Epigenetic inheritance and intergenerational effects in mollusks

Fallet, Manon; Luquet, Émilien; David, Patrice; Cosseau, Céline

doi:10.1016/j.gene.2019.144166

Cited by 38 publications

(36 citation statements)

References 150 publications

(83 reference statements)

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“…A similar result was observed in mice, where only the gene expression patterns of female offspring were impacted by maternal exposure to predator-cues (St-Cyr and McGowan, 2015). Interestingly, Hales et al (2017) observed a decrease in the number of differentially expressed genes between the F1 and F2 generations-a trend consistent with the observed decrease in transgenerational responses ( §4.2; Walsh et al, 2015) and the lability of inherited epigenetic marks (Fallet et al, 2020). In a companion methodological paper, Schield et al (2016) found shifts in the methylation state of sampled loci between F0 (with predator-cues) and F1 (without predatorcues) in D. ambigua, suggesting that DNA methylation patterns can vary between generations experiencing different predation environments.…”

Section: Inheritance Mechanismssupporting

confidence: 78%

“…Although this is not evidence of transgenerational epigenetic inheritance, it suggests that predation-risk driven behavior of fathers may influence the epigenetic programming of their offspring, which might in turn be transmitted to the next generation. To our knowledge, how and to what extent the epigenome is related to phenotype across generations is still an open question both in predator-prey systems and in general (see Fallet et al, 2020 for a detailed discussion). Taken together, the above results highlight the need for future work examining predator-induced TGP and WGP simultaneously, at both the (epi)genomic and phenotypic levels.…”

Section: Inheritance Mechanismsmentioning

confidence: 99%

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Transgenerational Plasticity in the Context of Predator-Prey Interactions

2020

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Almost all animal species are engaged in predator-prey interactions. These interactions, variable in time and space, favor the emergence and evolution of phenotypic plasticity, which allows prey to fine-tune their phenotype to the current risk of predation. A famous example is the induction of defensive neck-teeth, spines or helmets in some water fleas when they detect cues of predator presence. In general, the response may involve different types of traits (behavioral, morphological, physiological, and life-history traits), alone or in combination. The induced traits may be adaptive anti-predator defenses or reflect more general stress-based responses. Recently, it has been found that predator-induced plasticity occurs not only within but also across generations (transgenerational plasticity), i.e., the phenotype of a generation is influenced by the detection of predator-cues in previous generation(s), even if the current generation is not itself exposed to these cues. In this paper, we aim to review this accumulating literature and propose a current state of key aspects of predator-induced transgenerational plasticity in metazoans. In particular, we review whether patterns of predator-induced transgenerational plasticity depend on the type of traits. We analyze the adaptive value of predator-induced transgenerational plasticity and explore the evidence for its evolution and underlying mechanisms. We also consider its temporal dynamics: what are the time windows during which predator-cues must be detected to be transmitted across generations? Are transgenerational responses in offspring stage-dependent? How many generations does transgenerational plasticity persist? Finally, we discuss other factors highlighted in the literature that influence predator-induced transgenerational plasticity: what are the relative contributions of maternal and paternal exposure to predator-cues in generating transgenerational plasticity? Do transgenerational responses depend on offspring sex? Do they scale with the perceived level of predation risk? This review shows that we are only at the beginning of understanding the processes of predatorinduced transgenerational plasticity, and it encourages future research to fill the lack of knowledge highlighted here.

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Section: Inheritance Mechanismssupporting

confidence: 78%

Section: Inheritance Mechanismsmentioning

confidence: 99%

Transgenerational Plasticity in the Context of Predator-Prey Interactions

2020

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“…These proposals are not mutually exclusive. Transgenerational inheritance has gained interest over the last years [171], notably in marine species [50,172,173], and including sea bass [83]. Parents and/or the germline were unfortunately not sampled in this study for further analysis.…”

Section: Discussionmentioning

confidence: 99%

Genome-wide epigenomic stress response in the European sea bass (Dicentrarchus labrax, L.)

