Sepsis is a comprehensive ailment of systemic inflammatory response syndrome arising from infection. Activation of CASPASE-1 plays a central role in initiating the inflammatory cascade during sepsis. Herein, we construct optogenetically engineered extracellular vesicles (EVs) that achieve the specific degradation of CASPASE-1 and inhibit sepsis-associated inflammation. Specifically, blue light (460 nm)-induced CRY2/CIBN heterodimerization was applied during the EVs production stage to selectively load GCE-CTM fusion proteins into EVs by EXPLORs technology, yielding EVs GCE-CTM loading efficiency compared to conventional methods. Upon systemic delivery, EVs GCE-CTM preferentially accumulated in macrophages, where the GCE domain selectively bound activated CASPASE-1. The CTM motif then facilitated its lysosomal degradation by chaperone-mediated autophagy, resulting in potent inhibition of CASPASE-1 activity. In a murine model of sepsis, treatment with EVs GCE-CTM effectively attenuated systemic inflammation, reduced multi-organ damage, and significantly improved survival outcomes. This approach enables highly efficient, ubiquitin-independent degradation of intracellular target proteins through macrophage-directed EVs delivery, offering a potential therapeutic approach to address sepsis and other inflammation-related diseases. EVs GCE-CTM , an optogenetically engineered extracellular vesicle targeting CASPASE1 for degradation, suppresses IL18 and IL1 β , reducing inflammation and alleviating sepsis in macrophages.
Du et al. (Fri,) studied this question.