Direct analysis of radiation-induced chromosome fragments and rings in unstimulated human peripheral blood lymphocytes by means of the premature chromosome condensation technique

Development of the procedure to stimulate peripheral blood lymphocytes has greatly facilitated the understanding of chromosome aberration formation and repair mechanisms in human cells. Yet, because radiation induces far more initial chromosome breaks than are observed as aberrations in metaphase, it has not been possible to examine the kinetics of primary chromosome breakage and rejoining with this procedure. An improved method to induce premature chromosome condensation in unstimulated lymphocytes has been used to study primary chromosome breakage, rejoining, and ring formation at various times after irradiation with up to 800 rad of X-rays. The dose-response relations for chromosome fragments analyzed immediately or 1, 2, or 24 h after exposure were found to be linear. Rapid rejoining of chromosome fragments, which takes place in the first 3 h after X-ray exposure, was not correlated with a simultaneous increase in the formation of rings. The yield of rings per cell scored 24 h after irradiation, however, increased significantly and fit a linear quadratic equation. Both chromosome fragment rejoining and ring formation were completed about 6 h after irradiation. The frequency distributions of rings among cells followed a Poisson distribution, whereas chromosome fragments were overdispersed.     

The repair of bleomycin-induced DNA damage and its relationship to chromosome aberration repair.

Previous studies using the technique of premature chromosome condensation indicated that nearly one-half of the bleomycin-induced chromatid breaks and gaps in CHO cells could be repaired within 1 h (repair starting at 30 min) after treatment. Cycloheximide and streptovitacin A (but not hydroxyurea or hycanthone) inhibited chromosome repair. The purpose of this study was to measure the kinetics of DNA repair after bleomycin treatment using the alkaline elution technique and to determine whether various inhibitors could block this repair. After bleomycin treatment, the major proportion of the repair of DNA damage occurred within 15 min, with significant repair evident by 2 min. This fast repair component was inhibited by 0.2% EDTA. A slower repair component was observed to occur up to 60 min after bleomycin treatment. None of the inhibitors tested were found to have a significant effect on the repair of bleomycin damage at the DNA level. Since chromosome breaks were observed not to begin repair until after 30 min while over 50% of the DNA was repaired by 15 min, these results suggest that the DNA lesions that are repaired quickly are not important in the formation of chromosome aberrations. Further, since cycloheximide and streptovitacin A blocked chromosome repair but had little measurable effect on DNA repair, these results suggest that the DNA lesions responsible for chromosome damage represent only a small proportion of the total DNA lesions produced by bleomycin.     

Premature chromosome condensation. I. Visualization of x-ray-induced chromosome damage in interphase cells

A new method is described to visualize chromosome damage in interphase cells immediately after exposure to mutagenic agents. This method involves the fusion of treated interphase cells with untreated mitotic cells which results in the induction of premature chromosome condensation (PCC). Chinese hamster ovary (CHO) cells were treated with X-rays and chromosome aberrations were scored in G2-PCC and the mitotic chromosomes. The incidence of aberrations was significantly higher in PCC than that observed in the mitotic chromosomes of the treated cells. Post-irradiation incubation for I h before fusion allowed the repair of some of the chromosome damage. Data are also presented which indicate that the extent of radiation damage visualized in PCC is inversely proportional to the degree of chromosome condensation. These results indicate that the PCC method has a greater senstivity in the detection of induced chromosome damage than the standard method of scoring metaphase chromosomes.     

The relationship between DNA and chromosome damage after bleomycin treatment: dose-response measurements

The molecular basis for chromosome aberration formation has been studied using the sensitive techniques of premature chromosome condensation and DNA alkaline elution. The dose response of Chinese hamster ovary cells to bleomycin treatment at the DNA and chromosome levels was compared. Each DNA elution curve showed a 2-component profile, with a more sensitive component apparent at low doses. The chromosome aberration curves also exhibited a 2-component profile when determined in G2-PCC; however, this phenomenon was less apparent when chromosome damage was enumerated in mitotic figures. These results suggest that differential sensitivity to bleomycin exists within the cellular chromatin. The effect of dose rate on aberration formation was examined by administering bleomycin at 2 concentrations that, with different treatment times, yielded equivalent amounts of DNA damage. The chromatid exchange rate was independent of dose rate, suggesting that rapidly repaired DNA lesions are not involved in the formation of exchanges.     

