Miguel A. Reigosa

In vitro genotoxic and cytotoxic effects of ivermectin and its formulation ivomec on Chinese hamster ovary (CHOK1) cells.

The effects of ivermectin (IVM) and its commercial formulation ivomec (IVM 1.0%) were studied on Chinese hamster ovary (CHO(K1)) cells by several genotoxicity [sister chromatid exchange (SCE) and single cell gel electrophoresis (SCGE)] and cytotoxicity [cell-cycle progression (CCP), mitotic index (MI), proliferative replication index (PRI), 3(4,5-dimethylthiazol-2-yl)-2,5-diphenyltetrazolium bromide (MTT), and neutral red (NR)] bioassays within the 1.0-250 microg/ml concentration-range. While IVM and ivomec did not modified SCE frequencies, they induced DNA-strand breaks revealed by SCGE. An enhancement of slightly damaged cells and a decrease in undamaged cells were observed in IVM-treated cultures with 5.0-50.0 microg/ml. In ivomec((R))-treated cells, while an increase in slightly damaged cells was induced with 5.0-50.0 microg/ml, the damaged and undamaged cells increased and decreased only with 50.0 microg/ml. Both compounds exerted a delay in CCP and a reduction in PRI when 25.0 microg/ml was employed whereas cytotoxicity was observed at higher concentration than 50.0 microg/ml. No MI alteration was observed with 1.0-10.0 and 1.0-5.0 microg/ml of IVM and ivomec, respectively. A concentration-related trend to an increase in MI was achieved within 1.0-10.0 microg/ml. An increase in the MI was induced in 10.0 microg/ml ivomec-treated cultures. A marked reduction of about 89% and 62% in regard to controls was observed with 25.0 microg/ml of IVM and ivomec, respectively. NR and MTT assays revealed a cell growth inhibition when 0.25-250.0 microg/ml of both compounds was employed. The results highlighted that IVM and ivomec exert both genotoxicity and cytotoxicity in mammalian cells in vitro, at least in CHO(K1) cells.

Effect of dithiocarbamate pesticide zineb and its commercial formulation, azzurro. IV. DNA damage and repair kinetics assessed by single cell gel electrophoresis (SCGE) assay on Chinese hamster ovary (CHO) cells.

Single cell gel electrophoresis (SCGE) was used to analyse dithiocarbamate zineb- and the zineb-containing technical formulation azzurro-induced DNA damage and repair in CHO cells. Cells were treated with zineb (50.0 microg/ml) or azzurro (100.0 microg/ml) for 80min, washed and reincubated in pesticide-free medium for 0-12h until SCGE. Viability of treated cells (0 h) did not differ from control remaining unchanged up to 6h of incubation. After 12h, viability decreased up to 70 and 54% in zineb- and azzurro-treated cultures, respectively. SCGE revealed at 0 h the absence of undamaged cells and an increase of slightly damaged and damaged cells in zineb-treated cultures or by an increase in damaged cells in azzurro-treated cultures. For both chemicals, a time-dependent repair of pesticide-induced DNA damage within a 0-12h post-treatment incubation period was observed. Overall, damaged cells decreased as a function of the repair time for both pesticides while the slightly damaged cells decreased as a function of the repair time of zineb-induced DNA damage. Concomitantly, a time-dependent increase of undamaged cells was observed within the 0.5-12h repair time for both pesticides. At 12h after treatment, no differences in the frequencies of undamaged, slightly damaged and damaged cells were found between both zineb- or azzurro-treated cultures and control values as well as between zineb- and azzurro-treated cells. Immediately after exposure, nuclear DNA from zineb and azzurro-treated cells were larger and wider than nuclear DNA from untreated cells. When damaged cells were allowed to repair, a time-dependent decrease of the amount of free DNA migrating fragments was observed committed only to damaged cells but not in slightly or undamaged cells. On the other hand, no time-dependent alteration on nuclear DNA width within the 0-12h repair period was observed.