Krick

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et al. 2020

Preprint

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AbstractUnderstanding the molecular basis of stress is of long standing interest in biology and fish science. We tackled this question by modifying the epiGBS (epiGenotyping By sequencing) technique to screen for cytosine methylation and explore the genome-wide epigenomic response to a repeated acute stress challenge in the European sea bass (Dicentrarchus labrax). Following a minimally invasive sampling using nucleated red blood cells (RBCs), our modified epiGBS protocol retrieved 501,108,033 sequencing reads after trimming, with a mean mapping efficiency of 73.0% (unique best hits). Sequencing reads mapped across all linkage groups (LGs). A total of 47,983 CpG coordinates with a minimum 30X read depth was retained for differential methylation analysis between pre- and post-stress fish. A family effect was demonstrated, and 57 distinct differentially methylated cytosines (DMCs) distributed on 17 of 24 LGs were found between RBCs of pre- and post-stress individuals and located close to 51 distinct stress-related genes. Thirty-eight of these genes were previously reported as differentially expressed in the brain of zebrafish, most of them involved in stress coping differences. Some DMC-related genes appear as good candidates to study the stress response, especially a set of them associated to the Brain Derived Neurotrophic Factor (BDNF), a protein that favors stress adaptation and fear memory. Limits to our study and future directions are presented, including the use of RBCs as a surrogate to other target tissues, to provide with classical physiological measurements a more complete picture of the stress response in fish.

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“…An early epigenetic study in molluscs using methylation‐sensitive polymerase chain reaction (PCR) and bisulphite sequencing revealed extensive CpG methylation in Crassostrea gigas (Gavery & Roberts, 2010). To date, epigenetic studies in molluscs have predominantly involved methylation analyses, often studying developmental effects (Fallet et al ., 2020), although other mechanisms include remodelling of chromatin structure through chemical changes to histone proteins and regulation by small RNA molecules. Thus, epigenetic effects may result from a mix of mechanisms in natural environments (Suarez‐Ulloa et al ., 2015).…”

Section: Shell Morphology: Genetic Adaptation and Phenotypic Plasticitymentioning

confidence: 99%

Deciphering mollusc shell production: the roles of genetic mechanisms through to ecology, aquaculture and biomimetics

et al. 2020

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Most molluscs possess shells, constructed from a vast array of microstructures and architectures. The fully formed shell is composed of calcite or aragonite. These CaCO3 crystals form complex biocomposites with proteins, which although typically less than 5% of total shell mass, play significant roles in determining shell microstructure. Despite much research effort, large knowledge gaps remain in how molluscs construct and maintain their shells, and how they produce such a great diversity of forms. Here we synthesize results on how shell shape, microstructure, composition and organic content vary among, and within, species in response to numerous biotic and abiotic factors. At the local level, temperature, food supply and predation cues significantly affect shell morphology, whilst salinity has a much stronger influence across latitudes. Moreover, we emphasize how advances in genomic technologies [e.g. restriction site‐associated DNA sequencing (RAD‐Seq) and epigenetics] allow detailed examinations of whether morphological changes result from phenotypic plasticity or genetic adaptation, or a combination of these. RAD‐Seq has already identified single nucleotide polymorphisms associated with temperature and aquaculture practices, whilst epigenetic processes have been shown significantly to modify shell construction to local conditions in, for example, Antarctica and New Zealand. We also synthesize results on the costs of shell construction and explore how these affect energetic trade‐offs in animal metabolism. The cellular costs are still debated, with CaCO3 precipitation estimates ranging from 1–2 J/mg to 17–55 J/mg depending on experimental and environmental conditions. However, organic components are more expensive (~29 J/mg) and recent data indicate transmembrane calcium ion transporters can involve considerable costs. This review emphasizes the role that molecular analyses have played in demonstrating multiple evolutionary origins of biomineralization genes. Although these are characterized by lineage‐specific proteins and unique combinations of co‐opted genes, a small set of protein domains have been identified as a conserved biomineralization tool box. We further highlight the use of sequence data sets in providing candidate genes for in situ localization and protein function studies. The former has elucidated gene expression modularity in mantle tissue, improving understanding of the diversity of shell morphology synthesis. RNA interference (RNAi) and clustered regularly interspersed short palindromic repeats ‐ CRISPR‐associated protein 9 (CRISPR‐Cas9) experiments have provided proof of concept for use in the functional investigation of mollusc gene sequences, showing for example that Pif (aragonite‐binding) protein plays a significant role in structured nacre crystal growth and that the Lsdia1 gene sets shell chirality in Lymnaea stagnalis. Much research has focused on the impacts of ocean acidification on molluscs. Initial studies were predominantly pessimistic for future molluscan biodiversity...

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Epigenetic inheritance and intergenerational effects in mollusks

Cited by 38 publications

References 150 publications

Transgenerational Plasticity in the Context of Predator-Prey Interactions

Transgenerational Plasticity in the Context of Predator-Prey Interactions

Genome-wide epigenomic stress response in the European sea bass (Dicentrarchus labrax, L.)

Deciphering mollusc shell production: the roles of genetic mechanisms through to ecology, aquaculture and biomimetics

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