A field study of the molecular response of brown macroalgae to heavy metal exposure: An (epi)genetic approach

Our understanding of the relative contribution of genetic and epigenetic mechanisms to organismal response to stress is largely biased towards specific taxonomic groups (e.g. seed plants) and environmental stresses (e.g. drought and salinity). In previous work, we found intraspecific differences in...

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Published in:Journal of hazardous materials 2024-12, Vol.480, p.136304, Article 136304
Main Authors: García-Seoane, Rita, Richards, Christina L., Aboal, Jesús R., Fernández, J. Ángel, Schmid, Marc W., Boquete, M. Teresa
Format: Article
Language:English
Subjects:
coasts
cytosine
DNA methylation
DNA Methylation - drug effects
drought
EpiGBS
Epigenesis, Genetic - drug effects
Epigenetics
Fucus - drug effects
Fucus - genetics
Fucus vesiculosus
genetic variation
Genetics
Heavy metals
macroalgae
Metals, Heavy - toxicity
phenotype
Polymorphism, Single Nucleotide
salinity
Seaweed - drug effects
Seaweed - genetics
SNPs
species
stress response
Water Pollutants, Chemical - toxicity
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Summary:Our understanding of the relative contribution of genetic and epigenetic mechanisms to organismal response to stress is largely biased towards specific taxonomic groups (e.g. seed plants) and environmental stresses (e.g. drought and salinity). In previous work, we found intraspecific differences in heavy metal (HM) uptake capacity in the brown macroalgae Fucus vesiculosus. The molecular mechanisms underlying these differences, however, remained unknown. Here, we evaluated the concentrations of HMs, and characterized the genetic (single nucleotide polymorphisms) and epigenetic (cytosine DNA methylation) variability in reciprocal transplants of F. vesiculosus between two polluted and two unpolluted sites on the NW Spanish coast after 90 days. Genetic and epigenetic differentiation did not explain the phenotypic differentiation observed, possibly due to the combined effect of multiple environmental factors acting on the algae in their natural habitats. Nonetheless, we provide further evidence of intraspecific genetic differentiation in F. vesiculosus at short spatial scales, as well as first evidence of population-specific epigenetic changes in brown macroalgae in response to changes in environmental conditions (i.e. transplantation ex situ). We propose that both genetic and, to some extent, epigenetic mechanisms might impinge upon the adaptive potential of this species to environmental change, but this needs to be further addressed. [Display omitted] •Exposure history leads to phenotypic differences in macroalgae metal uptake capacity.•Genetic and epigenetic differentiation do not explain these phenotypic differences.•Environmental complexity of natural habitats might explain this lack of association.•Change of environment induces population-specific epigenetic changes in macroalgae.•Genetic and epigenetic mechanisms may influence the adaptive potential of macroalgae.
ISSN:0304-3894
1873-3336
1873-3336
DOI:10.1016/j.jhazmat.2024.136304