Genotoxic and cytotoxic effects of carbofuran and furadan on Chinese hamster ovary (CHOK1) cells.

The in vitro geno- and cytotoxicity exerted by the N-methylcarbamate pesticide carbofuran (CF) and its commercial formulation furadan (F) were studied in Chinese hamster ovary (CHO(K1)) cells by several bioassays for both genotoxicity (e.g., the sister chromatid exchange (SCE) and micronuclei (MNi) frequencies), and cytotoxicity (e.g., cell-cycle progression, mitotic index (MI), 3(4,5-dimethylthiazol-2-yl)-2,5-diphenyltetrazolium bromide (MTT), and neutral red (NR)). Both CF and F activities were tested within the range of 5-100 microg/ml. CF within a 10-100 microg/ml concentration-range induced a significant dependent increase of SCE frequency and MNi over control values. At the same concentration-range, F increased significantly the SCE frequencies over control values although in a non-dependent manner while only an enhanced frequency of MNi was found in those 50 microg/ml-treated cultures. No binucleated cytokinesis-block cells were found in 100 microg/ml F-treated cultures. The NDI index revealed a delay in the onset of cell-division with 50 and 100 microg/ml of CF and F, respectively. The delayed rate of nuclear division induced by 100 microg/ml of F was higher than that induced by an equal concentration of CF. CF and F induced both a significant concentration-dependent delay in cell-cycle progression and a decrease in the proliferative replication index within 5-100 microg/ml and 50-100 microg/ml concentration-range, respectively. Decreased cell viability was found in up to 26% and 47% in 100 microg/ml CF- and F-treated cultures, respectively. The NR and MTT assays revealed a clear cell growth inhibition when concentrations of 50 and 100 microg/ml of either CF or F were employed. Accordingly, the results highlight that CF by itself and F, even in a greater extend exerts both genotoxicity and cytotoxicity in mammalian cells in culture, at least in CHOK1 cells.

Herbicide 2,4-dichlorophenoxyacetic acid (2,4-D)-induced cytogenetic damage in human lymphocytes in vitro in presence of erythrocytes

The genotoxic effects of 2,4‐D and its commercial derivative 2,4‐D DMA were studied by measuring sister chromatid exchange (SCE), cell‐cycle progression and mitotic index in human whole blood (WBC) and plasma leukocyte cultures (PLC). Concentrations of 10, 25, 50 and 100 μg herbicide/ml were used during 72 h. In WBC, a significant increase in SCE frequency was observed within the 10–50 μg 2,4‐D/ml and 25–100 μg 2,4‐D DMA/ml dose range. Contrarily, in PLC, none of the concentrations employed affected the SCEs frequency. A significant delay in cell proliferation was observed in WBC after treatments with 25 and 50 μg 2,4‐D/ml and 50 and 100 μg 2,4‐D DMA/ml. In PLC, only 100.0 μg 2,4‐D/ml altered cell‐cycle progression. For both chemicals, a progressive dose‐related inhibition of mitotic activity was observed. The results demonstrated that the presence of erythrocytes in the culture system modulated the DNA and cellular damage inflicted by 2,4‐D and 2,4‐D DMA into human lymphocytes in vitro as well as both 2,4‐D and 2,4‐D DMA were more potent genotoxic agents in the presence of human red cells.

Effect of the dithiocarbamate pesticide zineb and its commercial formulation, the azzurro. V. Abnormalities induced in the spindle apparatus of transformed and non-transformed mammalian cell lines

