Epigenetics have essential roles in development and human diseases. Compared to the complex histone modifications, epigenetic changes on mammalian DNA are as simple as methylation on cytosine. Guanine, however, can be oxidized as an epigenetic change which can undergo base-pair transversion, causing a genetic difference. Accumulating evidence indicates that reactive oxygen species (ROS) are important signaling molecules for embryonic stem cell (ESC) differentiation, possibly through transient changes on genomic DNA such as 7,8-dihydro-8-oxoguanine (8-oxoG). Technical limitations on detecting such DNA modifications, however, restrict the investigation of the role of 8-oxoG in ESC differentiation. Here, we developed a Hoogsteen base pairing-mediated PCR-sequencing assay to detect 8-oxoG lesions that can subsequently cause G to T transversions during PCR. We then used this assay to assess the epigenetic and transient 8-oxoG formation in the Tbx5 gene of R1 mouse ESCs subjected to oxidative stress by removing 2-mercaptoethanol (2ME) from the culture media. To our surprise, significantly higher numbers of 8-oxoG-mediated G∙C to C∙G transversion, not G∙C to T∙A, were detected at 7th and 9th base position from the transcription start site of exon 1 of Tbx5 in ESCs in the (-)2ME than (+)2ME group (p < 0.05). This was consistent with the decrease in the amount of amplifiable of DNA harboring the 8-oxoG lesions at the Tbx5 promoter region in the oxidative stressed ESCs. The ESCs responded to oxidative stress, possibly through the epigenetic effects of guanine oxidation with decreased proliferation (p < 0.05) and increased formation of beating embryoid bodies (EBs; p < 0.001). Additionally, the epigenetic changes of guanine induced up-regulation of Ogg1 and PolB, two base excision repairing genes for 8-oxoG, in ESCs treated with (-)2ME (p < 0.01). Together, we developed a gene-specific and direct quantification assay for guanine oxidation. Using oxidative stressed mouse ESCs, we validated this assay and assessed the epigenetic effects of 8-oxoG by studying expression of DNA repair genes, ESC proliferation, and EB formation.
Fertilization rates and subsequent embryo development rely on sperm factors related to semen quality and viability. Photobiomodulation therapy (PBMT) is based on emission of electromagnetic waves of a laser optical system that interact with cells and tissues resulting in biological effects. This interaction is mediated by photoacceptors that absorb the electromagnetic energy. Effects are dependent of irradiation parameters, target cell type, and species. In sperm, PBMT improves several features like motility and viability, affecting sperm aerobic metabolism and energy production. The aim of this study was to investigate, under same conditions, how different output powers (5, 7.5, and 10 mW) and time of irradiation (5 and 10 min) of laser (He-Ne laser, 633 nm) may affect frozen/thawed bovine sperm functions. Results showed significant effects depending on power while using 10 min of irradiation on motility parameters and mitochondrial potential. However, no effect was observed using 5 min of irradiation, regardless of power applied. In conclusion, PBMT is effective to modulate bovine sperm function. The effectiveness is dependent on the interaction between power applied and duration of irradiation, showing that these two parameters simultaneously influence sperm function. In this context, when using the same fluency and energy with different combinations of power and time of exposure, we observed distinct effects, revealing that biological effects should be also based on simple parameters rather than only composite parameters such as fluency, irradiance and energy. Laser irradiation of frozen/thawed bovine semen led to an increase on mitochondrial function and motility parameters that could potentially improve fertility rates.
The aim of this study was to compare 2 different techniques to obtain swine oocytes from abattoir ovaries. Ovaries were washed in saline at 35°C and submitted to slashing or aspiration, simultaneously. For the slashing group, ovaries were held with a hemostat inside a beaker containing 35 mL of HEPES-buffered Tyrode’s media (HbT) and follicles (2–6 mm) were incised with a scalpel. For every 5 slashed ovaries, HbT-containing follicular fluid was transferred to 50-mL centrifuge tubes. For the aspiration group, follicles (2–6 mm) were aspirated using an 18-gauge needle and a 5-mL syringe. The follicular fluid of each ovary was transferred to a 50-mL centrifuge tube. Tubes from both techniques were placed in a water bath at 35°C for 15 min to allow settling of the cumulus–oocyte complexes (COC). The supernatant was removed and the sediment was resuspended in HbT and placed in water bath at 35°C for an additional 15 min. The sediment was resuspended in 15 mL of HbT and COC were recovered under stereomicroscopy. Oocytes were in vitro matured for 44 h in TCM-199 added with 10% porcine follicular fluid (PFF) and hormones (LH and FSH) at 38.5°C, 5% CO2 and high humidity. The oocyte recovery rate of each technique was determined by the ratio between the number of COC and ovaries used. To verify nuclear maturation by epifluorescence microscopy (Zeiss), oocytes were fixed, permeabilized, and incubated in 10 μg mL–1 of RNAse for 30 min and in 10 μg mL–1 of propidium iodide for 10 min. Heat shock protein 70 (HSP70) content was assessed as described in Kawarsky and King (2001 Zygote 9(3), 39–50) to verify the metabolic stress. Data were analyzed by ANOVA and Tukey’s test using the software Statistica for Windows. A level of 5% was considered significant in all assessments. The oocyte recovery rate (COC/ovary) was higher for the slashing group (2.665 ± 0.38) compared with the aspiration group (1.762 ± 0.15). The percentage of oocytes that reached the germinative vesicle (GV) stage (h 0 of maturation) did not differ between groups (100 ± 0 and 86.66 ± 13.36, slashing and aspiration group, respectively). The same was observed for the percentage of oocytes that reached the metaphase II stage (MII, after 44 of maturation; 79.99 ± 9.74 and 96.00 ± 4.00, slashing and aspiration group, respectively). Moreover, no difference at pixel quantification of HSP70 was observed between groups (256.50 ± 42.42 and 238.61 ± 71.18, slashing and aspiration group, respectively). In conclusion, the slashing procedure provided a better oocyte recovery rate compared with the aspiration of ovaries. This technique does not affect nuclear maturation, because no differences were observed regarding the percentage of oocytes that reached the GV and MII stages. In addition, it does not affect HSP70 content, suggesting that the slashing of ovaries does not increase the basal stress of oocytes in an in vitro-maturation system.
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