Interactive Regulations of Dynamic Methylation and Transcriptional Responses to Recurring Environmental Stresses During Biological Invasions

Fu, Ruiying; Huang, Xuena; Chen, Yiyong; Chen, Zaohuang; Zhan, Aibin

doi:10.3389/fmars.2021.800745

Cited by 5 publications

(3 citation statements)

References 95 publications

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“…Gene expression is among the most well-known molecular plastic traits, mainly because transcriptional regulations, which link genotypes and phenotypes, can be immediately induced to cope with environmental stresses during many ecological and evolutionary processes ( Fu et al 2021 ; Josephs 2021 ). Many studies have examined the roles of gene expression plasticity in organismal acclimation and adaptation to various environmental changes.…”

Section: Introductionmentioning

confidence: 99%

Multidimensional plasticity jointly contributes to rapid acclimation to environmental challenges during biological invasions

Huang

Shenkar

et al. 2023

RNA

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Rapid plastic response to environmental changes, which involves extremely complex underlying mechanisms, is crucial for organismal survival during many ecological and evolutionary processes such as those in global change and biological invasions. Gene expression is among the most studied molecular plasticity, while co- or post-transcriptional mechanisms are still largely unexplored. Using a model invasive ascidian Ciona savignyi, we studied multidimensional short-term plasticity in response to hyper- and hypo-salinity stresses, covering the physiological adjustment, gene expression, alternative splicing (AS), and alternative polyadenylation (APA) regulations. Our results demonstrated that rapid plastic response varied with environmental context, timescales, and molecular regulatory levels. Gene expression, AS, and APA regulations independently acted on different gene sets and corresponding biological functions, highlighting their non-redundant roles in rapid environmental adaptation. Stress-induced gene expression changes illustrated the use of a strategy of accumulating free amino acid under high salinity and losing/reducing them during low salinity to maintain the osmotic homoeostasis. Genes with more exons were inclined to use AS regulations, and isoform switches in functional genes such as SLC2a5 and Cyb5r3 resulted in enhanced transporting activities by upregulating the isoforms with more transmembrane regions. The extensive 3'-untranslated region (3'UTR) shortening through APA was induced by both salinity stresses, and APA regulation predominated transcriptomic changes at some stages of stress response. The findings here provide evidence for complex plastic mechanisms to environmental changes, and thereby highlight the importance of systemically integrating different levels of regulatory mechanisms in studying initial plasticity in evolutionary trajectories.

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Section: Introductionmentioning

confidence: 99%

Multidimensional plasticity jointly contributes to rapid acclimation to environmental challenges during biological invasions

Huang

Shenkar

et al. 2023

RNA

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“…Recent advances have shown that epigenetic variation, particularly for the most commonly studied type in animals – DNA methylation – could not only change phenotypic outcomes but also contribute to evolutionary and adaptive potential of wild populations (Adrian‐Kalchhauser et al, 2020; Hu et al, 2019; Hu & Barrett, 2017). Unlike genetic variation, epigenetic variants can be directly influenced by environmental conditions and provide a faster route to respond to environmental change (Fu et al, 2021; Heckwolf et al, 2020; Richards et al, 2017; Verhoeven et al, 2016). Epigenetic changes can also facilitate evolution when stably transmitted across generations or by increasing genetic mutation rate (Schmid et al, 2018).…”

Section: Introductionmentioning

confidence: 99%

Complementary genomic and epigenomic adaptation to environmental heterogeneity

Gao

Chen

et al. 2022

Molecular Ecology

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While adaptation is commonly thought to result from selection on DNA sequencebased variation, recent studies have highlighted an analogous epigenetic component as well. However, the relative roles of these mechanisms in facilitating population persistence under environmental heterogeneity remain unclear. To address the underlying genetic and epigenetic mechanisms and their relationship during environmental adaptation, we screened the genomes and epigenomes of nine global populations of a predominately sessile marine invasive tunicate, Botryllus schlosseri. We detected clear population differentiation at the genetic and epigenetic levels. Patterns of genetic and epigenetic structure were significantly influenced by local environmental variables. Among these variables, minimum annual sea surface temperature was identified as the top explanatory variable for both genetic and epigenetic variation. However, patterns of population structure driven by genetic and epigenetic variation were somewhat distinct, suggesting possible autonomy of epigenetic variation. We found both shared and specific genes and biological pathways among genetic and epigenetic loci associated with environmental factors, consistent with complementary and independent contributions of genetic and epigenetic variation to environmental adaptation in this system. Collectively, these mechanisms may facilitate population persistence under environmental change and sustain successful invasions across novel environments.

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“…Therefore, adaptation solely based upon changes in allele frequencies of available genetic variation limits the capacity for wild populations to cope with novel or rapidly changing environments (Hu & Barrett, 2017). Epigenetic changes, such as DNA methylation, can regulate many biological processes such as gene expression to promote phenotypic plasticity without changing underlying genotypes (Fu, Huang, Chen, et al, 2021; Huang et al, 2017). This mechanism can provide a rapid pathway for fine‐tuning phenotypes and “buy time” for genetic adaptation to catch up under rapid environmental changes during the initial stages of colonization (Bogan et al, 2021; Heckwolf et al, 2020).…”

Section: Introductionmentioning

confidence: 99%

(Epi)genomic adaptation driven by fine geographical scale environmental heterogeneity after recent biological invasions

Chen

et al. 2022

Ecological Applications

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Elucidating processes and mechanisms involved in rapid local adaptation to varied environments is a poorly understood but crucial component in management of invasive species. Recent studies have proposed that genetic and epigenetic variation could both contribute to ecological adaptation, yet it remains unclear on the interplay between these two components underpinning rapid adaptation in wild animal populations. To assess their respective contributions to local adaptation, we explored epigenomic and genomic responses to environmental heterogeneity in eight recently colonized ascidian (Ciona intestinalis) populations at a relatively fine geographical scale. Based on MethylRADseq data, we detected strong patterns of local environment‐driven DNA methylation divergence among populations, significant epigenetic isolation by environment (IBE), and a large number of local environment‐associated epigenetic loci. Meanwhile, multiple genetic analyses based on single nucleotide polymorphisms (SNPs) showed genomic footprints of divergent selection. In addition, for five genetically similar populations, we detected significant methylation divergence and local environment‐driven methylation patterns, indicating the strong effects of local environments on epigenetic variation. From a functional perspective, a majority of functional genes, Gene Ontology (GO) terms, and biological pathways were largely specific to one of these two types of variation, suggesting partial independence between epigenetic and genetic adaptation. The methylation quantitative trait loci (mQTL) analysis showed that the genetic variation explained only 18.67% of methylation variation, further confirming the autonomous relationship between these two types of variation. Altogether, we highlight the complementary interplay of genetic and epigenetic variation involved in local adaptation, which may jointly promote populations' rapid adaptive capacity and successful invasions in different environments. The findings here provide valuable insights into interactions between invaders and local environments to allow invasive species to rapidly spread, thus contributing to better prediction of invasion success and development of management strategies.

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Interactive Regulations of Dynamic Methylation and Transcriptional Responses to Recurring Environmental Stresses During Biological Invasions

Cited by 5 publications

References 95 publications

Multidimensional plasticity jointly contributes to rapid acclimation to environmental challenges during biological invasions

Multidimensional plasticity jointly contributes to rapid acclimation to environmental challenges during biological invasions

Complementary genomic and epigenomic adaptation to environmental heterogeneity

(Epi)genomic adaptation driven by fine geographical scale environmental heterogeneity after recent biological invasions

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