RSa Cells Research Articles

The Involvement of Annexin II in Resistance to UVB-Induced Cell Death and in the Increased Nucleotide Excision Repair Capacity of UV-Damaged DNA in Human Cells

Annexin II, an HSP27-interacting protein, is involved in the protection of human cells against UVC. UVB is concerned with deleterious actions on human health. In this study, we attempted to confirm the anti-UVB effect of annexin II, and to elucidate the mechanisms underlying annexin II-involving UV resistance. The RSa cells were more sensitive to UVB lethality than the AP(r)-1 cells. Overproduction of annexin II in RSa cells resulted in increased resistance to UVB lethality, while annexin II siRNA-transfected AP(r)-1 cells were sensitized to UVB lethality. The excision capacity of the two major types (CPD and 6-4PP) of UVC- and UVB-damaged DNA in AP(r)-1 cells was greater than in RSa cells. The excision capacity of the RSa cells improved following upregulation of annexin II, while the capacity of the AP(r)-1 cells decreased after annexin II downregulation. Our results suggest that annexin II is involved in the UV resistance of human cells, via functioning in nucleotide excision repair.

Inhibition of cell viability by human IFN-β is mediated by microRNA-431

MicroRNAs (miRNAs) are small non-coding RNAs that inhibit gene expression by cleaving or hindering the translation of target mRNAs. We used microarray-based comparative transcriptome analysis to identify changes in miRNA expression and function between a human cell line, RSa, which is highly sensitive to HuIFN-β-mediated inhibition of cell viability, and its variant, the F-IFr cell line, which is relatively resistant to the cytokine. miR-431 expression was significantly higher in RSa cells compared with F-IFr cells. The addition of HuIFN-β to RSa cultures reduced cell viability, down-regulated expression of IGF1R and IRS2 (putative miR-431 target genes), and inhibited the PI3K-Akt and MAPK pathways. The survival of F-IFr cells was not reduced by HuIFN-β, but transient transfection with miR-431 precursors significantly decreased viability and concomitantly down-regulated IGF1R and IRS2 expression. In addition, the MAPK pathway, but not the PI3K-Akt pathway, was suppressed in F-IFr cells. Based on these results, we propose that, in RSa cells, HuIFN-β-induced miR-431 expression may down-regulate IGF1R and IRS2 expression, and consequently inhibit cell proliferation by suppressing the MAPK pathway.

UVC Mutagenicity Is Suppressed in Japanese Miso-Treated Human RSa Cells, PossiblyviaGRP78 Expression

Little is known about the ability of miso, to modulate mutability in human cells. We have observed increased levels of glucose-regulated protein 78 (GRP78) expression in association with suppression of mutation in human RSa cells irradiated with ultraviolet C (UVC). Here we examined to determine whether miso treatment results in increased GRP78 expression and suppression of UVC mutagenicity in RSa cells. Supernatants of water extracts of miso products and their components were tested. In the sample-treated cells, the amount of GRP78, as estimated by RT-PCR and immunoblotting analysis, increased, and the UVC-induced ouabain resistant mutation (Oua(R)) and the K-ras codon 12-base substitution mutation frequency decreased. This decrease was not observed in cells with downregulation of GRP78 by GRP78 siRNA transfection. The results suggest that miso suppresses UVC mutagenicity by increasing GRP78 expression in human cells.

The Roles of HSP27 and Annexin II in Resistance to UVC-Induced Cell Death: Comparative Studies of the Human UVC-Sensitive and -Resistant Cell Lines RSa and APr-1

We have reported that heat shock protein 27 (HSP27) and annexin II are involved in the protection of human cells against UVC-induced cell death. In this study we tried to confirm the combined roles of HSP27 and annexin II in cell death after UVC irradiation. In RSa cells with sensitivity to UVC, expression of annexin II decreased after UVC irradiation, but not in AP(r)-1 cells with increased resistance to UVC. HSP27 siRNA-transfected AP(r)-1 cells were sensitized to UVC lethality and showed decreased annexin II expression after UVC irradiation. In contrast, transfection of RSa cells with HSP27 cDNA increased their resistance to UVC lethality and caused increased annexin II expression. Furthermore, over-production of annexin II in RSa cells resulted in increased resistance to UVC lethality. This study indicates the involvement of cellular HSP27 expression in the UVC susceptibility of human cells, which occurs in association with regulation of annexin II expression.

