Department of Chemistry, Imperial College London, Molecular Sciences Research Hub, White City, London, W12 0BZ, UK.
Department of Neurology, Louisiana State University Health Sciences Center-Shreveport, Shreveport, LA, 71130, USA.
Theranostics. 2020 May 17;10(15):6599-6614. doi: 10.7150/thno.44226. eCollection 2020.
Inflammatory conditions are associated with a variety of diseases and can significantly contribute to their pathophysiology. Neutrophils are recognised as key players in driving vascular inflammation and promoting inflammation resolution. As a result, neutrophils, and specifically their surface formyl peptide receptors (FPRs), are attractive targets for non-invasive visualization of inflammatory disease states and studying mechanistic details of the process. : A small-molecule Formyl Peptide Receptor 2 (FPR2/ALX)-targeted compound was combined with two rhodamine-derived fluorescent tags to form firstly, a targeted probe (Rho-pip-C1) and secondly a targeted, pH-responsive probe (Rho-NH-C1) for applications. We tested internalization, toxicity and functional interactions with neutrophils for both compounds, as well as the fluorescence switching response of Rho-NH-C1 to neutrophil activation. Finally, imaging (fluorescent intravital microscopy [IVM]) and therapeutic efficacy studies were performed in an inflammatory mouse model. : studies showed that the compounds bound to human neutrophils via FPR2/ALX without causing internalization at relevant concentrations. Additionally, the compounds did not cause toxicity or affect neutrophil functional responses (e.g. chemotaxis or transmigration). studies using IVM showed Rho-pip-C1 bound to activated neutrophils in a model of vascular inflammation. The pH-sensitive ("switchable") version termed Rho-NH-C1 validated these findings, showing fluorescent activity only in inflammatory conditions. : These results indicate a viable design of fluorescent probes that have the ability to detect inflammatory events by targeting activated neutrophils.
炎症状态与多种疾病相关,并可显著影响其病理生理学。中性粒细胞被认为是驱动血管炎症和促进炎症消退的关键因素。因此,中性粒细胞及其表面的形式肽受体(FPR)是用于非侵入性可视化炎症疾病状态和研究该过程机制细节的有吸引力的靶标。本研究将小分子 Formyl Peptide Receptor 2(FPR2/ALX)靶向化合物与两个罗丹明衍生的荧光标记物结合,首先形成靶向探针(Rho-pip-C1),然后形成靶向、pH 响应探针(Rho-NH-C1)用于应用。我们测试了两种化合物的内化、毒性和与中性粒细胞的功能相互作用,以及 Rho-NH-C1 对中性粒细胞激活的荧光开关反应。最后,在炎症小鼠模型中进行了成像(荧光活体显微镜[IVM])和治疗效果研究。研究表明,这些化合物通过 FPR2/ALX 与人类中性粒细胞结合,在相关浓度下不会引起内化。此外,这些化合物不会引起毒性或影响中性粒细胞的功能反应(例如趋化性或迁移)。使用 IVM 的研究表明,Rho-pip-C1 在血管炎症模型中与激活的中性粒细胞结合。称为 Rho-NH-C1 的 pH 敏感(“可切换”)版本验证了这些发现,仅在炎症条件下显示荧光活性。这些结果表明设计出了可行的荧光探针,它们具有通过靶向激活的中性粒细胞来检测炎症事件的能力。
