Spreading depolarization triggers pro- and anti-inflammatory signalling: a potential link to headache.

Cortical spreading depolarization (CSD), the neurophysiological event believed to underlie aura, may trigger migraine headaches through inflammatory signaling that originates in neurons and spreads to the meninges via astrocytes. Increasing evidence from studies on rodents and migraine patients supports this hypothesis. The transition from pro-inflammatory to anti-inflammatory mechanisms is crucial for resolving inflammation. However, the resolution of inflammation in the context of CSD and migraine headaches remains poorly understood. This study aims to elucidate the progression of post-CSD inflammatory signaling and its resolution in neurons, astrocytes, and microglia in mouse brains. CSD was triggered optogenetically or by pinprick. HMGB1 release, caspase-1 activation, and cell-specific activation of NF-κB pairs, along with ensuing transcriptomic changes, were evaluated using immunofluorescence, Western blotting, co-immunoprecipitation, FRET analysis, and cell-specific transcriptomics. Our findings indicate that after the initial burst, HMGB1 release from neurons ceased, and caspase-1 activation, which peaked 1-hour post-CSD, diminished within 3-5 hours. This suggests that pro-inflammatory stimuli driving inflammatory signaling decreased within hours after CSD. Pro-inflammatory NF-κB p65:p50 pairs, along with anti-inflammatory cRel:p65 pairs, were detected in astrocyte nuclei shortly after CSD. However, 24 hours post-CSD, the former had disappeared while the latter persisted, indicating a shift from pro-inflammatory to anti-inflammatory activity in astrocytes. Pathway analysis of cell-specific transcriptomic data confirmed NF-κB-related pro-inflammatory transcription in astrocytes 1-hour post-CSD, while no such activity was observed in neurons. Detailed transcriptomic analysis with Bayesian cell proportion reconstruction revealed that microglia exhibited transcriptional changes trending towards an anti-inflammatory profile, along with upregulation of several chemokines and cytokines (e.g., TNF). This suggests that microglia may play a role in supporting the inflammatory responses in astrocytes through the release of these mediators. The upregulation of genes involved in chemotaxis (e.g., Ccl3) and spine pruning (e.g., C1q) in microglia implies that microglia may contribute to synaptic repair, while inflammatory signaling in astrocytes could potentially modulate meningeal nociceptor activity through an extensive astrocyte endfeet syncytium abutting subarachnoid and perivascular spaces although direct evidence remains incomplete. This nuanced understanding of the inflammatory response in CNS cell types highlights the intricate cellular interactions and responses to CSD. Following a single CSD, distinct transcriptomic responses occur in neurons, astrocytes, and microglia, driving inflammatory and anti-inflammatory responses, potentially contributing to headache initiation and resolution.