Gremlin1 repression-mediated mitochondrial network hyperfunction contributes to TCE-induced zebrafish cardiac defects.

BACKGROUND: Trichloroethylene (TCE) is a ubiquitous pollutant with potential capacity to induce congenital heart disease (CHD). However, the mechanisms underlying TCE-induced CHD are largely unraveled. METHODS: We exposed zebrafish embryos to TCE to investigate its cardiac development toxicity and related response factor through bulk RNA sequencing. We constructed transgenic fluorescent fish and employed the CRISPR/dCas9 system along with single-cell RNA sequencing to identify the genetic cause of TCE-induced CHD. RESULTS: We found that early-stage exposure to TCE induced significant cardiac defects characterized by elongated SV-BA distance, thinned myocardium, and attenuated contractility. Gremlin1 encoding gene, grem1a, a putative target showing high expression at the beginning of cardiac development, was sharply down-regulated by TCE. Consistently, grem1a knockdown in zebrafish induced cardiac phenotypes generally like those of the TCE-treated group, accompanying the disarrangement of myofibril structure. Single-cell RNA-seq depicted that mitochondrial respiration in grem1a-repressed cardiomyocytes was greatly enhanced, ultimately leading to a branch from the normal trajectory of myocardial development. Accordingly, in vitro results demonstrated that GREM1 repression increased mitochondrial content, ATP production, mitochondrial reactive oxygen species, mitochondrial membrane potential, and disrupted myofibril expansion in hPSC-CMs. CONCLUSIONS: These results suggested that TCE-induced gremlin1 repression could result in mitochondrial hyperfunction, thereby hampering cardiomyocyte development and causing cardiac defects in zebrafish embryos. This study not only provided a novel insight into the etiology for environmental stressor-caused cardiac development defects, but also offered a potential therapeutic and preventive target for TCE-induced CHD.