Neurobiology of Disease (Nov 2022)
CCL2 recruits fetal microchimeric cells and dampens maternal brain damage in post-partum mice
Abstract
Preventing brain cell loss and enhancing tissue repair are crucial objectives to improve the outcome of stroke. Fetal microchimerism has been implicated in brain repair following ischemic stroke in mice. CCL2/CCR2 signaling pathway triggers fetal progenitors trafficking to cutaneous wounds. Therefore, we sought to evaluate whether CCL2 could dampen brain damage in a model of excitotoxic lesion in post-partum mice.Virgin or post-partum mice were subjected to an intracerebral injection of ibotenate to induce excitotoxic lesions. Low doses of CCL2 or its vehicle were concomitantly injected. Morphological and molecular analyses were performed 1 and 5 days following the procedure.Intracerebral treatment with low doses of CCL2 was able to limit brain excitotoxic damage induced by ibotenate in post-partum mice, through an enhanced recruitment of fetal microchimeric cells to the damaged hemisphere. At day 1 post-injection, we observed a decreased cortical apoptosis associated with a reduced reactive astrocytosis. At day 5, we found an increased proportion of mature neurons and oligodendrocytes correlating with an increase in GAP43 growth cones. At this stage, immune microglial cells were reduced, while angiogenesis was enhanced. Importantly, CCL2 did not have beneficial effects in virgin mice therefore ruling out a specific role of CCL2 independently from fetal microchimeric cells mobilization.CCL2 treatment efficiently enhances fetal cell mobilization to improve the outcome of a brain excitotoxic challenge in post-partum mice. This study paves the way for a “natural stem cell therapy” based on the selective recruitment of fetal progenitors to repair maternal brain injury.