Abnormalities induced in the mitotic spindle by zineb and azzurro (1.0-25.0 micro g/ml, 24h) were evaluated in Chinese hamster ovary (CHO) and HeLa cells, and in non-transformed human fibroblasts (NTHF). Spindles were stained with FITC-conjugated anti-beta tubulin. Treatment with 10.0 micro g/ml of zineb induced complete inhibition of cell viability in NTHF cells while 10.0 micro g/ml of azzurro decreased cell growth down to 62%. Higher doses of both compounds induced cell death. In HeLa and CHO cells, 15.0 micro g/ml of zineb and 10.0-15.0 micro g/ml of azzurro decreased viability, whereas 25.0 micro g/ml of both compounds was cytotoxic. A significantly decreased mitotic index (MI) was observed in NTHF treated with 5.0 micro g/ml zineb or azzurro, whereas 10.0 micro g/ml of both chemicals were necessary to induce the same phenomenon in HeLa and CHO cells. Treatment with 1.0-5.0 micro g/ml of zineb or azzurro induced a dose-dependent increase of degenerated spindles in NTHF and the number of degenerated or multipolar spindles in HeLa and CHO cells increased in a dose-dependent manner with 1.0-10.0 micro g/ml zineb and azzurro. Although zineb and azzurro were able to induce mitotic spindle abnormalities in all cell types, non-transformed cells were less resistant than immortalized cells.

Erythrocytes modulate the baseline frequency of sister-chromatid exchanges and the kinetics of lymphocyte division in culture

The baseline sister-chromatid exchange (SCE) frequencies of human plasma lymphocyte cultures (PLC), but not pig PLC, were nearly twice as high as those of whole-blood cultures (WBC). Addition of human red blood cells (RBCs) to human PLC decreased the SCE frequency in proportion to the RBC-leukocyte co-incubation interval. When the period of RBC-leukocyte co-incubation was equivalent to the total length of the culture period (72 h), the SCE frequency was similar to that observed in WBC. Shorter co-incubation periods yielded SCE frequencies intermediate between those of PLC and WBC. Regardless of the species, cell proliferation was slower in PLC than in WBC. Experiments where RBCs were added to PLC showed that the time sequence of RBC incorporation also affects the cell-cycle progression of human and pig lymphocytes. When either human or pig RBCs were added immediately after PLC stimulation, the cell-cycle kinetics was similar to that of WBC. Shorter co-incubation periods made cell-cycle progression intermediate between PLC and WBC values. Thus, PBCs modulate the baseline frequency of SCEs in human PLC and the cell-cycle progression of both human and pig lymphocytes in a time-dependent manner. Two possible hypotheses for the heightened frequency of SCEs of human lymphocytes in RBC-free cultures were assessed. The loss of RBC-to-lymphocyte cellular contact in PLC did not influence the SCE frequencies of lymphocytes. Finally, the increase of SCEs in human PLC could not be related to differences in the generation time of lymphocytes in culture.

Genotoxic and cytotoxic in vitro evaluation of ivermectin and its formulation ivomec® on Aedes albopictus larvae (CCL-126™) cells

Genotoxic effects of ivermectin (IVM) and its commercial formulation ivomec® (IVM 1.0%) were studied on Aedes albopictus larvae (CCL-126™) cells by sister chromatid exchange (SCE) and single cell gel electrophoresis (SCGE) while cytotoxicity was determined by cell-cycle progression (CCP), proliferative rate index (PRI), mitotic index (MI), 3(4,5-dimethylthiazol-2-yl)-2,5-diphenyltetrazolium bromide (MTT), and neutral red (NR) endpoints within a 1–250 µg mL−1 concentration range. While IVM and ivomec® did not markedly affect SCE frequencies, these agents induced DNA-strand breaks enhancing both slightly damaged and damaged cells at 25–50 and 5–50 µg mL−1 IVM and ivomec®, respectively. Both compounds exerted a delay in CCP and reduction of PRI at 10 µg mL−1. Cytotoxicity was observed at concentrations higher than 25 µg mL−1. A marked reduction of about 98% and 94% of MI compared to controls was noted with 25 µg mL−1 of IVM and ivomec®, respectively. NR and MTT assays revealed that both compounds induced a cell growth inhibition within the 1–250 µg mL−1 concentration range. Data indicated that IVM and ivomec® exert both genotoxicity and cytotoxicity in insect cells in vitro, at least in A. albopictus larvae CCL-126™ cells.

Testing genotoxicity and cytotoxicity strategies for the evaluation of commercial radiosterilized fetal calf sera.