Involvement of aldolase A in X-ray resistance of human HeLa and UV r-1 cells

To find novel proteins involved in radio-resistance of human cells, we searched for nuclear proteins, whose expression levels alter after X-ray irradiation in HeLa cells, using agarose fluorescent two-dimensional differential gel electrophoresis following mass spectrometry. We identified 6 proteins, whose levels were increased in nuclei 24 h after irradiation at 5 Gy, including aldolase A. Nuclear aldolase A levels increased twofold after the irradiation, however, total aldolase A levels did not change. When the expression of aldolase A was suppressed by its specific siRNA, sensitization of the suppressed cells to X-ray-induced cell death was observed. In addition, UV r-1 cells with higher aldolase A expression exhibited lower sensitivity to X-ray-induced cell death than the parental RSa cells with lower aldolase A expression. These results suggest that aldolase A may play a role in the radio-response of human cells, probably in nuclei, in addition to its glycolytic role in the cytosol.

Down-Regulation of Molecular Chaperone 78-kd Glucose-Regulated Protein/Immunoglobulin-Binding Protein Expression Involved in Enhancement of Human RS Cell Mutability

Enhancement of cell mutability via extracellular materials of cancer cells is a crucial event leading to the development of cancers; however, the activation process of mutability is still not well understood. In this study, to identify the regulatory mechanism of cell mutability, we investigated mutability modulated in response to human pancreatic cancer cell-conditioned medium and identified the candidates for cellular molecules involved in the mutability modulation. To test the mutation-modulating effects of the conditioned medium, human RS cells were cultured with medium derived by culturing human pancreatic cancer KP-4 cells, followed by irradiation with UV (mainly 254 nm in wavelength). Mutations were detected by phenotypic ouabain resistance and genetic base substitution of K-ras codon 12. Messenger RNA differential display was used to identify genes that were differentially expressed between conditioned medium-treated and mock-treated RSa cells. The influence of 78-kd glucose-regulated protein/immunoglobulin-binding protein (GRP78/BiP) expression on mutability was assessed by the down-regulation of GRP78/BiP using antisense oligonucleotides or antisense complementary DNA. The UV-induced mutagenicity in RS cells was strengthened by preculture with KP-4 cell-conditioned medium. Messenger RNA differential display revealed that GRP78/BiP expression was suppressed in RS cells after treatment of the conditioned medium. Furthermore, the level of UV-induced mutations was elevated significantly in GRP78/BiP down-regulated cells. Culture of human RS cells with pancreatic cancer KP-4 cell-conditioned medium resulted in increased UV mutagenicity, possibly via the down-regulation of GRP78/BiP.

Leupeptin‐sensitive proteases involved in cell survival after X‐ray irradiation in human RSa cells

Proteases have received attention as important cellular components responsible for stress response in human cells. However, little is known about the role of proteases in the early steps of cell response after X-ray irradiation. In the present study, we first searched for proteases whose activity levels are changed soon after X-ray irradiation in human RSa cells with a high sensitivity to X-ray cell-killing. RSa cells showed an increased level of fibrinolytic protease activity within 10 min after irradiation with X-ray (up to 3 Gy). The induced protease activity was proved to be inhibited by leupeptin. We next examined whether this protease inducibility is related to the X-ray susceptibility of cells. Treatment of RSa cells with leupeptin prior to X-ray irradiation resulted in lowered colony survival and an increased ratio of G(2)/M-arrested cells and apoptotic cells. These results suggest that leupeptin-sensitive proteases are involved in the resistance of human RSa cells to X-ray cell-killing.

