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Microskeletal stiffness promotes aortic aneurysm by sustaining pathological vascular smooth muscle cell mechanosensation via Piezo1

Author

Listed:
  • Weiyi Qian

    (New York University)

  • Tarik Hadi

    (New York University Langone Medical Center)

  • Michele Silvestro

    (New York University Langone Medical Center)

  • Xiao Ma

    (New York University)

  • Cristobal F. Rivera

    (New York University Langone Medical Center)

  • Apratim Bajpai

    (New York University)

  • Rui Li

    (New York University)

  • Zijing Zhang

    (New York University)

  • Hengdong Qu

    (New York University Langone Medical Center)

  • Rayan Sleiman Tellaoui

    (New York University Langone Medical Center)

  • Annanina Corsica

    (New York University Langone Medical Center)

  • Ariadne L. Zias

    (New York University Langone Medical Center)

  • Karan Garg

    (New York University Langone Medical Center)

  • Thomas Maldonado

    (New York University Langone Medical Center)

  • Bhama Ramkhelawon

    (New York University Langone Medical Center
    New York University Langone Medical Center)

  • Weiqiang Chen

    (New York University
    New York University)

Abstract

Mechanical overload of the vascular wall is a pathological hallmark of life-threatening abdominal aortic aneurysms (AAA). However, how this mechanical stress resonates at the unicellular level of vascular smooth muscle cells (VSMC) is undefined. Here we show defective mechano-phenotype signatures of VSMC in AAA measured with ultrasound tweezers-based micromechanical system and single-cell RNA sequencing technique. Theoretical modelling predicts that cytoskeleton alterations fuel cell membrane tension of VSMC, thereby modulating their mechanoallostatic responses which are validated by live micromechanical measurements. Mechanistically, VSMC gradually adopt a mechanically solid-like state by upregulating cytoskeleton crosslinker, α-actinin2, in the presence of AAA-promoting signal, Netrin-1, thereby directly powering the activity of mechanosensory ion channel Piezo1. Inhibition of Piezo1 prevents mice from developing AAA by alleviating pathological vascular remodeling. Our findings demonstrate that deviations of mechanosensation behaviors of VSMC is detrimental for AAA and identifies Piezo1 as a novel culprit of mechanically fatigued aorta in AAA.

Suggested Citation

  • Weiyi Qian & Tarik Hadi & Michele Silvestro & Xiao Ma & Cristobal F. Rivera & Apratim Bajpai & Rui Li & Zijing Zhang & Hengdong Qu & Rayan Sleiman Tellaoui & Annanina Corsica & Ariadne L. Zias & Karan, 2022. "Microskeletal stiffness promotes aortic aneurysm by sustaining pathological vascular smooth muscle cell mechanosensation via Piezo1," Nature Communications, Nature, vol. 13(1), pages 1-19, December.
  • Handle: RePEc:nat:natcom:v:13:y:2022:i:1:d:10.1038_s41467-021-27874-5
    DOI: 10.1038/s41467-021-27874-5
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    Cited by:

    1. Nathalia G. Amado & Elena D. Nosyreva & David Thompson & Thomas J. Egeland & Osita W. Ogujiofor & Michelle Yang & Alexandria N. Fusco & Niccolo Passoni & Jeremy Mathews & Brandi Cantarel & Linda A. Ba, 2024. "PIEZO1 loss-of-function compound heterozygous mutations in the rare congenital human disorder Prune Belly Syndrome," Nature Communications, Nature, vol. 15(1), pages 1-12, December.

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