Supervision of cellular response to radiation by human interferon

Human interferon (HuIFN) conferred human RSa cells to increased resistance to ultraviolet light, 4-nitroquinoline-1-oxide and X-ray in association with enhancement of DNA-repair capacity. The HuIFN actions were summarized by the supervision of cellular response, possibly via plasminogen activator-like protease induction.     

A wide-ranging cellular response to UV damage of DNA

The kinases ATM and ATR are central to proper function of the DNA damage response. These kinases phosphorylate proteins to coordinate cell cycle progression and DNA damage repair/bypass. We have recently reported a large-scale identification of ATM/ATR substrates phosphorylated in response to UV damage of DNA. Overall 231 sites of phosphorylation were induced by UV damage of DNA or dependent on proper function of ATR. The study expanded the number of phosphorylation sites from protein classes known to be involved in the DNA damage response. Further, many sites were identified from protein types not thought to have a role in damage signaling. This observation suggests that the DNA damage response affects a much wider range of cellular processes than was previously appreciated. This study has also extended the successful use of the PhosphoScan® proteomic method from phospho-tyrosine to serine/threonine motifs, providing a general blueprint to use the method to study signaling pathways underlying a wide range of diseases.     

Suppression of UV mutagenicity by human interferon

Effects of human interferon (HuIFN)-alpha on UV mutagenicity were examined in a human cell strain, RSa, and xeroderma pigmentosum (XP)-derived fibroblasts (XP1KY). The frequency of ouabain-resistance mutation in UV-irradiated RSa cells was unusually high (Suzuki et al., 1985), but that in cells pretreated with HuIFN-alpha before irradiation was reduced. 6-Thioguanine-resistance mutation was also depressed in XP1KY cells treated with HuIFN-alpha before irradiation. However, the depression of UV mutagenicity by HuIFN-alpha was lessened by treatment with cycloheximide immediately after UV irradiation. The relationship between HuIFN-depressed UV mutagenicity and HuIFN-affected DNA-repair and repair-related functions is discussed.     

Gamma-ray- and UV-sensitive strains of a radioresistant cell line: isolation and cross-sensitivity to other agents

Two gamma-ray-sensitive and two ultraviolet (UV)-sensitive variants were isolated from the gamma-ray- and UV-resistant TN-368 lepidopteran insect cell line. The isolation was performed by inducing mutations in the TN-368 cells using ethyl methanesulfonate, growing them for an expression period, irradiating with 137Cs gamma rays or 254-nm UV radiation, allowing cells to incorporate 5-bromodeoxyuridine (BrdU) in the presence of hydroxyurea (DNA repair synthesis), and finally irradiating with 365-nm UV radiation to cause DNA strand breakage at sites of BrdU incorporation with the intent of killing those cells that have undergone DNA repair synthesis and sparing those cells which, for a variety of reasons, did not. The survival of the Cs2 and Cs7 variants exposed to X rays is significantly different from the parent TN-368 line at the P less than 0.0001 level. The survival of the UV10 and UV19 variants exposed to UV radiation is different from the parent at the P less than 0.0001 and P less than 0.003 levels, respectively. In cross-sensitivity testing of the gamma-ray-sensitive variants, only Cs2 is more sensitive to 254-nm UV and only Cs7 is more sensitive to 44 degrees C heating; both are sensitive to PUVA. The UV-sensitive mutants are both sensitive to X irradiation, PUVA, and mitomycin C. However, UV10 is not sensitive to 44 degrees C heating while UV19 is, making UV19 the only variant strain sensitive to all agents examined. Despite the isolation procedure which was intended to select for DNA repair-deficient cells, the results suggest that a more general mechanism is responsible for the sensitivity of the variant cells to the agents tested.     

Spontaneous mutability in UV-sensitive excision-defective strains of Saccharomyces.

The genes RAD1, RAD2, RAD3 and RAD4 encode enzymes in the pathway leading to excision repair of UV-induced DNA damage in Saccharomyces cerevisiae. Four mutant alleles of these loci (rad1-1, rad2-2, rad3-12, and rad4-3) were studied for their effect on spontaneous reversion rate to lysine and histidine independence, by means of the 1000-compartment fluctuation test of von Borstel, Cain and Steinberg. Of these four excision-defective alleles, only rad3-12 was found to substantially increase the spontaneous reversion rate of the nonsense-suppressible lys1-1 allele, both through locus reversion as well as by forward mutation at one of eight suppressor loci. Similarly, only rad3-12 conferred a considerable increase in the reversion frequency of the missense his1-7 mutant. As the RAD3 gene product is believed to mediate the first step in the excision-repair pathway, it is assumed that spontaneous lesions in the rad3 strain are channelled into a mutagenic repair pathway, thus accounting for the enhanced spontaneous mutation rate.     