Decreased cell survival and DNA repair capacity after UVC irradiation in association with down-regulation of GRP78/BiP in human RSa cells

In contrast to extensive studies on the roles of molecular chaperones, such as heat shock proteins, there are only a few reports about the roles of GRP78/BiP, an endoplasmic reticulum (ER) stress-induced molecular chaperone, in mammalian cell responses to DNA-damaging stresses. To investigate whether GRP78/BiP is involved in resistance to a DNA-damaging agent, UVC (principally 254 nm in wavelength), we established human cells with down-regulation of GRP78/BiP by transfection of human RSa cells with antisense cDNA for GRP78/BiP. We found that the transfected cells showed higher sensitivity to UVC-induced cell death than control cells transfected with the vector alone. In the antisense-cDNA transfected cells, the removal capacities of the two major types of UVC-damaged DNA (thymine dimers and (6–4) photoproducts) in vivo and DNA synthesis activity of whole cell extracts to repair UVC-irradiated plasmids in vitro were remarkably decreased compared with those in the control cells. Furthermore, the antisense-cDNA transfected cells also showed slightly higher sensitivity to cisplatin-induced cell death than the control cells. Cisplatin-induced DNA damage is primarily repaired by nucleotide excision repair, like UVC-induced DNA damage. The present results suggest that GRP78/BiP plays a protective role against UVC-induced cell death possibly via nucleotide excision repair, at least in the human RSa cells tested.

Enhanced Expression of Transferrin Receptor Confers UV-resistance in Human and Monkey Cells

One of the most intriguing biological subjects is cell-surface molecules that regulate the susceptibility of human cells to cell-killing effects after irradiation with far-ultraviolet light (UV, principally 254 nm wavelength). Human RSa cells have unusual sensitivity to UV-induced cell-killing. We searched for molecules on the cell-surface of RSa cells that were present in different amounts as compared to a variant of these cells, UV(r)-1 cells, which have increased resistance to UV cell-killing. Among the 21 molecules examined, the amount of transferrin receptor (TfR) protein was found to be 2-fold higher in UV(r)-1 cells compared with in RSa cells. The amounts of this protein were also higher in the UV-resistant hematopoietic cell lines, CEM6 and Daudi, as compared to the UV-sensitive cell lines, Molt4 and 697. Culturing of UV(r)-1 cells in a medium containing anti-transferrin antibodies resulted in sensitization of the cells to UV cell-killing as demonstrated by colony formation assay. Similar results were observed by treatment of the cells with TfR siRNA. In contrast, overexpression of TfR protein led to a resistance to UV cell-killing in RSa cells and monkey COS7 cells as demonstrated by both colony formation and apoptosis assay. In TfR-overexpressing cells, reduction of p53 and Bax protein was observed after UV-irradiation. Thus, TfR expression appears to be involved in the regulation of UV-resistance, possibly via modulation of the amount of p53 and Bax protein.

Involvement of Human Small Fragment Nuclease in the Resistance of Human Cells to UV‐C‐induced Cell Death¶

ABSTRACTHuman small fragment nuclease (Sfn) is one of the cellular proteins that were reported to degrade small, single‐stranded DNA and RNA. However, the biological role of Sfn in cellular response to various stressors such as UV‐C (mainly 254 nm wavelength ultraviolet ray) remains unclear. We have examined whether modulation of human SFN gene expression affects cell survival capacity against UV‐C‐induced cell death, analyzing colony survival ability in UV‐C‐sensitive human RSa cells treated with short double‐stranded RNA (siRNA) specific for SFN messenger RNA (mRNA). The expression levels of SFN mRNA in the siRNA‐treated RSa cells decreased to about 15% compared with those in the control siRNA‐treated cells. The siRNA‐treated RSa cells showed lower colony survival and higher activity of caspase‐3 after UV‐C irradiation than the control siRNA‐treated RSa cells. Furthermore, the removal capacity of cyclobutane pyrimidine dimers (CPD) in the siRNA‐treated RSa cells decreased compared with the control siRNA‐treated RSa cells. There was no difference in the colony survival and CPD removal capacity after UV‐C irradiation between the control siRNA‐treated RSa cells and mock‐treated RSa cells. These results suggest that SFN expression is involved in resistance of RSa cells to UV‐C‐induced cell death through the roles it plays in the DNA repair process.

Protective role of HSP27 against UVC-induced cell death in human cells

It is an intriguing problem whether heat shock proteins (HSPs) play a protective role in UVC-induced cell death in human cells, and the problem has not been solved. To search for the HSPs involved in UVC resistance, gene expression profiles using cDNA array were compared between UVC-sensitive human RSa cells and their UVC-resistant variant AP r-1 cells. The expression levels of heat shock protein 27 (HSP27) were lower in RSa cells than in AP r-1 cells. RSa cells transfected with sense HSP27 cDNA showed slightly lower sensitivity to UVC-induced cell death than the control cells transfected with a vector alone and much lower sensitivity than RSa cells transfected with the antisense HSP27 cDNA. Furthermore, the removal capacities of the two major types of UVC-damaged DNA (thymine dimers and (6-4)photoproducts) in the cells with the up-regulation of HSP27 were moderately elevated compared with those in the control cells, while those in the cells with down-regulation were remarkably suppressed. These results suggest that HSP27 is involved in the UVC-resistance of human cells, at least those tested, possibly via functioning in nucleotide excision repair.

