Sequential Defects in Cardiac Lineage Commitment and Maturation Cause Hypoplastic Left Heart Syndrome

Overview

Journal Circulation

Specialty Cardiology & Vascular Diseases

Date 2021 Oct 25

PMID 34694888

Citations 26

Authors

Markus Krane

Martina Dressen

Gianluca Santamaria

Ilaria My

Christine M Schneider

Tatjana Dorn

Svenja Laue

Elisa Mastantuono

Riccardo Berutti

Hilansi Rawat

Ralf Gilsbach

Pedro Schneider

Harald Lahm

Sascha Schwarz

Stefanie A Doppler

Sharon Paige

Nazan Puluca

Sophia Doll

Irina Neb

Thomas Brade

Zhong Zhang

Claudia Abou-Ajram

Bernd Northoff

Lesca M Holdt

Stefanie Sudhop

Makoto Sahara

Alexander Goedel

Andreas Dendorfer

Fleur V Y Tjong

Maria E Rijlaarsdam

Julie Cleuziou

Nora Lang

Christian Kupatt

Connie Bezzina

Rudiger Lange

Neil E Bowles

Matthias Mann

Bruce D Gelb

Lia Crotti

Lutz Hein

Thomas Meitinger

Sean Wu

Daniel Sinnecker

Peter J Gruber

Karl-Ludwig Laugwitz

Alessandra Moretti

Affiliations

Soon will be listed here.

Abstract

Background: Complex molecular programs in specific cell lineages govern human heart development. Hypoplastic left heart syndrome (HLHS) is the most common and severe manifestation within the spectrum of left ventricular outflow tract obstruction defects occurring in association with ventricular hypoplasia. The pathogenesis of HLHS is unknown, but hemodynamic disturbances are assumed to play a prominent role.

Methods: To identify perturbations in gene programs controlling ventricular muscle lineage development in HLHS, we performed whole-exome sequencing of 87 HLHS parent-offspring trios, nuclear transcriptomics of cardiomyocytes from ventricles of 4 patients with HLHS and 15 controls at different stages of heart development, single cell RNA sequencing, and 3D modeling in induced pluripotent stem cells from 3 patients with HLHS and 3 controls.

Results: Gene set enrichment and protein network analyses of damaging de novo mutations and dysregulated genes from ventricles of patients with HLHS suggested alterations in specific gene programs and cellular processes critical during fetal ventricular cardiogenesis, including cell cycle and cardiomyocyte maturation. Single-cell and 3D modeling with induced pluripotent stem cells demonstrated intrinsic defects in the cell cycle/unfolded protein response/autophagy hub resulting in disrupted differentiation of early cardiac progenitor lineages leading to defective cardiomyocyte subtype differentiation/maturation in HLHS. Premature cell cycle exit of ventricular cardiomyocytes from patients with HLHS prevented normal tissue responses to developmental signals for growth, leading to multinucleation/polyploidy, accumulation of DNA damage, and exacerbated apoptosis, all potential drivers of left ventricular hypoplasia in absence of hemodynamic cues.

Conclusions: Our results highlight that despite genetic heterogeneity in HLHS, many mutations converge on sequential cellular processes primarily driving cardiac myogenesis, suggesting novel therapeutic approaches.

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