Novel formylpeptide receptor 1/2 agonist limits hypertension-induced cardiovascular damage

Singh, Jaideep; Jackson, Kristy L; Fang, Haoyun; Gumanti, Audrey; Claridge, Bethany; Tang, Feng Shii; Kiriazis, Helen; Salimova, Ekaterina; Parker, Alex M; Nowell, Cameron; Woodman, Owen L; Greening, David; Ritchie, Rebecca; Head, Geoffrey A; Qin, Cheng Xue

doi:10.26181/27184392.v1

Novel formylpeptide receptor 1/2 agonist limits hypertension-induced cardiovascular damage

journal contribution

posted on 2024-10-08, 01:32 authored by Jaideep Singh, Kristy L Jackson, Haoyun Fang, Audrey Gumanti, Bethany Claridge, Feng Shii Tang, Helen Kiriazis, Ekaterina Salimova, Alex M Parker, Cameron Nowell, Owen L Woodman, David GreeningDavid Greening, Rebecca RitchieRebecca Ritchie, Geoffrey A Head, Cheng Xue Qin

AIMS: Formylpeptide receptors (FPRs) play a critical role in the regulation of inflammation, an important driver of hypertension-induced end-organ damage. We have previously reported that the biased FPR small-molecule agonist, compound17b (Cmpd17b), is cardioprotective against acute, severe inflammatory insults. Here, we reveal the first compelling evidence of the therapeutic potential of this novel FPR agonist against a longer-term, sustained inflammatory insult, i.e. hypertension-induced end-organ damage. The parallels between the murine and human hypertensive proteome were also investigated.

METHODS AND RESULTS: The hypertensive response to angiotensin II (Ang II, 0.7 mg/kg/day, s.c.) was attenuated by Cmpd17b (50 mg/kg/day, i.p.). Impairments in cardiac and vascular function assessed via echocardiography were improved by Cmpd17b in hypertensive mice. This functional improvement was accompanied by reduced cardiac and aortic fibrosis and vascular calcification. Cmpd17b also attenuated Ang II-induced increased cardiac mitochondrial complex 2 respiration. Proteomic profiling of cardiac and aortic tissues and cells, using label-free nano-liquid chromatography with high-sensitivity mass spectrometry, detected and quantified ∼6000 proteins. We report hypertension-impacted protein clusters associated with dysregulation of inflammatory, mitochondrial, and calcium responses, as well as modified networks associated with cardiovascular remodelling, contractility, and structural/cytoskeletal organization. Cmpd17b attenuated hypertension-induced dysregulation of multiple proteins in mice, and of these, ∼110 proteins were identified as similarly dysregulated in humans suffering from adverse aortic remodelling and cardiac hypertrophy.

CONCLUSION: We have demonstrated, for the first time, that the FPR agonist Cmpd17b powerfully limits hypertension-induced end-organ damage, consistent with proteome networks, supporting development of pro-resolution FPR-based therapeutics for treatment of systemic hypertension complications.

Funding

This work was partly funded by the National Heart Foundation (NHF, Vanguard grant) of Australia (APP102885 to C.X.Q., K.L.J., R.H.R., and G.A.H), the Australian Medical Research Future Fund (MRFF1201805 to D.W.G), the NHMRC Ideas grants (APP2013158 to D.W.G) and the Victorian Government of Australia’s Operational Infrastructure Support Program. C.X.Q. is supported by a NHF Future Leader Fellowship. K.L.J. is supported by the NHMRC ECR Fellowship. D.W.G. is supported by Hains Fellowship. J.S. is supported by the Monash Graduate Scholarship. H.F. is supported by Research training programme scholarship along with Bright Sparks Top-up scholarship.

History

Publication Date

2024-07-01

Journal

Cardiovascular Research

Volume

120

Issue

11

Pagination

15p. (p. 1336-1350)

Publisher

Oxford University Press

ISSN

0008-6363

Rights Statement

© The Author(s) 2024. Published by Oxford University Press on behalf of the European Society of Cardiology. This is an Open Access article distributed under the terms of the Creative Commons Attribution License (https://creativecommons.org/licenses/by/4.0/), which permits unrestricted reuse, distribution, and reproduction in any medium, provided the original work is properly cited.