Epigenetic modulation of inflammation and synaptic plasticity promotes resilience against stress in mice.
Jun WangGeorgia E HodesHongxing ZhangSong ZhangWei ZhaoSam A GoldenWeina BiCaroline MénardVeronika KanaMarylene LeboeufMarc XieDana BregmanMadeline L PfauMeghan E FlaniganAdelaida Esteban-FernándezShrishailam YemulAli SharmaLap HoRichard A DixonMiriam MeradMing-Hu HanScott J RussoGiulio Maria PasinettiPublished in: Nature communications (2018)
Major depressive disorder is associated with abnormalities in the brain and the immune system. Chronic stress in animals showed that epigenetic and inflammatory mechanisms play important roles in mediating resilience and susceptibility to depression. Here, through a high-throughput screening, we identify two phytochemicals, dihydrocaffeic acid (DHCA) and malvidin-3'-O-glucoside (Mal-gluc) that are effective in promoting resilience against stress by modulating brain synaptic plasticity and peripheral inflammation. DHCA/Mal-gluc also significantly reduces depression-like phenotypes in a mouse model of increased systemic inflammation induced by transplantation of hematopoietic progenitor cells from stress-susceptible mice. DHCA reduces pro-inflammatory interleukin 6 (IL-6) generations by inhibiting DNA methylation at the CpG-rich IL-6 sequences introns 1 and 3, while Mal-gluc modulates synaptic plasticity by increasing histone acetylation of the regulatory sequences of the Rac1 gene. Peripheral inflammation and synaptic maladaptation are in line with newly hypothesized clinical intervention targets for depression that are not addressed by currently available antidepressants.
Keyphrases
- dna methylation
- major depressive disorder
- oxidative stress
- genome wide
- depressive symptoms
- gene expression
- climate change
- bipolar disorder
- mouse model
- social support
- stress induced
- sleep quality
- randomized controlled trial
- copy number
- high fat diet induced
- resting state
- bone marrow
- stem cells
- adipose tissue
- multiple sclerosis
- heat stress
- physical activity
- chemotherapy induced
- drug induced
- cerebral ischemia
- cell migration