53 accumulation. Treatment with lactacystin (an inhibitor of the proteasome) or heat shock leads to similar levels of p53 accumulation in normal and AT fibroblasts, but the p53 protein lacks a phosphorylated serine 15. Following microinjection of HaeIII into lactacystin-treated normal fibroblasts, lactacystin-induced p53 protein is phosphorylated at serine 15 and stabilized even in the presence of cycloheximide. However, neither stabilization nor phosphorylation at serine 15 is observed in AT fibroblasts under the same conditions. These results indicate the significance of serine 15 phosphorylation for p53 stabilization after DNA double-strand breaks and an absolute requirement for ATM in this phosphorylation process.

High sensitivity of the ultraviolet-induced p53 response in ultraviolet-sensitive syndrome, a photosensitive disorder with a putative defect in deoxyribonucleic acid repair of actively transcribed genes.

Previously, we reported a new category of photosensitive disorder named ultraviolet-sensitive syndrome (UVs S) [T. Itoh, T. Fujiwara, T. Ono, M. Yamaizumi, UVs syndrome, a new general category of photosensitive disorder with defective DNA repair, is distinct from xeroderma pigmentosum variant and rodent complementation group 1, Am. J. Hum. Genet. 56 (1995) 1267-1276.]. Cells derived from these patients show impaired recovery of RNA synthesis (RRS) after UV-irradiation irrespective of having a normal level of unscheduled DNA synthesis (UDS). These characteristics are reminiscent of Cockayne syndrome (CS) cells. By comparing sensitivity of the UV-induced p53 response in cells with different types of defects in nucleotide excision repair, we hypothesized that the UV-induced p53 response is triggered by inhibition of RNA synthesis [M. Yamaizumi, T. Sugano, UV-induced nuclear accumulation of p53 is evoked through DNA damage of actively transcribed genes independent of the cell cycle, Oncogene 9 (1994) 2775-2784.]. To test this hypothesis, we determined sensitivity of the p53 response in UVs S cells by immunostaining, Western blotting, and FACScan analysis. Maximal nuclear accumulation of p53 in the UVs S cells was observed with a one-third UV dose required for that in normal cells, while almost identical p53 responses were observed in UVs S and normal cells following treatment with heat or alpha-amanitin. Recovery of RNA synthesis after a low dose of UV-irradiation was impaired in UVs S cells to the same extent as seen in CS cells. These results provide further evidence to support our previous hypothesis regarding the mechanism of the p53 response induced by DNA damage.

Heat shock induces transient p53-dependent cell cycle arrest at G1/S.

Heat shock (43 degrees C, 45 min) induced transient nuclear accumulation of p53 in primary human fibroblasts without any clonogenically toxic effects. The accumulation of p53 reached a maximal level 3 approximately 5 h after heat shock, and returned to the basal level within 12 h. Following the increase in p53 level, cell cycle arrest at G1/S was observed in normal fibroblasts, whereas neither nuclear accumulation of p53 nor cell cycle arrest were observed in HeLa cells. By comparing cell cycle patterns of heat-treated mouse cells with different genotypes at the p53 locus (+/+, +/-, -/-), the observed cell cycle arrest at G1/S was demonstrated to be p53-dependent. Cell cycle arrest in normal human fibroblasts continued for nearly 24 h, resulting in a one day delay of cell growth compared with non-treated cells. Following enhancement of the p53 level, the amount of p21/WAF1/ CIP1 increased, and the high level of p21 was sustained for almost one day in a cell cycle-independent manner, suggesting the involvement of p21 in the inhibition of cell cycle progression by heat shock.

Visualization of mitochondrial protein import in cultured mammalian cells with green fluorescent protein and effects of overexpression of the human import receptor Tom20.

The presequence of the ornithine transcarbamylase precursor (pOTC) was fused to green fluorescent protein (GFP), yielding pOTC-GFP and pOTCN-GFP containing the presequence plus 4 and 58 residues of mature ornithine transcarbamylase, respectively. When GFP cDNA was transfected into COS-7 cells, the cytosol and nucleus were fluorescent. On the other hand, pOTC-GFP cDNA gave strong fluorescence of a unique mitochondrial pattern. After fractionation of cells expressing pOTC-GFP with digitonin, fluorescence was recovered mostly in the particulate fraction. Immunoblot analysis showed that processed GFP was present in the particulate fraction, whereas pOTC-GFP was recovered in both the soluble and particulate fractions. pOTC-GFP and pOTCN-GFP synthesized in vitro were imported efficiently into the isolated mitochondria. Single and triple amino acid mutations in the presequence resulted in impaired mitochondrial import and in a loss of mitochondrial fluorescence. Perinuclear aggregation of fluorescent mitochondria was observed when the human mitochondrial import receptor Tom20 (hTom20) was coexpressed with pOTC-GFP. Overexpression of hTom20 (not DeltahTom20, which lacks the anchor sequence) resulted in stimulated mitochondrial import of pOTC-GFP in COS-7 cells. When pOTC-GFP cDNA was microinjected into nuclei of human fibroblast cells, mitochondrial fluorescence was detected as early as 2-3 h after injection. These results show that GFP fusion protein can be used to visualize mitochondrial structures and to monitor mitochondrial protein import in a single cell in real time.

Cell cycle control is aberrant in Chinese hamster ovary cell mutants exhibiting apoptosis after serum deprivation.

We isolated mutants of Chinese hamster ovary cells that exhibit excessive apoptosis after serum deprivation. In the medium containing 10% serum, the growth rates of the mutants were 1.4 to 1.5-fold faster than those of wild-type cells. Whereas the cell cycle of wild-type cells was arrested at the G1 phase after serum deprivation, the cell cycle of the mutant cells was not fully arrested at this phase, suggesting that cell cycle regulation was disorganized in the mutants. The mutants were highly sensitive to a nucleotide-analogue 5-fluorouracil in the absence of serum, whereas wild-type cells were resistant to the drug. Based on the sensitivity to the drug after serum deprivation, we could classify the mutants into dominant groups and at least two recessive complementation groups. Thus, these mutants presumably contain different lesions in gene(s) required for cell cycle regulation and apoptosis.