Extracellular Matrix Downregulation in the Drosophila Heart Preserves Contractile Function and Improves Lifespan

Overview

Journal Matrix Biol

Publisher Elsevier

Specialties Biochemistry
Molecular Biology

Date 2016 Nov 8

PMID 27793636

Citations 18

Authors

Ayla O Sessions

Gaurav Kaushik

Sarah Parker

Koen Raedschelders

Rolf Bodmer

Jennifer E Van Eyk

Adam J Engler

Affiliations

Soon will be listed here.

Abstract

Aging is associated with extensive remodeling of the heart, including basement membrane (BM) components that surround cardiomyocytes. Remodeling is thought to impair cardiac mechanotransduction, but the contribution of specific BM components to age-related lateral communication between cardiomyocytes is unclear. Using a genetically tractable, rapidly aging model with sufficient cardiac genetic homology and morphology, e.g. Drosophila melanogaster, we observed differential regulation of BM collagens between laboratory strains, correlating with changes in muscle physiology leading to cardiac dysfunction. Therefore, we sought to understand the extent to which BM proteins modulate contractile function during aging. Cardiac-restricted knockdown of ECM genes Pericardin, Laminin A, and Viking in Drosophila prevented age-associated heart tube restriction and increased contractility, even under viscous load. Most notably, reduction of Laminin A expression correlated with an overall preservation of contractile velocity with age and extension of organismal lifespan. Global heterozygous knockdown confirmed these data, which provides new evidence of a direct link between BM homeostasis, contractility, and maintenance of lifespan.

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