Premature chromosome condensation. II. The nature of chromosome gaps produced by alkylating agents and ultraviolet light

Chinese hamster ovary (CHO) cells were treated with ultraviolet radiation or the alkylating agents, nitrogen mustard or trenimon, and chromosome damage to G2 phase cells were scored by the premature chromosome condensation (PCC) method or the metotic chromosome method. Treatment with these agents produced gaps but not chromatid breaks or exchanges. After UV treatment, the gap frequency observed in G2-PCC was higher than in the mitotic chromosomes, while the reverse trend was observed after treatment with nitrogen mustard or trenimon. These results suggest that two types of chromosome gaps exist, both of which are observable in mitotic chromosomes while only one type is observable in PCC due to differences in the stages of condensation between PCC and mitotic chromosomes.     

The cytogenetic effect of bleomycin on human peripheral lymphocytes in vitro and in vivo.

The cytogenetic effect of bleomycin (BLM) in human lymphocytes was studied after exposure to different doses during the G0 and G2 phases. BLM produced a marked specific effect on the cell cycle. The main aberration types after exposure in tg0 were dicentrics and deletions; and after exposure in G2, open chromatid breaks. A linear dose--response was calculated for all these aberration types as well as for the number of aberrant cells. In the G2 experiments, partially and totally pulverized cells also increased linearly with dose. The intercellular distributions of the most frequent aberration types after exposure in G0 and G2--the dicentrics and chromatid breaks, respectively--showed over-dispersion. These results show that the cytogenetic effect of BLM may be compared with that of densely ionizing irradiation. Preliminary results of chromosome analysis of three cancer patients in the course of BLM therapy showed effects similar to those in the G0 experiments.     

The influence of anoxia or oxygenation on the induction of chromosome aberrations in human lymphocytes by 15-MeV neutrons

Dicentric and total aberration yields induced in human lymphocytes by 15-MeV neutrons under conditions of oxygenation and of anoxia have been fitted to a dose-response curve using the function Y = D + βD². An oxygen-enhancement ratio (OER) ranging from 3.7 at low yields to 1.6 at high yields was calculated from the co-efficients of the dicentric yield curves and evidence is presented which suggests that oxygen does not act as a dose-modifying agent in this system. High dose RBE values of 1.2 and 2.1 with respect to 250 kVp X-rays for oxygenated and anoxic conditions were also obtained. Coefficients for total aberration yield gave similar values to dicentrics for both OER and RBE     

Putrescine biosynthesis in mammalial cells: Essential for DNA synthesis but not for mitosis

The object of this study was to examine the role of putrescine in the regulation of DNA synthesis and mitosis in synchronized Chinese hamster ovary cells using 1,3-diaminopropane (DAP) which is a potent inhibitor of ornithine decarboxylase (EC 4.1.17). Inhibition of putrescine biosynthesis significantly reduced the incorporation of [${}^3\text{H}$]-TdR into DNA but had no effect on the progression of cells from G1 to S phase. However, inhibition of putrescine synthesis in synchronized S phase cells did not affect their progression to mitosis. In these experiments, the DAP treatment had little or no effect on the levels of spermidine and spermine. These results indicate that putrescine biosynthesis is essential for the completion of DNA synthesis but not required for mitosis and cell division.     

