Abstract
Acute lung injury (ALI) pathogenesis is intricately linked to microvascular permeability. Soluble guanylate cyclase (sGC) is prominently expressed in the vascular system, playing a central role in vascular function. In contrast, its expression and function diminish notably during the progression of ALI, indicating sGC's potential significance as a pivotal modulator in the pathological processes of ALI. Nonetheless, the precise localization of sGC within lung tissue and its distinct mechanism in maintaining vascular homeostasis remain unclear. Furthermore, there is a necessity for a pharmacological agent capable of consistently activating sGC for the treatment of ALI. A novel sGC stimulator, sGC003, was engineered through structural modification of Riociguat. In a mouse model of ALI, sGC003 exhibited superior sGC activation and more potent anti-inflammatory effects relative to Riociguat. It also exhibited superior efficacy in improving respiratory function and reducing pulmonary edema. Through single-cell RNA sequencing and immunofluorescence co-localization analysis, we confirmed predominant expression of soluble guanylate cyclase in pericytes. The sGC stimulators were found to modulate the LPS-induced pericyte transcriptome reprogramming via the nitric oxide (NO)-sGC-cyclic guanosine monophosphate (cGMP) pathway. Differential gene expression analysis categorized pericytes into nine distinct subgroups, which were sequentially activated during vascular development, inflammation, and myofibrosis. Pseudotime analysis revealed that sGC003 more effectively suppressed the myofibroblast differentiation of pericytes compared to Riociguat. In conclusion, sGC003 mitigates ALI-induced pulmonary inflammation by modulating pericyte differentiation, particularly in preserving microvascular integrity outstanding performance. Its exceptional efficacy suggests that it could potentially serve as a safer and more efficient option as a novel sGC stimulant in the future.