Comparison of the reversibility of locipet23 andlys2 after UV irradiation in the standard and UV-sensitive strains ofSaccharomyces cerevisiae

Reversibility of the respiration-deficient locuspet23 and auxotrophic locuslys2 was followed in the standard (RAD1) and UV sensitive (rad1–2) strains ofSaccharomyces cerevisiae, both after identical doses of UV radiation and at identical survival. When comparing the reversibility after the treatment with identical doses of UV radiation a much higher reversibility of both loci in strainrad1–2 could be detected. When comparing the reversibility of the loci in question at identical survival of both strains it could be found that the reversibility of thepet23 locus is again much higher in strainrad1–2, whereas the reversibility of thelys2 locus is roughly identical in the two strains. Thus, the function of geneRAD1 in repair processes is apparently associated with the “error-free” repair, both at low and high doses of ultraviolet radiation.     

Altered cellular response to UV irradiation in a patient affected by premature ageing

Summary An abnormal response to UV-irradiation was found in a patient affected by precocious senescence. A decreased level of unscheduled DNA synthesis (UDS) was present in 60% of G_o lymphocytes and in fibroblasts after the fifth culture passage. Hypersensitivity of lymphocytes to UV-light was indicated also by a decreased rate of DNA synthesis after mitogen stimulation. The results of this study indicate that the defect which determines the premature ageing influences the capacity to repair UV-induced DNA damage.     

Effects of interferon alpha on human osteoprogenitor cell growth and differentiation in vitro.

The specific effects of interferon alpha (IFNalpha), on the differentiation pathways of human osteogenic cells are not known. The aim of this study was to investigate possible effects of IFNalpha on osteogenic development by investigating cell differentiation, colony formation (colony forming unit-fibroblastic, CFU-F), cell proliferation, and gene expression, in particular bone morphogenetic protein (BMP) expression, of human bone marrow osteoprogenitor cells. Human bone marrow fibroblasts were cultured with or without the addition of IFNalpha (5-1,000 IU/ml) in the presence and absence of dexamethasone (10 nM) and ascorbate (100 microM), which are agents known to affect osteogenic differentiation. IFNalpha produced a significant dose-dependent inhibition of cell proliferation and alkaline phosphatase specific activity at concentrations as low as 50 IU/ml. IFNalpha (50-1,000 IU/ml) inhibited the stimulation of alkaline phosphatase specific activity induced by ascorbate and dexamethasone. Examination of CFU-F showed dose- and time-dependent inhibitions of colony formation and reductions in both colony size and alkaline phosphatase-positive CFU-F colonies particularly at earlier times. Reactivity with an antibody specific for osteoprogenitors (HOP-26), was reduced in IFNalpha-treated cultures. Northern blot analysis showed a significant dose-dependent up-regulation of BMP-2 mRNA, estrogen receptor alpha mRNA and osteocalcin mRNA expression in ascorbate/dexamethasone cultures. In contrast, IFNalpha significantly inhibited BMP-2 mRNA expression in the absence of ascorbate and dexamethasone. In conclusion, IFNalpha inhibits human osteoprogenitor cell proliferation, CFU- F formation, HOP-26 expression, and alkaline phosphatase specific activity and modulates BMP-2 gene expression. These results suggest a role for IFNalpha in local bone turnover through the specific and direct modulation of osteoprogenitor proliferation and differentiation.     

Sensitivity to DNA-damaging agents and mutation induction by UV light in UV-sensitive CHO cells

Three UV-sensitive (UVs) mutants isolated from a CHO cell line were analyzed for survival after exposure to H2O2, EMS, MMC, CCNU, X-rays and for mutation induction after UV-irradiation. The UVs mutants showed normal sensitivities to EMS and H2O2, whereas they were hypersensitive to the bifunctional alkylating agents MMC and CCNU and to hypoxic X-irradiation. Compared to parental cells, one of the UV-sensitive clones showed approximately 3- and 7-fold enhancement in the mutagenic response per unit UV dose for 6-thioguanine and ouabain resistance, respectively.     

