Table_4_Transcriptomics and Fitness Data Reveal Adaptive Plasticity of Thermal Tolerance in Oysters Inhabiting Different Tidal Zones.XLS

Fine-scale adaptive evolution is always constrained by strong gene flow at vertical level in marine organisms. Rapid environmental fluctuations and phenotypic plasticity through optimization of fitness-related traits in organisms play important roles in shaping intraspecific divergence. The coastal...

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Bibliographic Details
Main Authors: Ao Li, Li Li, Wei Wang, Kai Song, Guofan Zhang
Format: Dataset
Language:unknown
Published: 2018
Subjects:
Physiology
Exercise Physiology
Nutritional Physiology
Reproduction
Cell Physiology
Systems Physiology
Animal Physiology - Biophysics
Animal Physiology - Cell
Animal Physiology - Systems
Comparative Physiology
Physiology not elsewhere classified
adaptive divergence
evolutionary trade-offs
global warming
oyster
phenotypic plasticity
fitness-related trait
transcriptomic
Pacific
Crassostrea gigas
Pacific oyster
Online Access:https://doi.org/10.3389/fphys.2018.00825.s004
https://figshare.com/articles/Table_4_Transcriptomics_and_Fitness_Data_Reveal_Adaptive_Plasticity_of_Thermal_Tolerance_in_Oysters_Inhabiting_Different_Tidal_Zones_XLS/7012751
id ftfrontimediafig:oai:figshare.com:article/7012751
record_format openpolar
spelling ftfrontimediafig:oai:figshare.com:article/7012751 2023-05-15T15:59:05+02:00 Table_4_Transcriptomics and Fitness Data Reveal Adaptive Plasticity of Thermal Tolerance in Oysters Inhabiting Different Tidal Zones.XLS Ao Li Li Li Wei Wang Kai Song Guofan Zhang 2018-08-27T14:12:12Z https://doi.org/10.3389/fphys.2018.00825.s004 https://figshare.com/articles/Table_4_Transcriptomics_and_Fitness_Data_Reveal_Adaptive_Plasticity_of_Thermal_Tolerance_in_Oysters_Inhabiting_Different_Tidal_Zones_XLS/7012751 unknown doi:10.3389/fphys.2018.00825.s004 https://figshare.com/articles/Table_4_Transcriptomics_and_Fitness_Data_Reveal_Adaptive_Plasticity_of_Thermal_Tolerance_in_Oysters_Inhabiting_Different_Tidal_Zones_XLS/7012751 CC BY 4.0 CC-BY Physiology Exercise Physiology Nutritional Physiology Reproduction Cell Physiology Systems Physiology Animal Physiology - Biophysics Animal Physiology - Cell Animal Physiology - Systems Comparative Physiology Physiology not elsewhere classified adaptive divergence evolutionary trade-offs global warming oyster phenotypic plasticity fitness-related trait transcriptomic Dataset 2018 ftfrontimediafig https://doi.org/10.3389/fphys.2018.00825.s004 2018-08-29T22:57:18Z Fine-scale adaptive evolution is always constrained by strong gene flow at vertical level in marine organisms. Rapid environmental fluctuations and phenotypic plasticity through optimization of fitness-related traits in organisms play important roles in shaping intraspecific divergence. The coastal systems experience strong variations in multiple abiotic environmental factors, especially the temperature. We used a typical intertidal species, Pacific oyster (Crassostrea gigas), to investigate the interaction between plasticity and adaptive evolution. We collected intertidal and subtidal oysters from two ecological niches and carried out common garden experiments for one generation. We identified fine-scale vertical adaptive divergence between intertidal and subtidal F 1 progeny at both sites, based on different hierarchical phenotypes, including morphological, physiological, and molecular traits. We further quantified the global plasticity to thermal stress through transcriptomic analysis. The intertidal oysters exhibited slow growth rate. However, they showed high survival and metabolic rates under heat stress, indicating vertically fine-scale phenotypic adaptive mechanisms and evolutionary trade-offs between growth and thermal tolerance. Transcriptomic analysis confirmed that the intertidal oysters have evolved high plasticity. The genes were classified into three types: evolutionarily divergent, concordantly plastic, and adaptive plastic genes. The evolved divergence between intertidal and subtidal oysters for these gene sets showed a significant positive correlation with plastic changes of subtidal populations in response to high temperature. Furthermore, the intertidal oysters exhibited delayed large-scale increase in expressional plasticity than that in subtidal counterparts. The same direction between plasticity and selection suggests that the oysters have evolved adaptive plasticity. This implies that adaptive plasticity facilitates the oyster to adapt to severe intertidal zones. The oysters exposed to ... Dataset Crassostrea gigas Pacific oyster Frontiers: Figshare Pacific
institution Open Polar
collection Frontiers: Figshare
op_collection_id ftfrontimediafig
language unknown
topic Physiology
Exercise Physiology
Nutritional Physiology
Reproduction
Cell Physiology
Systems Physiology
Animal Physiology - Biophysics
Animal Physiology - Cell
Animal Physiology - Systems
