High-throughput MicroRNA Sequencing in the Developing Branchial Arches Suggests MiR-92b-3p Regulation of a Cardiovascular Gene Network

Overview

Journal Front Genet

Date 2025 Mar 7

PMID 40051700

Authors

Sian Goldsworthy

Marta Losa

Nicoletta Bobola

Sam Griffiths-Jones

Affiliations

Soon will be listed here.

Abstract

Vertebrate branchial arches (BAs) are a developmental paradigm, undergoing coordinated differentiation and morphogenesis to form various adult derivative tissues. MicroRNAs can strengthen gene regulatory networks (GRNs) to promote developmental stability. To investigate microRNA-mediated regulation in BA development, we generated a novel microRNA-sequencing dataset from mouse BAs. We identified 550 expressed microRNAs, of which approximately 20% demonstrate significant differential expression across BA domains. The three most posterior BAs and the connecting outflow tract (PBA/OFT) express genes important for cardiovascular development. We predicted microRNA-target interactions with PBA/OFT-expressed cardiovascular genes and found target sites for miR-92b-3p to be enriched. We used a dual luciferase assay to validate miR-92b-3p interactions with two transcripts encoding the fundamental cardiac transcription factors (TFs), and . Furthermore, we demonstrated that miR-92b-3p mimic can downregulate endogenous and in human embryonic stem cells (hESCs) undergoing cardiomyocyte differentiation, confirming microRNA-target binding can occur in a cardiac cell type. miR-92b-3p has previously been shown to target transcripts encoding for two other cardiac TFs, and Therefore, we hypothesise that miR-92b-3p acts to stabilise cardiovascular GRNs during PBA/OFT development, through multiple microRNA-mediated regulatory networks.

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