Identification of a potent MAR element from the human genome and assessment of its activity in stably transfected CHO cells

Low‐level and unstable transgene expression are common issues using the CHO cell expression system. Matrix attachment regions (MARs) enhance transgene expression levels, but additional research is needed to improve their function and to determine their mechanism of action. MAR‐6 from CHO chromosomes actively mediates high and consistent gene expression. In this study, we compared the effects of two new MARs and MAR‐6 on transgene expression in recombinant CHO cells and found one potent MAR element that can significantly increase transgene expression. Two MARs, including the human CSP‐B MAR element and DHFR intron MAR element from CHO cells, were cloned and inserted downstream of the poly(A) site in a eukaryotic vector. The constructs were transfected into CHO cells, and the expression levels and stability of eGFP were detected by flow cytometry. The three MAR sequences can be ranked in terms of overall eGFP expression, in decreasing order, as follows: human CSP‐B, DHFR intron MAR element and MAR‐6. Additionally, as expected, the three MAR‐containing vectors showed higher transfection efficiencies and transient transgene expression in comparison with those of the non‐MAR‐containing vector. Bioinformatics analysis indicated that the NFAT and VIBP elements within MAR sequences may contribute to the enhancement of eGFP expression. In conclusion, the human CSP‐B MAR element can improve transgene expression and its effects may be related to the NFAT and VIBP elements.     

Fed-batch bioreactor performance and cell line stability evaluation of the artificial chromosome expression technology expressing an IgG1 in Chinese hamster ovary cells

The artificial chromosome expression (ACE) technology system uses an engineered artificial chromosome containing multiple site-specific recombination acceptor sites for the rapid and efficient construction of stable cell lines. The construction of Chinese hamster ovary(CHO) cell lines expressing an IgG1 monoclonal antibody (MAb) using the ACE system has been previously described (Kennard et al., Biotechnol Bioeng. 2009;104:540-553). To further demonstrate the manufacturing feasibility of the ACE system, four CHO cell lines expressing the human IgG1 MAb 4A1 were evaluated in batch and fed-batch shake flasks and in a 2-L fed-batch bioreactor. The batch shake flasks achieved titers between 0.7 and 1.1 g/L, whereas the fed-batch shake flask process improved titers to 2.5–3.0 g/L. The lead 4A1 ACE cell line achieved titers of 4.0 g/L with an average specific productivity of 40 pg/(cell day) when cultured in a non optimized 2-L fed-batch bioreactor using a completely chemically defined process. Generational stability characterization of the lead 4A1-expressing cell line demonstrated that the cell line was stable for up to 75 days in culture. Product quality attributes of the 4A1 MAb produced by the ACE system during the stability evaluation period were unchanged and also comparable to existing expression technologies such as the CHO-dhfr system. The results of this evaluation demonstrate that a clonal, stable MAb-expressing CHO cell line can be produced using ACE technology that performs competitively using a chemically defined fed-batch bioreactor process with comparable product quality attributes to cell lines generated by existing technologies.     

The relationship between the cell time available for repair and the effectiveness of a damaging treatment in provoking the formation of sister-chromatid exchanges

The effectiveness of a given dosage of visible light in inducing increased yields of SCEs was studied in Allium cepa L. meristems. Cells were first grown for one cycle time in the presence of BrdUrd and then irradiated at different times throughout the second cell cycle. The effectiveness of this treatment in provoking the formation of SCEs increases the closer the irradiation time is to the beginning of the S phase, and then decreases rapidly as cells progress through the S period. The largest increase in SCEs is obtained when irradiation coincides with early S phase. These results strongly suggest that SCEs arise at the time of DNA replication due to the presence of unrepaired lesions. Since repair appears to be a time-dependent process, the shorter the interval between damage induction and DNA replication, the greater the number of lesions that remain unrepaired, and as a consequence, the higher the effectiveness of the damaging treatment in provoking the formation of SCEs.     