Effects of 18 commercial lots of fetal calf serum (FCS) after gamma-irradiation and their non-irradiated counterparts were comparatively analyzed on CHO-K1 and MDBK MDL1 cells for genotoxicity [sister chromatid exchange (SCE), micronuclei (MNi), and single cell gel electrophoresis (SCGE)], cytotoxicity [cell-cycle progression (CCP), proliferative replication index (PRI), mitotic index (MI), growth promotion (GP), and plating efficiency (PE)], and microbiological properties (mycoplasma and bovine viral diarrhea virus contamination). SCE and SCGE were the most informative end-points for genotoxicity since significant differences were found in 44.4% (P<0.05-0.001, Students t-test) and 61.1% (P<0.05-0.001, chi(2) test) samples, respectively. MI was the cytotoxicity assay revealing the greatest variation, showing differences in 66.7% (P<0.05-0.001, chi(2) test) samples. Thus, these three end-points for screening bioproducts such as FCS were found most suitable for detecting potential geno-cytotoxicants in biological samples; their simultaneous use could be strongly recommended.

Pig plasma modulates cell cycle kinetics but not the baseline frequency of sister-chromatid exhanges in human lymphocytes

The effect of human and pig plasma on the baseline frequency of sister-chromatid exchanges (SCEs) in human and porcine plasma leukocyte cultures was studied. Human plasma leukocyte cultures, but not porcine plasma leukocyte cultures, showed at least a twofold increase in SCE frequency over whole blood culture values. Addition of pig plasma to human plasma leukocyte cultures and human plasma to pig plasma leukocyte cultures did not modify the baseline SCE frequencies. In both human and porcine cultures, cell proliferation was slower in plasma leukocyte cultures than in whole blood cultures. The addition of pig plasma to human plasma leukocyte cultures, but not the incorporation of human plasma in pig plasma leukocyte cultures, accelerated the cell cycle progression of lymphocytes. With 10% pig plasma in the plasma leukocyte culture medium, lymphocyte proliferation was similar to that in whole blood cultures. Smaller concentrations of pig plasma rendered cell cycle progression intermediate between the basal plasma leukocyte culture and whole blood culture values. Exchanging fetal calf serum for human AB serum in human plasma leukocyte cultures did not affect the cell cycle kinetics of lymphocytes but it did decrease their baseline SCE frequency.

Erythrocytes modulate cell cycle progression but not the baseline frequency of sister chromatid exchanges in pig lymphocytes

Foi estudado o efeito de co-culturas com concentracoes variadas de celulas sanguineas vermelhas (RBCs) suinas e humanas na frequencia basal de trocas de cromatides irmas (SCEs) e na progressao do ciclo celular em culturas de plasma de porco (PLCs) e culturas leucocitarias do sangue total (WBCs). Nao foi observada nenhuma variacao na frequencias de SCEs entre os controles de WBC e PLC em porcos. A adicao de RBCs de suinos e humanos a PLCs nao modificou a frequencia basal de SCEs. Por outro lado, a proliferacao celular foi mais lenta em PLCs que em WBCs. A adicao de RBCs humanas ou suinas a PLCs acelerou a progressao do ciclo celular de linfocitos suinos. Quando RBCs foram adicionadas a PLCs, a concentracao e a sequencia temporal da incorporacao de RBC afetaram a progressao do ciclo celular de linfocitos suinos. Quando adicionadas doses de RBCs suinas ou humanas equivalentes aquelas presentes em WBCs, imediatamente apos estimulacao da PLC, a cinetica do ciclo celular foi similar a das WBCs. Periodos mais curtos de co-incubacao ou uma reducao na dose de RBCs causaram uma progressao do ciclo celular intermediaria entre os valores de PLCs e WBCs. Assim, RBCs suinas e humanas modularam a progressao do ciclo celular in vitro de linfocitos suinos em uma maneira dependente da dose e do tempo, e a frequencia basal baixa de SCEs de linfocitos suinos independe da presenca ou nao de eritrocitos na cultura