RESUMO
Although chloroacetonitrile (CAN), a disinfection by-product of chlorination of drinking water, is considered a rodent carcinogen that induces lung adenomas in mice, previous studies on its genotoxicity have yielded inconclusive results. Thus, its cancer mode of action has not been clearly defined. We evaluated CAN-induced genotoxicity in mice using mouse bone marrow micronucleus test, comet assays and expression of genes associated with DNA damage repair. Mice exposed to CAN at 8.75, 17.5, 35 and 52.5mg/kg for 7 days did not exhibit any significant increases in the incidence of micronuclei formation at 24 and 48h after last exposure. However, CAN caused significant suppressions of erythroblast proliferation at the highest dose. In the alkaline comet assay, there was a significant increase in the incidence of DNA strand breaks in mice killed after 3h of last treatment with 35 and 52.5mg/kg/day CAN, while no significant difference in the DNA strand breaks was found in mice killed after 24h of the last treatment. However, slight (but significant) CAN-induced oxidative DNA damage was detected following Fpg digestion at 3-h sampling time, digestion with EndoIII resulted in considerable increases in oxidative DNA damage at 3 and 24h after the last exposure to 35 and 52.5mg/kg/day CAN as detected by oxidative comet assays. The expression of DNA repair genes OGG1 , Apex1, PARP1 and p53 were up-regulated in mice given 35mg/kg/day CAN at 3h but not in 24h after the last treatment except OGG1 . However, the significant up-regulation of OGG1 at 24h after the last treatment further indicates the occurrence of oxidative DNA damage. Overall, CAN exposure is associated with up-regulation of DNA repair gene expression and the induction of oxidative DNA damage, which may be at least partially responsible for CAN-induced genotoxicity and eventually cause carcinogenicity.
RESUMO
The objective of the experiment of this paper is to develop and improve in the sexing method for preimplantation embryos of water buffalo (Bubalus bubalis) using loop-mediated isothermal amplification (LAMP) reaction. Embryo sexing has been recognized to control effectively the sex of offspring in the embryo transfer industry. A rapid and simple detection system was established by adding ethidium bromide (EB) or 5 µl of CuSO4 (3M) to the product of LAMP reaction. The result of these additions after 2 min was a color change and a precipitate. It could be employed as an alternative method in the detection of the reaction products in place of the time consuming electrophoresis or the turbidity meter. The in vitro produced buffalo embryos were divided into one to eight pieces using a microblade attached to a micromanipulator. The cell number in each piece was counted before sexing. Sexing of DNA samples extracted from one to five biopsies cells was performed by LAMP. After biopsy, the remaining part of the embryos was used to confirm the sex by polymerase chain reaction (PCR). Fifty buffalo embryos were used and the accuracy of sex prediction was 100% when the blastomeres dissociated from a morula exceeds three. In conclusion, the present procedure without turbidity meter and electrophoresis was reliable and applicable for sexing the water buffalo embryos.