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NOSTRIN belongs to the family of F-BAR proteins, which are multi-domain adaptor proteins that have emerged as important regulators of membrane remodeling and actin dynamics in a variety of vital cellular processes. They have been analyzed structurally and biochemically and overexpression studies have revealed their potential in inducing membrane curvature and tubulation. Several studies have begun to decipher the function of individual proteins, but the understanding of F-BAR protein functions in vivo is still quite limited. The F-BAR protein NOSTRIN is mainly expressed in endothelial cells and has originally been described as interaction partner of the endothelial nitric oxide synthase (eNOS), modulating eNOS subcellular localization. The phenotypic characterization of NOSTRIN knockout mice revealed decreased nitric oxide (NO) and cGMP levels, an increase in systolic blood pressure and an impairment of the acetylcholine-induced, NO-dependent relaxation of aortic rings from mice with global as well as endothelial cell-specific knockout of the NOSTRIN gene (ECKO) . These findings implied that NOSTRIN plays a role in regulating NO production in vivo, but the underlying molecular mechanisms were unclear. Therefore, this study was aimed at addressing the mechanism causing the inhibited vasodilation specifically upon stimulation with acetylcholine in NOSTRIN KO and ECKO mice, and at exploring additional roles of NOSTRIN in the signal transduction of endothelial cells.
The major acetylcholine receptor that mediates vessel relaxation upon stimulation with acetylcholine is the muscarinic acetylcholine receptor subtype M3 (M3R). In the present study NOSTRIN was identified as novel interaction partner of the M3R and important factor for the correct spatial distribution and functionality of the M3R. Moreover, it provides the first example of an F-BAR protein regulating a GPCR. Confocal immunofluorescence microscopy analysis of isolated aortae from NOSTRIN KO and WT mice indicated that NOSTRIN was necessary for the proper subcellular localization of the M3R and targeted it to the plasma membrane. A series of pulldown experiments revealed a direct interaction of NOSTRIN with the M3R. The binding required the SH3 domain of NOSTRIN and the third intracellular loop of the M3R, which has a recognized role in receptor regulation. The interaction of NOSTRIN with the M3R was confirmed by co-localization of NOSTRIN and the M3R upon overexpression in mammalian cells. Expression levels of the M3R as well as eNOS were not affected by the loss of NOSTRIN in accordance with the finding, that NOSTRIN impacts on the acetylcholine/eNOS signaling axis through regulation of the subcellular trafficking of its binding partners.
Furthermore, there were first indications for a role of NOSTRIN in facilitating the carbachol-induced calcium response in M3R-expressing cells, suggesting that NOSTRIN might influence M3R activation. in the absence of NOSTRIN, the function of the M3R in mammalian cells overexpressing the M3R was markedly impaired, resulting in abolition of the calcium response to the M3R agonist carbachol. In accordance, the activated eNOS fraction associated with the Golgi complex was markedly reduced in aorta explants from NOSTRIN knockout and ECKO mice. Moreover, NOSTRIN knockout inhibited the carbachol-induced, activating phosphorylation of eNOS in murine aortae as well as primary mouse lung endothelial cells confirming its role as important regulator of eNOS activity in vivo.
Background and Aim: Genome-wide association studies revealed a strong association between cardiovascular diseases (CVD) and clonal hematopoiesis of indeterminate potential (CHIP), highlighting one of its most common CHIP-driving mutations-TET2 (ten-eleven translocation 2), as a target for CHIP related CVD research. Our lab has established the generation of self-organizing cardiac organoids (SCO), which demonstrate the cellular composition and organization of the native human heart, and mimics human myocardial responses to stress stimulation. This project aims to examine whether SCOs would be an appropriate CHIP model and decipher promising drugs for cardiovascular CHIP treatment.
Methods: To study TET2-mutant cardiovascular CHIP, we set up the TET2 cardiac-CHIP model through a knockdown (KD) of TET2 in myeloid cells that infiltrated our lab-made SCO. Immunofluorescence and qPCR were performed to ascertain TET2-KD myeloid cell infiltration, SCO fibrosis, and apoptosis assessments. SCO fibrosis was further analyzed by immunofluorescence staining, and cardiac contractile frequency and amplitude were determined by calcium flux analysis. Finally, RNAseq was performed to analyze transcriptomic changes in drug/vehicle-treated TET2-KD myeloid cells and the TET2 cardiac-CHIP model.
Results: The TET2 cardiac-CHIP model resulted in significantly increased inflammation in SCO, accompanied by fibrosis and more cleaved Caspase-3, causing cardiomyocytes apoptosis and promoting the release of cTNT. The shortlisted drugs revealed a reduction of proliferation in TET2-KD myeloid cells, decreased pro-inflammatory cytokines, and a higher apoptosis level. Furthermore, the TET2 cardiac-CHIP model treated with selected drugs showed a remarkable decline in TET2-KD myeloid cell infiltration and pro-inflammation cytokines, cardiomyocyte apoptosis, fibrosis, and lowered cTNT levels, while drug control groups were not affected. Moreover, the drug treatment groups improved the heartbeat frequency and amplitude accessed by the calcium transient assay. RNAseq data also validated the above findings.
Conclusions & Discussion: Our results indicate that SCOs are an efficient pre-clinical model for studying and validating CHIP genes and drug interactions. Our data revealed that TET2-KD myeloid cells invade SCO and secrete pro-inflammatory cytokines, which promote apoptosis of cardiomyocytes and the release of cTNT. In this regard, our TET2 cardiac-CHIP model matches the inflammatory phenotype previously characterized in CHIP patients. Nevertheless, this phenotype could be rescued using positive drug candidates (Clopidogrel, R406, and Lanatoside C) selected by this project, emphasizing the significant value of our TET2 cardiac-CHIP model for drug screens and pre-clinical validation studies. Furthermore, among these three drug candidates, we found Lancatoside C, as proved by FDA/EMA, showed an unmet possibility for clinical therapeutic demand, insinuating potential benefit in repurposing Lanatoside C for the treatment of TET2-mutant cardiovascular CHIP.