Israeli insight into depression could lead to new fast-acting drugs
Of mice and microglia
Most research into clinical depression targets the brain’s neuron cells, while the involvement of other types of brain cells has not been thoroughly examined, Yirmiya explained. Curious about the workings of microglia, the researchers devised an experiment that mimicked chronic unpredictable stress in humans — a leading cause of depression — by exposing mice to repeated, unpredictable stressful conditions over a period of five weeks.
The mice developed behavioral and neurological symptoms mirroring those seen in depressed humans, including a reduction in pleasurable activity and in social interaction, as well as reduced generation of new brain cells (neurogenesis). Decreased neurogenesis is seen an important biological marker of depression.
During the first week of stress exposure, microglia cells actively proliferate and cause the production of specific inflammatory molecules, and then the cells begin to die. Over five weeks of stress exposure, this pattern resulted in a reduction in the number of microglia, and to a degenerated appearance of some microglia cells, particularly in a specific region of the brain involved in stress response.
When the researchers blocked the initial stress-induced activation of microglia with drugs or genetic manipulation, they were able to stop the subsequent microglia cell death and decline, as well as the depressive symptoms and suppressed neurogenesis. “We were able to demonstrate that such microglia-stimulating drugs served as effective and fast-acting antidepressants, producing complete recovery of the depressive-like behavioral symptoms, as well as increasing the neurogenesis to normal levels within a few days of treatment,” Yirmiya said.
However, these treatments were not effective in mice that had already been exposed to the five-week stress period and therefore had a lower number of microglia at the start of treatment. Based on these findings, the investigators treated the “depressed” mice with drugs that stimulated the microglia and increased their number to a normal level.
“In addition to the clinical importance of these results, our findings provide the first direct evidence that in addition to neurons, disturbances in the functioning of brain microglia cells have a role in causing psychopathology in general, and depression in particular,” said Yirmiya. “This suggests new avenues for drug research, in which microglia stimulators could serve as fast-acting antidepressants in some forms of depressive and stress-related conditions.”
Abigail Klein Leichman