Transcriptomic Analysis of Gill and Kidney from Asian Seabass (<i>Lates calcarifer</i>) Acclimated to Different Salinities Reveals Pathways Involved with Euryhalinity

Transcriptomic Analysis of Gill and Kidney from Asian Seabass (<i>Lates calcarifer</i>) Acclimated to Different Salinities Reveals Pathways Involved with Euryhalinity

Asian seabass (or commonly known as barramundi), <i>Lates calcarifer,</i> is a bony euryhaline teleost from the Family<i> Latidae</i>, inhabiting nearshore, estuarine, and marine connected freshwaters throughout the tropical Indo-West Pacific region. The species is catadromou...

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Main Authors: Shubha Vij, Kathiresan Purushothaman, Prakki Sai Rama Sridatta, Dean R. Jerry
Format: Article
Language:English
Published: MDPI AG 2020-06-01
Series:Genes
Subjects:
euryhalinity
Asian seabass
fish
osmoregulation
acclimation
transcriptome
Online Access:https://www.mdpi.com/2073-4425/11/7/733
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spelling doaj-266887dbcabd4348a5144d01de47c58b2020-11-25T03:53:24ZengMDPI AGGenes2073-44252020-06-011173373310.3390/genes11070733Transcriptomic Analysis of Gill and Kidney from Asian Seabass (<i>Lates calcarifer</i>) Acclimated to Different Salinities Reveals Pathways Involved with EuryhalinityShubha Vij0Kathiresan Purushothaman1Prakki Sai Rama Sridatta2Dean R. Jerry3Reproductive Genomics Group, Temasek Life Sciences Laboratory, Singapore 117604, SingaporeReproductive Genomics Group, Temasek Life Sciences Laboratory, Singapore 117604, SingaporeReproductive Genomics Group, Temasek Life Sciences Laboratory, Singapore 117604, SingaporeTropical Futures Institute, James Cook University, Singapore 387380, SingaporeAsian seabass (or commonly known as barramundi), <i>Lates calcarifer,</i> is a bony euryhaline teleost from the Family<i> Latidae</i>, inhabiting nearshore, estuarine, and marine connected freshwaters throughout the tropical Indo-West Pacific region. The species is catadromous, whereby adults spawn in salinities between 28 and 34 ppt at the mouth of estuaries, with resultant juveniles usually moving into brackish and freshwater systems to mature, before returning to the sea to spawn again as adults. The species lives in both marine and freshwater habitats and can move quickly between the two; thus, the species’ ability to tolerate changes in salinity makes it a good candidate for studying the salinity acclimation response in teleosts. In this study, the transcriptome of two major osmoregulatory organs (gills and kidneys) of young juvenile Asian seabass reared in freshwater and seawater were compared. The euryhaline nature of Asian seabass was found to be highly pliable and the moldability of the trait was further confirmed by histological analyses of gills and kidneys. Differences in major expression pathways were observed, with differentially expressed genes including those related to osmoregulation, tissue/organ morphogenesis, and cell volume regulation as central to the osmo-adaptive response. Additionally, genes coding for mucins were upregulated specifically under saline conditions, whereas several genes important for growth and development, as well as circadian entrainment were specifically enriched in fish reared in freshwater. Routing of the circadian rhythm mediated by salinity changes could be the initial step in salinity acclimation and possibly migration in euryhaline fish species such as the Asian seabass.https://www.mdpi.com/2073-4425/11/7/733euryhalinityAsian seabassfishosmoregulationacclimationtranscriptome
collection DOAJ
language English
format Article
sources DOAJ
author Shubha Vij
Kathiresan Purushothaman
Prakki Sai Rama Sridatta
Dean R. Jerry
spellingShingle Shubha Vij
Kathiresan Purushothaman
Prakki Sai Rama Sridatta
Dean R. Jerry
Transcriptomic Analysis of Gill and Kidney from Asian Seabass (<i>Lates calcarifer</i>) Acclimated to Different Salinities Reveals Pathways Involved with Euryhalinity
Genes
euryhalinity
Asian seabass
fish
osmoregulation
acclimation
transcriptome
author_facet Shubha Vij
Kathiresan Purushothaman
Prakki Sai Rama Sridatta
Dean R. Jerry
author_sort Shubha Vij
title Transcriptomic Analysis of Gill and Kidney from Asian Seabass (<i>Lates calcarifer</i>) Acclimated to Different Salinities Reveals Pathways Involved with Euryhalinity
title_short Transcriptomic Analysis of Gill and Kidney from Asian Seabass (<i>Lates calcarifer</i>) Acclimated to Different Salinities Reveals Pathways Involved with Euryhalinity
title_full Transcriptomic Analysis of Gill and Kidney from Asian Seabass (<i>Lates calcarifer</i>) Acclimated to Different Salinities Reveals Pathways Involved with Euryhalinity
title_fullStr Transcriptomic Analysis of Gill and Kidney from Asian Seabass (<i>Lates calcarifer</i>) Acclimated to Different Salinities Reveals Pathways Involved with Euryhalinity
title_full_unstemmed Transcriptomic Analysis of Gill and Kidney from Asian Seabass (<i>Lates calcarifer</i>) Acclimated to Different Salinities Reveals Pathways Involved with Euryhalinity
title_sort transcriptomic analysis of gill and kidney from asian seabass (<i>lates calcarifer</i>) acclimated to different salinities reveals pathways involved with euryhalinity
publisher MDPI AG
series Genes
issn 2073-4425
publishDate 2020-06-01
description Asian seabass (or commonly known as barramundi), <i>Lates calcarifer,</i> is a bony euryhaline teleost from the Family<i> Latidae</i>, inhabiting nearshore, estuarine, and marine connected freshwaters throughout the tropical Indo-West Pacific region. The species is catadromous, whereby adults spawn in salinities between 28 and 34 ppt at the mouth of estuaries, with resultant juveniles usually moving into brackish and freshwater systems to mature, before returning to the sea to spawn again as adults. The species lives in both marine and freshwater habitats and can move quickly between the two; thus, the species’ ability to tolerate changes in salinity makes it a good candidate for studying the salinity acclimation response in teleosts. In this study, the transcriptome of two major osmoregulatory organs (gills and kidneys) of young juvenile Asian seabass reared in freshwater and seawater were compared. The euryhaline nature of Asian seabass was found to be highly pliable and the moldability of the trait was further confirmed by histological analyses of gills and kidneys. Differences in major expression pathways were observed, with differentially expressed genes including those related to osmoregulation, tissue/organ morphogenesis, and cell volume regulation as central to the osmo-adaptive response. Additionally, genes coding for mucins were upregulated specifically under saline conditions, whereas several genes important for growth and development, as well as circadian entrainment were specifically enriched in fish reared in freshwater. Routing of the circadian rhythm mediated by salinity changes could be the initial step in salinity acclimation and possibly migration in euryhaline fish species such as the Asian seabass.
topic euryhalinity
Asian seabass
fish
osmoregulation
acclimation
transcriptome
url https://www.mdpi.com/2073-4425/11/7/733
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