A tripartite structure, the complex nuclear receptor element (cNRE), is a cis-regulatory module of viral origin required for atrial chamber preferential gene expression

Optimal cardiac function requires appropriate contractile proteins in each heart chamber. Atria require slow myosins to act as variable reservoirs, while ventricles demand fast myosin for swift pumping functions. Hence, myosin is under chamber-biased cis-regulatory control to achieve this functional...

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Published inbioRxiv
Main Authors Luana Nunes Santos, Costa, Angela, Nikolov, Martin, Allysson Coelho Sampaio, Stockdale, Frank, Hozana Andrade Castillo, Mariana Bortoletto Grizante, Dudczig, Stefanie, Vasconcelos, Michelle, Rosenthal, Nadia, Jusuf, Patricia Regina, Lopes-De-Oliveira, Paulo, Matos, Tatiana, Nikovits, Wiliam, Schubert, Michael, Ramialison, Mirana, Xavier-Neto, Jose
Format Paper
LanguageEnglish
Published Cold Spring Harbor Cold Spring Harbor Laboratory Press 20.11.2021
Subjects
Animal models
Gene expression
Gene regulation
Heart diseases
Muscle contraction
Myosin
Regulatory sequences
Ventricle
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Summary:Optimal cardiac function requires appropriate contractile proteins in each heart chamber. Atria require slow myosins to act as variable reservoirs, while ventricles demand fast myosin for swift pumping functions. Hence, myosin is under chamber-biased cis-regulatory control to achieve this functional distribution. Failure in proper regulation of myosin genes can lead to severe congenital heart dysfunction. The precise regulatory input leading to cardiac chamber-biased expression remains uncharted. To address this, we computationally and molecularly dissected the quail Slow Myosin Heavy Chain III (SMyHC III) promoter that drives specific gene expression to the atria to uncover the regulatory information leading to chamber expression and understand their evolutionary origins. We show that SMyHC III gene states are autonomously orchestrated by a complex nuclear receptor cis-regulatory element (cNRE), a 32-bp sequence with hexanucleotide binding repeats. Using in vivo transgenic assays in zebrafish and mouse models, we demonstrate that preferential atrial expression is achieved by the combinatorial regulatory input composed of atrial activation motifs and ventricular repression motifs. Through comparative genomics, we provide evidence that the cNRE emerged from an endogenous viral element, most likely through infection of an ancestral host germline. Our study reveals an evolutionary pathway to cardiac chamber-specific expression. Competing Interest Statement The authors have declared no competing interest.
DOI:10.1101/2021.11.18.469087