A novel NIR fluorescent probe to image HNO during ferroptosis

Background: As an important reactive nitrogen species (RNS), HNO has been identified as an essential signaling molecule in many physiological processes. Ferroptosis produces a large amount of reactive oxygen species and reactive nitrogen species. However, the detailed mechanism of HNO during process of ferroptosis is rarely reported, especially in the near-infrared range. So, we designed a new near-infrared (NIR) HNO fluorescent probe X-1 based on a tricyanofuran (TCF) derivative and then applied it in ferroptosis imaging. The TCF derivative was chosen as the NIR fluorophore and 2-(diphenylphosphino)benzoate was used as the recognition group. Results: In this paper, a novel NIR HNO fluorescent probe X-1 based on tricyanofuran (TCF) derivatives was synthesized using the Staudinger linkage reaction. X-1 exhibited high selectivity for HNO in the near-infrared region (lem = 660 nm). When the recognition group undergoes the Staudinger linkage reaction with HNO, the NIR fluorescence emission increased significantly with the enhancement of the ICT effect. The response mechanism of X-1 to HNO was verified by high-resolution mass spectrometry (HRMS). Probe X-1 has the advantages of fast response (5 min), low detection limit, a large Stokes shift (120 nm) and strong anti-interference ability for HNO recognition. CCK-8 staining result indicates that the probe X-1 has good biocompatibility and little toxic effect on the cells. The probe was successfully applied to imaging the exogenous and endogenous HNO in living cells. Significance: In the near-infrared range, HNO was discovered as a mediator of cellular signaling molecules, increasing in concentration during the process of ferroptosis. Furthermore, using this probe, it was further verified that sorafenib, a commonly used drug for cancer treatment, exerts its therapeutic effect by inducing ferroptosis in cancer cells, leading to cell death.