Comparison of DNA-repair synthesis,chromosome aberrations and induction of micronuclei in cultured human fibroblast,Chinese hamster ovary and central mudminnow (Umbra limi) cells exposed to chemical mutagens

In mammalian cells it has previously been observed that low DNA-repair activity is correlated wtih high chromosome-aberration frequency. Since fish cells typically express comparatively low amounts of DNA repair, the chromosome aberration test holds potential as a sensitive fish genotoxicity assay. A comparison of in vitro DNA-repairm activity showed HF > CHO > Ul-H = Ul-F following exposure to MNNG and 4NQO. Although peak chromosome-aberration frequency varied CHO > Ul-H > HF, at comparable mutagen concentrations the relationship was Ul-H > HF > CHO following 4NQO exposure and Ul-H > HF = CHO after MNNG exposure. Analyzing for chromosome aberrations at high mutagen concentrations was not possible due t mitotic inhibition/toxicity which varied according to the mutagen and cell line. Micronuclei frequency varied CHO > Ul-H > HF = Ul-F. In CHO and Ul-H, a 10–15 fold increase over the controls compares with only a 2–3 fold increase for HF and Ul-F. These differences are likely related, in part, to the cell-division rate of each line and the coincident repair of the damaged DNA. Reasons for the lack of negative correlation between DNA repair and chromosomal damage in fish cells are discussed.     

N-glycosylation is required for efficient secretion of a novel human secreted glycoprotein, hPAP21

The present study reported the isolation and characterization of a novel human secreted protein, named as hPAP21 (human protease-associated domain-containing protein, 21 kDa), encoded by the hypothetical gene chromosome 2 open reading frame 7 (C2orf7) that contains signal peptide in its N-terminus, without transmembrane domain, except for PA domain in its middle. Western blotting assay indicated that the c-Myc tagged hPAP21 could be secreted into culture medium in the transfected Chinese hamster ovary cells. However, the molecular weights, whatever intracellular (28 kDa) or extracellular (30 kDa) forms, are larger than that of the prediction. To define whether the glycosylation was important process for its secretion, endoglycosidase H (Endo H) and PNGase F (PNG F) were employed to evaluate the effect of glycosylation types on secretion of hPAP21. Interestingly, the extracellular forms were primarily sensitive to PNG F, not Endo H, implying that complex N-glycosylation could be required for the secretion of hPAP21. Furthermore, N-glycosylation of Asn171 was confirmed as potential crucial process for the secretory protein via site-directed mutagenesis assay. All data will be contributed to the understanding of molecular functions of hPAP21.     

Investigation of the genotoxic effects of 2-amino-9H-pyrido[2,3-b]indole in different organs of rodents and in human derived cells

Aim of the present study was the investigation of the genotoxicity of amino-alpha-carboline (AalphaC) in human derived cells and of its organ-specific effects in laboratory rodents. This heterocyclic amine (HA) is contained in fried meat and fish in higher concentrations than most other cooked food mutagens. In the present experiments, AalphaC caused dose-dependent induction of micronuclei in the human derived hepatoma cell line HepG2 at concentrations > or =50 microM. In contrast, no significant effects were seen in Hep3B, another human hepatoma cell line, which may be explained by the concurrent lower activity of sulfotransferase (SULT), an enzyme playing a key role in the activation of AalphaC. A positive result was also obtained in the single cell gel electrophoresis (SCGE) assay in peripheral human lymphocytes, but the effect was only significant at the highest concentration (1000 microM). In Fischer F344 rats and ICR mice, the liver was the main target organ for the formation of DNA adducts (at > or =50 mg/kg bw), and in lungs and colon substantially lower levels were detected. Identical organ specificity as in the DNA adduct measurements was seen in SCGE assays with rats, whereas in mice the most pronounced induction of DNA migration was observed in the colon. Comparison of our results with data from earlier experiments indicate that the genotoxic potency of AalphaC is equal to that of other HAs, which are contained in human foods in much smaller amounts. Therefore, our findings can be taken as an indication that the human health risk caused by exposure to AalphaC is higher than that of other HAs that are formed during the cooking of meat and fish.     