Microcolony formation by single-cell Synechococcus strains as a fast response to UV radiation

UV radiation (UVR) has different effects on prokaryotic cells, such as, for instance, filamentation and aggregation in bacteria. Here we studied the effect of UVR on microcolony formation in two freshwater Synechococcus strains of different ribotypes (group B and group I) and phycobiliprotein compositions (phycoerythrin [PE] and phycocyanin [PC]). Each strain was photoacclimated at two light intensities, low light (LL) (10 μmol m⁻² s⁻¹) and moderate light (ML) (100 μmol m⁻² s⁻¹). The cultures were exposed for 6 days to treatments with UVR or without UVR. PE-rich Synechococcus acclimated to LL had a low carotenoid/chlorophyll a (car/chl) ratio but responded faster to UVR treatment, producing the highest percentages of microcolonies and of cells in microcolonies. Conversely, the same strain acclimated to ML, with a higher car/chl ratio, did not aggregate significantly. These results suggest that microcolony formation by PE-rich Synechococcus is induced by UVR if carotenoid levels are low. PC-rich Synechococcus formed a very low percentage of microcolonies in both acclimations even with low car/chl ratio. The different responses of the two Synechococcus strains to UVR depend on their pigment compositions. On the other hand, this study does not exclude that UVR-induced microcolony formation could also be related to specific ribotypes.     

Changes in the cellular behaviour of human colonic cell line Caco-2 in response to butyrate treatment

Gut-derived adenocarcinoma Caco-2 cells were treated with sodium butyrate (NaB) at physiologically relevant concentrations. We characterized its effects on proliferation, differentiation, apoptosis, adhesion to the solid support and interleukin-8 secretion. Differentiation was determined by brush border alkaline phosphatase activity. Apoptosis was assessed by acridine orange and Hoechst stains. Differentiation and apoptosis were analyzed in both adherent and floating cell populations. The transformed Caco-2 cells did not retain their malignant phenotype in the presence of NaB. They appeared to undergo a change in the phenotype induced by NaB, as indicated by reduced proliferation, enhanced differentiation, stimulation of apoptosis leading to decreased viability of cells, and stimulation of interleukin-8 secretion. Considering all the above facts and data, we postulate that Caco-2 cells cultured in NaB supplemented medium could regain the phenotypic characteristics of the phenotype of the parent cell from which originated the Caco-2 line.     

Cross-resistance to UV radiation of a cisplatin-resistant human cell line: overexpression of cellular factors that recognize UV-modified DNA.

A human cell line selected for cisplatin resistance (CPR) was irradiated with UV light and showed cross-resistance to UV light. Applying a modified chloramphenicol acetyltransferase assay, we observed that CPR cells acquired enhanced host cell reactivation of a transfected plasmid carrying UV damage. Gel mobility shift analysis indicated that two nuclear factors that recognize UV-modified DNA were overexpressed in CPR cells. In addition, factors that bind UV-modified DNA were independent from the factors that bind cisplatin-modified DNA. The significance of the identified binding factors, possibly DNA repair enzymes, is discussed.     

Molecular mechanisms of natural killer cell activation in response to cellular stress

Protection against cellular stress from various sources, such as nutritional, physical, pathogenic, or oncogenic, results in the induction of both intrinsic and extrinsic cellular protection mechanisms that collectively limit the damage these insults inflict on the host. The major extrinsic protection mechanism against cellular stress is the immune system. Indeed, it has been well described that cells that are stressed due to association with viral infection or early malignant transformation can be directly sensed by the immune system, particularly natural killer (NK) cells. Although the ability of NK cells to directly recognize and respond to stressed cells is well appreciated, the mechanisms and the breadth of cell-intrinsic responses that are intimately linked with their activation are only beginning to be uncovered. This review will provide a brief introduction to NK cells and the relevant receptors and ligands involved in direct responses to cellular stress. This will be followed by an in-depth discussion surrounding the various intrinsic responses to stress that can naturally engage NK cells, and how therapeutic agents may induce specific activation of NK cells and other innate immune cells by activating cellular responses to stress.     

Proteomic analysis of cellular response to microcystin in human amnion FL cells

Microcystins (MC), the potent inhibitor of protein phosphatase 1 and 2A, are hepatotoxins of increasing importance due to its high acute toxicity and potent tumor promoting activity. So far, the exact mechanisms of MC-induced hepatotoxicity and tumor promoting activity have not been fully elucidated. To better understand the mechanisms underlying microcystin-RR (MC-RR) induced toxicity as well as provide the possibility for the establishment of biomarkers for MC-RR exposure, differential proteome analysis on human amnion FL cells treated by MC-RR was carried out using two-dimensional gel electrophoresis (2-DE) followed by matrix-assisted laser desorption/ionization-time-of-flight mass spectrometry. Image analysis of silver-stained 2-dimensional gels revealed that 89 proteins showed significant differential expression in MC-RR treated cells compared with control, and 8 proteins were unique to MC-RR treated cells and 8 proteins were only detected in control cells. Sixty-six proteins were further identified with high confidence by peptide mass fingerprinting. Some of the identified differentially expressed proteins have clearly relationship with the process of apoptosis, signal transduction, and cytoskeleton alteration which are consistent with the literature. The functional implications of alterations in the levels of these proteins were discussed. However, most of which have not been reported previously to be involved in cellular processes responded to MC-RR. Therefore, this work will provide new insight into the mechanism of MC-RR toxicity.     

