Effects of chronic restraint stress on the global DNA methylation profile of rat lung cells: Modulation by physical exercise.

The potential of behavioral stress to affect epigenetic mechanisms of non-encephalic tissues is still underestimated. In the present study we evaluated the effects of chronic behavioral stress on the DNA methylation profile of rat lung cells. Furthermore, we evaluated the potential of physical exercise to modulate the changes evoked by behavioral stress in lung cells. Male Wistar rats were divided into four experimental groups: (1) animals submitted to chronic restraint stress (CRS) (ST group) during the period of the 67th-80th postnatal day (PND); (2) animals submitted to physical exercise (EX group) during the 53rd-79th PND; (3) animals submitted to swimming during the 53rd-79th PND and to CRS during the 67th-80th PND (EX-ST group); and (4) animals not submitted to stress or swimming protocols (CTL). Global DNA methylation was quantified using an ELISA-based approach and gene expression was evaluated by real time PCR. A decreased global DNA methylation profile was observed in the ST group, however physical exercise demonstrated protection of lung cells from this stress-related hypomethylation. Increased expression of the Dnmt1 gene was evidenced in the ST group, whereas physical exercise was shown to protect lung cells from this stress-related effect in the EX-ST group. Comparative analysis of the ST and EX groups revealed opposite effects on the expression of Dnmt3a and Dnmt3b; however, a stress-related increase in expression of Dnmt3a and Dnmt3b was not seen in the EX-ST group. Our data showed that behavioral stress induced significant changes in the DNA methylation profile of rat lung cells and that this could be modulated by physical exercise.

Physical exercise affects the epigenetic programming of rat brain and modulates the adaptive response evoked by repeated restraint stress.

Epigenetics has recently been linked to molecular adaptive responses evoked by physical exercise and stress. Herein we evaluated the effects of physical exercise on global DNA methylation and expression of the Dnmt1 gene in the rat brain and also verified its potential to modulate responses evoked by repeated restraint stress (RRS). Wistar rats were classified into the following experimental groups: (1) physically active (EX): animals submitted to swimming during postnatal days 53-78 (PND); (2) stress (ST): animals submitted to RRS during 75-79PND; (3) exercise-stress (EX-ST): animals submitted to swimming during 53-78PND and to RRS during 75-79PND, and (4) control (CTL): animals that were not submitted to intervention. Samples from the hippocampus, cortex and hypothalamus were obtained at 79PND. The global DNA methylation profile was assessed using an ELISA-based method and the expression of Dnmt1 was evaluated by real-time PCR. Significantly increased methylation was observed in the hypothalamus of animals from the EX group in comparison to CTL. Comparative analysis involving the EX-ST and ST groups revealed increased global DNA methylation in the hippocampus, cortex, and hypothalamus of EX-ST, indicating the potential of physical exercise in modulating the responses evoked by RRS. Furthermore, decreased expression of the Dnmt1 gene was observed in the hippocampus and hypothalamus of animals from the EX-ST group. In summary, our data indicate that physical exercise affects DNA methylation of the hypothalamus and might modulate epigenetic responses evoked by RRS in the hippocampus, cortex, and hypothalamus.