A comparative analysis of heart microRNAs in vertebrates brings novel insights into the evolution of genetic regulatory networks

Abstract Background During vertebrate evolution, the heart has undergone remarkable changes that lead to morphophysiological differences in the fully formed heart of these species, such as chamber septation, heart rate frequency, blood pressure, and cardiac output volume. Despite these differences,...

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Main Authors: Pedro G. Nachtigall, Luiz A. Bovolenta, James G. Patton, Bastian Fromm, Ney Lemke, Danillo Pinhal
Format: Article
Language:English
Published: BMC 2021-03-01
Series:BMC Genomics
Subjects:
Online Access:https://doi.org/10.1186/s12864-021-07441-4
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spelling doaj-c20ad12303eb40508da0777f6ac6ca002021-03-11T11:53:49ZengBMCBMC Genomics1471-21642021-03-0122112010.1186/s12864-021-07441-4A comparative analysis of heart microRNAs in vertebrates brings novel insights into the evolution of genetic regulatory networksPedro G. Nachtigall0Luiz A. Bovolenta1James G. Patton2Bastian Fromm3Ney Lemke4Danillo Pinhal5Laboratório Especial de Toxinologia Aplicada (LETA), CeTICS, Instituto ButantanDepartment of Biophysics and Pharmacology, Institute of Biosciences of Botucatu, São Paulo State University (UNESP)Department of Biological Sciences, Vanderbilt UniversityDepartment of Molecular Biosciences, The Wenner-Gren Institute (MBW), Stockholm UniversityDepartment of Biophysics and Pharmacology, Institute of Biosciences of Botucatu, São Paulo State University (UNESP)Department of Chemical and Biological Sciences, Institute of Biosciences of Botucatu, São Paulo State University (UNESP)Abstract Background During vertebrate evolution, the heart has undergone remarkable changes that lead to morphophysiological differences in the fully formed heart of these species, such as chamber septation, heart rate frequency, blood pressure, and cardiac output volume. Despite these differences, the heart developmental process is guided by a core gene set conserved across vertebrates. Nonetheless, the regulatory mechanisms controlling the expression of genes involved in heart development and maintenance are largely uncharted. MicroRNAs (miRNAs) have been described as important regulatory elements in several biological processes, including heart biology. These small RNA molecules are broadly conserved in sequence and genomic context in metazoans. Mutations may occur in miRNAs and/or genes that contribute to the establishment of distinct repertoires of miRNA-target interactions, thereby favoring the differential control of gene expression and, consequently, the origin of novel phenotypes. In fact, several studies showed that miRNAs are integrated into genetic regulatory networks (GRNs) governing specific developmental programs and diseases. However, studies integrating miRNAs in vertebrate heart GRNs under an evolutionary perspective are still scarce. Results We comprehensively examined and compared the heart miRNome of 20 species representatives of the five major vertebrate groups. We found 54 miRNA families with conserved expression and a variable number of miRNA families with group-specific expression in fishes, amphibians, reptiles, birds, and mammals. We also detected that conserved miRNAs present higher expression levels and a higher number of targets, whereas the group-specific miRNAs present lower expression levels and few targets. Conclusions Both the conserved and group-specific miRNAs can be considered modulators orchestrating the core and peripheral genes of heart GRNs of vertebrates, which can be related to the morphophysiological differences and similarities existing in the heart of distinct vertebrate groups. We propose a hypothesis to explain evolutionary differences in the putative functional roles of miRNAs in the heart GRNs analyzed. Furthermore, we present new insights into the molecular mechanisms that could be helping modulate the diversity of morphophysiology in the heart organ of vertebrate species.https://doi.org/10.1186/s12864-021-07441-4Small RNANon-coding RNAFunctional genomicsComparative genomicsCardiac miRNAsGenetic regulatory network
collection DOAJ
language English
format Article
sources DOAJ
author Pedro G. Nachtigall
Luiz A. Bovolenta
James G. Patton
Bastian Fromm
Ney Lemke
Danillo Pinhal
spellingShingle Pedro G. Nachtigall
Luiz A. Bovolenta
James G. Patton
Bastian Fromm
Ney Lemke
Danillo Pinhal
A comparative analysis of heart microRNAs in vertebrates brings novel insights into the evolution of genetic regulatory networks
BMC Genomics
Small RNA
Non-coding RNA
Functional genomics
Comparative genomics
Cardiac miRNAs
Genetic regulatory network
author_facet Pedro G. Nachtigall
Luiz A. Bovolenta
James G. Patton
Bastian Fromm
Ney Lemke
Danillo Pinhal
author_sort Pedro G. Nachtigall
title A comparative analysis of heart microRNAs in vertebrates brings novel insights into the evolution of genetic regulatory networks
title_short A comparative analysis of heart microRNAs in vertebrates brings novel insights into the evolution of genetic regulatory networks
title_full A comparative analysis of heart microRNAs in vertebrates brings novel insights into the evolution of genetic regulatory networks
title_fullStr A comparative analysis of heart microRNAs in vertebrates brings novel insights into the evolution of genetic regulatory networks
title_full_unstemmed A comparative analysis of heart microRNAs in vertebrates brings novel insights into the evolution of genetic regulatory networks
title_sort comparative analysis of heart micrornas in vertebrates brings novel insights into the evolution of genetic regulatory networks
publisher BMC
series BMC Genomics
issn 1471-2164
publishDate 2021-03-01
description Abstract Background During vertebrate evolution, the heart has undergone remarkable changes that lead to morphophysiological differences in the fully formed heart of these species, such as chamber septation, heart rate frequency, blood pressure, and cardiac output volume. Despite these differences, the heart developmental process is guided by a core gene set conserved across vertebrates. Nonetheless, the regulatory mechanisms controlling the expression of genes involved in heart development and maintenance are largely uncharted. MicroRNAs (miRNAs) have been described as important regulatory elements in several biological processes, including heart biology. These small RNA molecules are broadly conserved in sequence and genomic context in metazoans. Mutations may occur in miRNAs and/or genes that contribute to the establishment of distinct repertoires of miRNA-target interactions, thereby favoring the differential control of gene expression and, consequently, the origin of novel phenotypes. In fact, several studies showed that miRNAs are integrated into genetic regulatory networks (GRNs) governing specific developmental programs and diseases. However, studies integrating miRNAs in vertebrate heart GRNs under an evolutionary perspective are still scarce. Results We comprehensively examined and compared the heart miRNome of 20 species representatives of the five major vertebrate groups. We found 54 miRNA families with conserved expression and a variable number of miRNA families with group-specific expression in fishes, amphibians, reptiles, birds, and mammals. We also detected that conserved miRNAs present higher expression levels and a higher number of targets, whereas the group-specific miRNAs present lower expression levels and few targets. Conclusions Both the conserved and group-specific miRNAs can be considered modulators orchestrating the core and peripheral genes of heart GRNs of vertebrates, which can be related to the morphophysiological differences and similarities existing in the heart of distinct vertebrate groups. We propose a hypothesis to explain evolutionary differences in the putative functional roles of miRNAs in the heart GRNs analyzed. Furthermore, we present new insights into the molecular mechanisms that could be helping modulate the diversity of morphophysiology in the heart organ of vertebrate species.
topic Small RNA
Non-coding RNA
Functional genomics
Comparative genomics
Cardiac miRNAs
Genetic regulatory network
url https://doi.org/10.1186/s12864-021-07441-4
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