Effects of length and location on the cellular response to double-stranded RNA.

Since double-stranded RNA (dsRNA) has not until recently generally been thought to be deliberately expressed in cells, it has commonly been assumed that the major source of cellular dsRNA is viral infections. In this view, the cellular responses to dsRNA would be natural and perhaps ancient antiviral responses. While the cell may certainly react to some dsRNAs as an antiviral response, this does not represent the only response or even, perhaps, the major one. A number of recent observations have pointed to the possibility that dsRNA molecules are not seen only as evidence of viral infection or recognized for degradation because they cannot be translated. In some instances they may also play important roles in normal cell growth and function. The purpose of this review is to outline our current understanding of the fate of dsRNA in cells, with a focus on the apparent fact that their fates and functions appear to depend critically not only on where in the cell dsRNA molecules are found, but also on how long they are and perhaps on how abundant they are.     

Effects of fractionated X-irradiation on subsequent response to acute X-irradiation in two human tumour cell lines in vitro

The exposure of two human tumour cell lines, one derived from a squamous cell carcinoma of the tongue (HN-1) and the other from an adenocarcinoma of the breast (MCF-7), to fractionated X-irradiation in vitro, resulted in altered sensitivity to subsequent acute X-irradiation exposure in the former but not the latter tumour cell type. The X-ray-pretreated HN-1 cells, designated HN-1/DXR11 cells, showed a significantly increased sensitivity to X-irradiation with a D0 of 0.97 Gy, compared with a figure of 1.39 Gy for the parental cells. No significant changes were noted in a number of basic cell kinetic or biological parameters in the X-ray-pretreated cells. However, this enhanced X-ray sensitivity in the HN-1/DXR11 cells was associated with decreased cellular levels of total intracellular glutathione. These findings are consistent with the theory that intracellular thiols are involved in protection from radiation damage. This is one of the first observations that prior exposure to X-irradiation can modify subsequent responses to acute X-irradiation treatment in human tumour cells.     

Effects of deferasirox and deferiprone on cellular iron load in the human hepatoma cell line HepaRG

Two oral chelators, CP20 (deferiprone) and ICL670 (deferasirox), have been synthesized for the purpose of treating iron overload diseases, especially thalassemias. Given their antiproliferative effects resulting from the essential role played by iron in cell processes, such compounds might also be useful as anticancer agents. In the present study, we tested the impact of these two iron chelators on iron metabolism, in the HepaRG cell line which allowed us to study proliferating and differentiated hepatocytes. ICL670 uptake was greater than the CP20 uptake. The iron depletion induced by ICL670 in differentiated cells increased soluble transferrin receptor expression, decreased intracellular ferritin expression, inhibited ⁵⁵Fe (III) uptake, and reduced the hepatocyte concentration of the labile iron pool. In contrast, CP20 induced an unexpected slight increase in intracellular ferritin, which was amplified by iron-treated chelator exposure. CP20 also promoted Fe(III) uptake in differentiated HepaRG cells, thus leading to an increase of both the labile pool and storage forms of iron evaluated by calcein fluorescence and Perls staining, respectively. In acellular conditions, compared to CP20, iron removing ability from the calcein-Fe(III) complex was 40 times higher for ICL670. On the whole, biological responses of HepaRG cells to ICL670 treatment were characteristic of expected iron depletion. In contrast, the effects of CP20 suggest the potential involvement of this compound in the iron uptake from the external medium into the hepatocytes from the HepaRG cell line, therefore acting like a siderophore in this cell model.     

Differential response of human fibroblasts to the cytotoxic and mutagenic effects of UV radiation in different phases of the cell cycle

The effects of DNA repair on UV-induced mutagenesis and cell killing in human diploid skin fibroblasts in different phases of the cell cycle were studied. The cells were synchronized in G1 by culturing at 30 degrees C. Using this synchronization method, it could be demonstrated that cells irradiated at 30 degrees C and allowed to carry out excision repair for various lengths of time, show a much lower mutation frequency than cells irradiated in the exponentially growing state. Irradiation in early G1 gives rise to less mutations than irradiation in S. However, the surviving fraction is not decreased when cells are irradiated in S in comparison with irradiation in G1. Moreover, there is no recovery from UV-induced lethal effects when irradiated cells are kept stationary at 30 degrees C for various periods of time. This is in contrast with the results obtained with density-inhibited fibroblasts held at 37 degrees C, which show a recovery from the UV-induced lethal effects.