Involvement of human small fragment nuclease in the resistance of human cells to UV-C-induced cell death.

Human small fragment nuclease (Sfn) is one of the cellular proteins that were reported to degrade small, single-stranded DNA and RNA. However, the biological role of Sfn in cellular response to various stressors such as UV-C (mainly 254 nm wavelength ultraviolet ray) remains unclear. We have examined whether modulation of human SFN gene expression affects cell survival capacity against UV-C-induced cell death, analyzing colony survival ability in UV-C-sensitive human RSa cells treated with short double-stranded RNA (siRNA) specific for SFN messenger RNA (mRNA). The expression levels of SFN mRNA in the siRNA-treated RSa cells decreased to about 15% compared with those in the control siRNA-treated cells. The siRNA-treated RSa cells showed lower colony survival and higher activity of caspase-3 after UV-C irradiation than the control siRNA-treated RSa cells. Furthermore, the removal capacity of cyclobutane pyrimidine dimers (CPD) in the siRNA-treated RSa cells decreased compared with the control siRNA-treated RSa cells. There was no difference in the colony survival and CPD removal capacity after UV-C irradiation between the control siRNA-treated RSa cells and mock-treated RSa cells. These results suggest that SFN expression is involved in resistance of RSa cells to UV-C-induced cell death through the roles it plays in the DNA repair process.

Involvement of Human Small Fragment Nuclease in the Resistance of Human Cells to UV-C–induced Cell Death¶

Human small fragment nuclease (Sfn) is one of the cellular proteins that were reported to degrade small, single-stranded DNA and RNA. However, the biological role of Sfn in cellular response to various stressors such as UV-C (mainly 254 nm wavelength ultraviolet ray) remains unclear. We have examined whether modulation of human SFN gene expression affects cell survival capacity against UV-C-induced cell death, analyzing colony survival ability in UV-C-sensitive human RSa cells treated with short double-stranded RNA (siRNA) specific for SFN messenger RNA (mRNA). The expression levels of SFN mRNA in the siRNA-treated RSa cells decreased to about 15% compared with those in the control siRNA-treated cells. The siRNA-treated RSa cells showed lower colony survival and higher activity of caspase-3 after UV-C irradiation than the control siRNA-treated RSa cells. Furthermore, the removal capacity of cyclobutane pyrimidine dimers (CPD) in the siRNA-treated RSa cells decreased compared with the control siRNA-treated RSa cells. There was no difference in the colony survival and CPD removal capacity after UV-C irradiation between the control siRNA-treated RSa cells and mock-treated RSa cells. These results suggest that SFN expression is involved in resistance of RSa cells to UV-C-induced cell death through the roles it plays in the DNA repair process.

Involvement of LEU13 in interferon-induced refractoriness of human RSa cells to cell killing by X rays.

Culture of human cells with human interferon alpha and beta (IFNA and IFNB) results in increased resistance of the cells to cell killing by X rays. To identify candidate genes responsible for the IFN-induced X-ray resistance, we searched for genes whose expression levels are increased in human RSa cells treated with IFNA, using an mRNA differential display method and Northern blotting analysis. RSa cells, which showed increased survival (assayed by colony formation) after X irradiation when they were treated with IFNA prior to irradiation, showed increased expression levels of LEU13 (IFITM1) mRNA after IFNA treatment alone. In contrast, IF(r) and F-IF(r) cells, both of which are derived from RSa cells, showed increased X-ray resistance and high constitutive LEU13 mRNA expression levels compared to the parental RSa cells. Furthermore, the IFNA-induced resistance of RSa cells to killing by X rays was suppressed by antisense oligonucleotides for LEU13 mRNA. LEU13, a leukocyte surface protein, was previously reported to mediate the actions of IFN such as inhibition of cell proliferation. The present results suggest a novel role of LEU13 different from that in the inhibition of cell proliferation, involved in IFNA-induced refractoriness of RSa cells to X rays.

