The meninges are a membranous structure enveloping the central nervous system (CNS) that host a rich repertoire of immune cells mediating CNS immune surveillance. Here, we report that the meninges contain a pool of monocytes and neutrophils supplied not from the blood, but by adjacent skull and vertebral bone marrow. Under pathological conditions, including spinal cord injury and neuroinflammation, CNS-infiltrating myeloid cells can originate from brain borders and display transcriptional signatures distinct from their blood-derived counterparts. Thus, CNS borders are populated by myeloid cells from adjacent bone-marrow niches, strategically placed to supply innate immune cells under homeostatic and pathological conditions. These findings call for reinterpretation of immune-cell infiltration into the CNS during injury and autoimmunity and may inform future therapeutic approaches harnessing meningeal immune cells.
So far, intravenous tissue-type plasminogen activator (tPA) and mechanical
removal of arterial blood clot (thrombectomy) are the only available treatments
for acute ischemic stroke. However, the short therapeutic window and the lack of
specialized stroke unit care make the overall availability of both treatments
limited. Additional agents to combine with tPA administration or thrombectomy to
enhance efficacy and improve outcomes associated with stroke are needed.
Stroke-induced inflammatory processes are a response to the tissue damage due to
the absence of blood supply but have been proposed also as key contributors to
all the stages of the ischemic stroke pathophysiology. Despite promising results
in experimental studies, inflammation-modulating treatments have not yet been
translated successfully into the clinical setting. This review will (a) describe
the timing of the stroke immune pathophysiology; (b) detail the immune responses
to stroke sift-through cell type; and (c) discuss the pitfalls on the
translation from experimental studies to clinical trials testing the therapeutic
pertinence of immune modulators.
The increase of cerebral blood flow evoked by neuronal activity is essential to ensure enough energy supply to the brain. In the neurovascular unit, endothelial cells are ideally placed to regulate key neurovascular functions of the brain. Nevertheless, some outstanding questions remain about their exact role neurovascular coupling (NVC). Here, we postulated that the tissue-type plasminogen activator (tPA) present in the circulation might contribute to NVC by a mechanism dependent of its interaction with endothelial N-Methyl-D-Aspartate Receptor (NMDAR). To address this question, we used pharmacological and genetic approaches to interfere with vascular tPA-dependent NMDAR signaling, combined with laser speckle flowmetry, intravital microscopy and ultrafast functional ultrasound in vivo imaging. We found that the tPA present in the blood circulation is capable of potentiating the cerebral blood flow increase induced by the activation of the mouse somatosensorial cortex, and that this effect is mediated by a tPA-dependent activation of NMDAR expressed at the luminal part of endothelial cells of arteries. Although blood molecules, such as acetylcholine, bradykinin or ATP are known to regulate vascular tone and induce vessel dilation, our present data provide the first evidence that circulating tPA is capable of influencing neurovascular coupling (NVC).
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