Effects of metabolic inhibitors on cell lethality and mutation induction in Chinese hamster cells. I. Inhibitors of de novo purine synthesis and a comparison with the effects of caffeine

The effect of pre- and posttreatment incubation of UV-irradiated and ethyl methanesulphonate (EMS) treated cells with non-toxic concentrations of inhibitors of de novo purine synthesis (dnPS) on expression of potentially lethal and premutational damage at the hypoxanthine-guanine phosphoribosyl transferase (HGPRT) locus in V79 cells has been examined. The concentrations of inhibitors used were shown to profoundly perturb de novo DNA synthesis, by measurements of [¹⁴C]formate uptake, and cell cycle progression by flow cytofluorimetry. Postincubation in 6-methyl mercaptopurine ribonucleoside (MMPR) usually but not invariably potentiated the cytotoxic effects of UV and EMS but azaserine (AZS) and methotrexate (MTX) were without effect. No effects on mutant frequencies were observed on posttreatment with any of these agents. Caffeine produced the least effect on dnPS, but invariably potentiated lethal damage. This potentiation of lethal damage is not mediated by dnPS inhibition as has been suggested for Chinese hamster ovary (CHO) cells.     

Mutagenicity testing in mammalian cells: I. Derivation of a chinese hamster ovary cell line heterozygous for the adenine phosphoribosyltransferase and thymidine kinase loci

As a first step in the development of a multiple-marker, mammalian cell mutagenesis assay system, we have isolated a Chinese hamster ovary (CHO) cell line that is heterozygous for both the adenine phosphoribosyltransferase (aprt) and thymidine kinase (tk) loci. Presumptive aprt^+/? heterozygotes with intermediate levels of APRT activity were selected from unmutagenized CHO cell populations on the basis of resistance to low concentrations of the adenine analog, 8-azaadenine. A functional aprt^+/? heterozygote with ～50% wild-type APRT activity was subsequently used to derive sublines that were also heterozygous for the tk locus. Biochemical and genetic characterization of one such subline, CHO-AT3-2, indicated that it was indeed heterozygous at both the aprt and tk loci. CHO-AT3-2 cells permitted single-step selection of mutants resistant to 8-azaadenine or 5-fluorodeoxyuridine, allowing quantitation and direct comparison of mutation induction at the autosomal aprt or tk loci, as well as in the gene involved in ouabain resistance or at the X-linked, hypoxanthine-guanine phosphoribosyltransferase (hgprt) locus. Significant dose-dependent increases in mutation frequency were observed for all 4 genetic markers after treatment of CHO-AT3-2 cells with ethyl methanesulfonate.     

Knockout of sialidase and pro-apoptotic genes in Chinese hamster ovary cells enables the production of recombinant human erythropoietin in fed-batch cultures

Sialic acid, a terminal monosaccharide present in N-glycans, plays an important role in determining both the in vivo half-life and the therapeutic efficacy of recombinant glycoproteins. Low sialylation levels of recombinant human erythropoietin (rhEPO) in recombinant Chinese hamster ovary (rCHO) cell cultures are considered a major obstacle to the production of rhEPO in fed-batch mode. This is mainly due to the accumulation of extracellular sialidases released from the cells. To overcome this hurdle, three sialidase genes (Neu1, 2, and 3) were initially knocked-out using the CRISPR/Cas9-mediated large deletion method in the rhEPO-producing rCHO cell line. Unlike wild type cells, sialidase knockout (KO) clones maintained the sialic acid content and proportion of tetra-sialylated rhEPO throughout fed-batch cultures without exhibiting a detrimental effect with respect to cell growth and rhEPO production. Additional KO of two pro-apoptotic genes, BAK and BAX, in sialidase KO clones (5X KO clones) further improved rhEPO production without any detrimental effect on sialylation. On day 10 in fed-batch cultures, the 5X KO clones had 1.4-times higher rhEPO concentration and 3.0-times higher sialic acid content than wild type cells. Furthermore, the proportion of tetra-sialylated rhEPO on day 10 in fed-batch cultures was 42.2–44.3% for 5X KO clones while it was only 2.2% for wild type cells. Taken together, KO of sialidase and pro-apoptotic genes in rCHO cells is a useful tool for producing heavily sialylated glycoproteins such as rhEPO in fed-batch mode.