Induction of apoptosis and ubiquitin hydrolase gene expression by human serum factors in the early phase of acute myocardial infarction

The physiologic events leading to apoptosis in myocardial infarction and the molecules involved in the death process have not been clarified unequivocally. We developed a method to search for serum factors that induce apoptosis of human cells, using serum obtained from patients within 1 day of the onset of acute myocardial infarction (AMI). Serum factors were found to have the ability to increase the caspase-3 activity levels in human RSa cells, which are susceptible to apoptosis inducers. The factors obtained from AMI patients by elution at about 0.5 mol/L KCl from a dye-ligand column were named AMI-SFs (serum factors from AMI). Electrophoretic analysis showed DNA fragmentation in AMI-SF-treated RSa cells, but not in RSa cells treated with fractions from AMI patients 1 week after clinical onset of illness. AMI-SF-induced DNA fragmentation was also demonstrated by terminal deoxynucleotidyl transferase-mediated deoxyuridine triphosphate nick-end labeling analysis, whereas a suppression of fragmentation was seen in RSa cells treated with AMI-SFs in combination with a caspase-3 inhibitor. The increase in caspase-3 activity was not inhibited by neutralizing antibodies to tumor necrosis factor-α, interleukin-6, human interferon-β, or interferon-γ. Polymerase chain reaction-based messenger RNA differential display and Northern blotting revealed an increase in the messenger RNA expression level of human ubiquitin hydrolase in AMI-SF-treated RSa cells. Antisense oligonucleotides for ubiquitin hydrolase inhibited the increase in caspase-3 activity. These findings suggested that serum from AMI patients in the acute phase contains factors that induce apoptosis, possibly by inducing the expression of the ubiquitin hydrolase gene, at least in the human cells tested. (J Lab Clin Med 2003;141:168-78)

Involvement of human heat shock protein 90 alpha in nicotine-induced apoptosis.

There have been conflicting reports of the apoptotic effects of nicotine on human cells and those studies reporting nicotine-induced apoptosis have not unequivocally clarified the molecular mechanisms underlying the effect. However, we found here that human RSa cells, established from embryonic fibroblastic cells doubly infected with Rous sarcoma virus and Simian virus 40, underwent apoptosis when cultured with medium containing 0.06-0.6 microM nicotine. The apoptosis was assessed by cellular DNA fragmentation and caspase-3 protease activation. Viability of RSa cells was reduced by nicotine treatment, as analyzed by MTT assay and the reduction was lessened by combination treatment with a caspase-3 inhibitor, acetyl-L-aspartyl-L-glutamyl-L-valyl-L-aspart-1-al (Ac-DEVD-CHO). Levels of expression of heat shock protein 90 alpha (Hsp90 alpha) were found to be increased 20 min after the nicotine treatment, as analyzed by polymerase chain reaction-based mRNA differential display after Northern blotting analysis of mRNA amounts. Cellular contents of Hsp90 alpha were furthermore increased in the nicotine-treated RSa cells, as quantitated by Western immunoblot analysis. By contrast, in RSa cells treated with nicotine in combination with geldanamycin (GA), an inhibitor of Hsp90 alpha function, DNA fragmentation was not detected and caspase-3 protease activity levels were the same as those of mock-treated cells. Nicotine-induced caspase-3 activation and Hsp90 alpha expression, as well as suppression of the induction by GA, were also observed in a xeroderma pigmentosum patient-derived cell line, XP2OS cells. Thus, it was suggested that nicotine induces apoptosis, possibly via Hsp90 alpha expression, in human cells tested.

Establishment and characterization of GSA-1, a human cell line highly susceptible to apoptosis after free-fall.

