ABSTRACT Pulmonary hypertension (PH) is characterized by endothelial dysfunction, irregular vascular remodeling and consistent vasoconstriction leading to eventual fatal right heart failure despite current medical therapies. The most common drug targets in PH are G protein coupled receptors (GPCRs), which are a target for almost a third of all FDA-approved drugs. Although these receptors have been studied intensely for over 40 years, several aspects of GPCR signaling remain poorly understood. Canonically, it has been well established that these receptors are able to signal through both heterotrimeric G proteins and β-arrestins (βarrs). These events were thought to be largely separable given that G proteins primarily initiate downstream signaling while βarrs can signal and regulate receptor desensitization and trafficking. Recent studies have suggested evidence for a combined role of G protein and βarr in GPCRs signaling through the formation of signaling “megaplexes” and the impairment of βarr-based signaling in the absence of functional G proteins. However, there remains a significant knowledge gap surrounding the significance of G protein and βarr coordinated signaling. Our long term aim is to understand the signaling mechanisms of GPCRs to provide better insight for the development of novel therapeutics for PH. In our recent studies, we have directly assessed whether G proteins and βarrs can interact across a panel receptors and were surprised to find that all receptors tested could form a complex between the inhibitory G protein (Gαi) and βarr, including the type 1 angiotensin II receptor (AT1R) and atypical chemokine receptor 3 (ACKR3, also known as CXCR7), which are both potential drug targets in PH. We further found that these complexes could interact with secondary effectors, most notably extracellular signal-regulated kinase (ERK). These results suggested a conserved, non-canonical role for Gαi:βarr signaling across GPCRs. Our overarching goal is to define the mechanism in which Gαi:βarr form complexes and understand their impact on physiology. We hypothesize that Gαi:βarr complex formation require a discrete set of motifs present in Gαi, βarrs and GPCRs and that these complexes regulate endothelial function in PH. To test this hypothesis, first I will determine the specific sequence motifs in Gαi, βarr and the receptor that are required to form Gαi:βarr complex. Second, I will determine the signalling pathways that are regulated by Gαi:βarr interaction using APEX proximity labeling and novel “complex BRET” assays. Third, I will determine the impact of Gai:βarr within PH patient endothelial cells by targeting Gαi and βarr signaling and testing their effects on endothelial function. This study strives to understand an emerging paradigm in GPCR signalling in which Gαi and βarr work together to orchestrate unique downstream signalling. Completion of these aims will provide novel insights for cell signalling, development of new pharmacologic...