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  • br Acknowledgments This study is a

    2024-10-08


    Acknowledgments This study is a part of a MSc thesis and supported by Scientific Research Projects Coordination Unit of Akdeniz University (grant number: 2011.02.0122.007).
    Introduction Apelin receptor (putative receptor protein related to the angiotensin receptor AT1, APJ) belongs to the G-protein-coupled receptors (GPCRs) [1], [2], whose endogenous ligand apelins are emerging as a key hormone in cardiovascular homoeostasis [3], [4]. Amongst all apelins, apelin-13 binds with high affinity to and associates with APJ more efficiently than apelin-36 and rapidly dissociates from APJ in Chinese hamster ovary (CHO) UNC 0642 engineered to express the cloned human APJ [5]. Apelins mediate a variety of physiological processes including neuroprotection, pain, fluid homoeostasis, endocrine and metabolic functions. One of the key emerging features of the apelin-APJ system is its interaction with the renin–angiotensin system [3], [6]. New research has found that APJ has a dual role in cardiac hypertrophy through different signalling pathways [7]. Apelin activates APJ signals via the G protein pathway and elicits a cardiac protective response, whereas sustained overload activates APJ to induce cardiac hypertrophy via a G protein-independent fashion. Hence, the apelin-APJ system is expected to be a therapeutic target for treatment of heart failure, hypertension, and obesity-related diseases. In the last decade, there has been a substantial re­evaluation of the classic assumption that GPCRs undergo conformational alterations after agonist binding and initiate a GDP/GTP exchange at the Gα subunit in order to activate Gα and Gβγ, which interact with downstream effectors, such as phosphoinositide 3-kinases (PI3K), adenylyl cyclase (AC), phospholipases (PLC) and ion channels [8], [9]. For example, using Förster resonance energy transfer (FRET), Gαi subunits were discovered to undergo rearrangement instead of dissociation during adrenergic receptor activation by noradrenaline, which illustrates the complexity of G-protein signalling [10]. Understanding the profile of G-proteins coupled to APJ could provide more detailed information about the molecular link between activation of APJ and its biological effects. Previous research has discovered that forskolin-stimulated cAMP production is suppressed by apelin-13, indicating APJ was hypothesized to couple to Gαi/o [11]. Moreover, the activation of ERK1/2 by apelin is mediated via PKC in HEK293 cells expressing mouse APJ, indicative of coupling to either Gαo or Gαq [12]. Here, we use BRET and FRET to analyze the dynamics of G-protein coupling to human APJ in real time, which not only confirms the binding of Gαi2, Gαo and Gαq, but also demonstrates the activation of Gαi3 after APJ stimulated with apelin-13. We also found that during APJ activation, Gαo and Gαq subunits will dissociate with Gβ1γ2 via the classic model. Interestingly, using both BRET and FRET we found Gαi2, Gαi3 and Gβ1γ2 subunits undergo a re-arrangement without subunit dissociation upon apelin-13 stimulation, which provide new evidence to support this novel theory about this specific activation pattern of Gαi.
    Materials and Methods
    Results
    Discussion G-proteins convert many pharmacological and physiological stimuli to cellular responses [23]. Canonically, G-protein coupled receptors (GPCRs) can activate G-protein subunit dissociation into Gα and Gβγ [9], [24], which initiate particular signalling pathways, respectively, responding to neurotransmitters and hormones. For a long time, it is generally accepted that only dissociated G-protein α subunits play a specified role in receptor signal transduction. However, in recent years this dissociation model has been challenged as being a robust cellular response mechanism to stimuli [10], [16], [24], [25]. Recently, Robishaw and Berlot [26] have brought up a ‘clamshell’ model, predicting that each βγ dimer remains closely associated with the alpha subunit on the receptor. In the past decade, with the emergence of novel technology, especially FRET and BRET, real-time and dynamic observation of the interaction between two proteins in living cells became topical and achievable [17], [22], [27], [28]. Monika Frank has revealed the specific mechanisms of Gαi activation through rearrangement instead of dissociation using FRET in noradrenaline stimulated adrenergic receptor model [24]. Here we also found that activation of APJ with apelin-13 also leads to the activation of Gαi through this unique mechanism which was also confirmed by BRET technology. It indicates that the rearrangement of Gαi during the activation is independent of the type of GPCRs, or at least widely exists.