Comparative Physiology
Physiology not elsewhere classified
adaptive divergence
evolutionary trade-offs
global warming
oyster
phenotypic plasticity
fitness-related trait
transcriptomic
spellingShingle Physiology
Exercise Physiology
Nutritional Physiology
Reproduction
Cell Physiology
Systems Physiology
Animal Physiology - Biophysics
Animal Physiology - Cell
Animal Physiology - Systems
Comparative Physiology
Physiology not elsewhere classified
adaptive divergence
evolutionary trade-offs
global warming
oyster
phenotypic plasticity
fitness-related trait
transcriptomic
Ao Li
Li Li
Wei Wang
Kai Song
Guofan Zhang
Table_4_Transcriptomics and Fitness Data Reveal Adaptive Plasticity of Thermal Tolerance in Oysters Inhabiting Different Tidal Zones.XLS
topic_facet Physiology
Exercise Physiology
Nutritional Physiology
Reproduction
Cell Physiology
Systems Physiology
Animal Physiology - Biophysics
Animal Physiology - Cell
Animal Physiology - Systems
Comparative Physiology
Physiology not elsewhere classified
adaptive divergence
evolutionary trade-offs
global warming
oyster
phenotypic plasticity
fitness-related trait
transcriptomic
description Fine-scale adaptive evolution is always constrained by strong gene flow at vertical level in marine organisms. Rapid environmental fluctuations and phenotypic plasticity through optimization of fitness-related traits in organisms play important roles in shaping intraspecific divergence. The coastal systems experience strong variations in multiple abiotic environmental factors, especially the temperature. We used a typical intertidal species, Pacific oyster (Crassostrea gigas), to investigate the interaction between plasticity and adaptive evolution. We collected intertidal and subtidal oysters from two ecological niches and carried out common garden experiments for one generation. We identified fine-scale vertical adaptive divergence between intertidal and subtidal F 1 progeny at both sites, based on different hierarchical phenotypes, including morphological, physiological, and molecular traits. We further quantified the global plasticity to thermal stress through transcriptomic analysis. The intertidal oysters exhibited slow growth rate. However, they showed high survival and metabolic rates under heat stress, indicating vertically fine-scale phenotypic adaptive mechanisms and evolutionary trade-offs between growth and thermal tolerance. Transcriptomic analysis confirmed that the intertidal oysters have evolved high plasticity. The genes were classified into three types: evolutionarily divergent, concordantly plastic, and adaptive plastic genes. The evolved divergence between intertidal and subtidal oysters for these gene sets showed a significant positive correlation with plastic changes of subtidal populations in response to high temperature. Furthermore, the intertidal oysters exhibited delayed large-scale increase in expressional plasticity than that in subtidal counterparts. The same direction between plasticity and selection suggests that the oysters have evolved adaptive plasticity. This implies that adaptive plasticity facilitates the oyster to adapt to severe intertidal zones. The oysters exposed to ...
format Dataset
author Ao Li
Li Li
Wei Wang
Kai Song
Guofan Zhang
author_facet Ao Li
Li Li
Wei Wang
Kai Song
Guofan Zhang
author_sort Ao Li
title Table_4_Transcriptomics and Fitness Data Reveal Adaptive Plasticity of Thermal Tolerance in Oysters Inhabiting Different Tidal Zones.XLS
title_short Table_4_Transcriptomics and Fitness Data Reveal Adaptive Plasticity of Thermal Tolerance in Oysters Inhabiting Different Tidal Zones.XLS
title_full Table_4_Transcriptomics and Fitness Data Reveal Adaptive Plasticity of Thermal Tolerance in Oysters Inhabiting Different Tidal Zones.XLS
title_fullStr Table_4_Transcriptomics and Fitness Data Reveal Adaptive Plasticity of Thermal Tolerance in Oysters Inhabiting Different Tidal Zones.XLS
title_full_unstemmed Table_4_Transcriptomics and Fitness Data Reveal Adaptive Plasticity of Thermal Tolerance in Oysters Inhabiting Different Tidal Zones.XLS
title_sort table_4_transcriptomics and fitness data reveal adaptive plasticity of thermal tolerance in oysters inhabiting different tidal zones.xls
publishDate 2018
url https://doi.org/10.3389/fphys.2018.00825.s004
https://figshare.com/articles/Table_4_Transcriptomics_and_Fitness_Data_Reveal_Adaptive_Plasticity_of_Thermal_Tolerance_in_Oysters_Inhabiting_Different_Tidal_Zones_XLS/7012751
geographic Pacific
geographic_facet Pacific
genre Crassostrea gigas
Pacific oyster
genre_facet Crassostrea gigas
Pacific oyster
op_relation doi:10.3389/fphys.2018.00825.s004
https://figshare.com/articles/Table_4_Transcriptomics_and_Fitness_Data_Reveal_Adaptive_Plasticity_of_Thermal_Tolerance_in_Oysters_Inhabiting_Different_Tidal_Zones_XLS/7012751
op_rights CC BY 4.0
op_rightsnorm CC-BY
op_doi https://doi.org/10.3389/fphys.2018.00825.s004
_version_ 1766394862138032128

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