The induction of apoptosis by microgravity and/or gravity-changing stress is considered to be one of the important causes of cell death, although the molecular mechanisms of the apoptotic event remain unclarified. In this study, we established a cell line, GSA-1, from ethyl methanesulfonate-treated human RSa cells. GSA-1 cells were highly susceptible to apoptosis after a free-fall; 24.4% of these cells underwent apoptosis after free-fall, compared with only 6% of the RSa cells. The apoptosis of GSA-1 cells was augmented by ultraviolet (UV, principally 254-nm wavelength) irradiation before free-fall to a greater extents than those in RSa cells. The molecular mechanisms of apoptosis included p53 and Bax proteins; the expression of nuclear p53 and cytoplasmic Bax in GSA-1 cells increased at 4 h after free-fall irrespective of irradiation. In addition, the rate of removal of cyclobutane pyrimidine dimer (CPD) in UV-irradiated GSA-1 cells was higher in cells exposed to free-fall than in those under the 1-G condition. Our results suggested that in GSA-1 cells, free-fall accelerates apoptosis, and that this process is associated with the accumulation of p53 and Bax, as well as CPD removal. Thus, GSA-1 cells should be useful for investigating the mechanism of cellular response, including the induction of apoptosis under gravity-changing stress.

Enhanced expression of the LDH-A gene after gravity-changing stress in human RSa cells.

A major issue in radiation and space biology is whether gene expression levels are altered in cells exposed to gravity-changing stress. In the present study, genes up- or down-regulated in radiation-sensitive human RSa cells cultured under gravity-changing conditions, were identified using a PCR-based mRNA differential display method. Exposure of cells to gravity-changing stress was performed by free-fall with a drop-shaft facility or by an airplane-conducted parabolic flight. Among the candidates for gravity-changing stress-responsive genes obtained by the differential display analysis, the lactate dehydrogenase A gene (LDH-A) was confirmed by Northern blotting analysis to exhibit increased expression levels. The gravity-changing stress consisted of a combination of microgravity and hypergravity. However, exposure of the cells to hypergravity produced by centrifuge only slightly affected the LDH-A mRNA expression. Thus, LDH-A was found to be a candidate for the genes which play a role in the cellular response to gravity-changing stress, and mainly to microgravity.

Hypermutable Change of Human UVr-1 Cells by p53 Overexpression

The p53 protein has been reported to regulate cellular responses to genetic stress such as far-ultraviolet light (UV), protecting human cells from mutation. Levels of p53 protein in hypermutable RSa cells were found here to increase soon after UV irradiation, while those in UVr-1 cells, a hypomutable variant of RSa cells, showed a delayed increase. Three cell lines overexpressing wild-type p53 in UVr-1 cells exhibited higher sensitivity to UV mutagenicity than did control U-V-7 cells transfected with vector alone, assessed using the ouabain-resistance phenotypic mutation test and identification of K-ras codon 12 base substitution mutation. On the other hand, U-V-7 cells showed UV-induced elevation of antipain-sensitive protease activity, but p53 transfectants did not. Moreover, antipain treatment to U-V-7 cells was increased susceptibility to UV mutagenicity. Thus, p53 protein overproduction may sensitize human cells, at least those tested, to UV mutagenicity, in association with inhibition of protease activity.

Mutagenicity of bisphenol A and its suppression by interferon-α in human RSa cells

Bisphenol A is used as a monomer in the production of polycarbonate plastic products. The widespread use of bisphenol A has raised concerns about its effects in humans. Since there is little information on the mutagenic potential of the chemical, the mutagenicity of bisphenol A was tested using human RSa cells, which has been utilized for identification of novel mutagens. In genomic DNA from cells treated with bisphenol A at concentrations ranging from 1×10 −7 to 1×10 −5 M, base substitution mutations at K- ras codon 12 were detected using PCR and differential dot-blot hybridization with mutant probes. Mutations were also detected using the method of peptide nucleic acid (PNA)-mediated PCR clamping. The latter method enabled us to detect the mutation in bisphenol A-treated cells at a dose (1×10 −8 M) equivalent to that typically found in the environment. Induction of ouabain-resistant (Oua R) phenotypic mutation was also found in cells treated with 1×10 −7 and 1×10 −5 M of bisphenol A. The induction of K- ras codon 12 mutations and Oua R mutations was suppressed by pretreating RSa cells with human interferon (HuIFN)-α prior to bisphenol A treatment. The cells treated with bisphenol A at the concentration of 1×10 −6 M elicited unscheduled DNA synthesis (UDS). These findings suggested that bisphenol A has mutagenicity in RSa cells as well as mutagens that have been tested in these cells, and furthermore, that a combination of the PNA-mediated PCR clamping method with the human RSa cell line may be used as an assay system for screening the mutagenic chemicals at very low doses.