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1. Genetic variation underlies plastic responses to global change drivers in the purple sea urchin, Strongylocentrotus purpuratus

   https://doi.org/10.1098/rspb.2022.1249  

   Strader, Marie E.; Wolak, Matthew E.; Simon, Olivia M.; Hofmann, Gretchen E. (August 2022, Proceedings of the Royal Society B: Biological Sciences)

   Phenotypic plasticity and adaptive evolution enable population persistence in response to global change. However, there are few experiments that test how these processes interact within and across generations, especially in marine species with broad distributions experiencing spatially and temporally variable temperature and p CO 2 . We employed a quantitative genetics experiment with the purple sea urchin, Strongylocentrotus purpuratus , to decompose family-level variation in transgenerational and developmental plastic responses to ecologically relevant temperature and p CO 2 . Adults were conditioned to controlled non-upwelling (high temperature, low p CO 2 ) or upwelling (low temperature, high p CO 2 ) conditions. Embryos were reared in either the same conditions as their parents or the crossed environment, and morphological aspects of larval body size were quantified. We find evidence of family-level phenotypic plasticity in response to different developmental environments. Among developmental environments, there was substantial additive genetic variance for one body size metric when larvae developed under upwelling conditions, although this differed based on parental environment. Furthermore, cross-environment correlations indicate significant variance for genotype-by-environment interactive effects. Therefore, genetic variation for plasticity is evident in early stages of S. purpuratus , emphasizing the importance of adaptive evolution and phenotypic plasticity in organismal responses to global change. 

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2. Associations between DNA methylation and gene regulation depend on chromatin accessibility during transgenerational plasticity

   https://doi.org/10.1186/s12915-023-01645-8  

   Bogan, Samuel N.; Strader, Marie E.; Hofmann, Gretchen E. (June 2023, BMC Biology)

   Abstract BackgroundEpigenetic processes are proposed to be a mechanism regulating gene expression during phenotypic plasticity. However, environmentally induced changes in DNA methylation exhibit little-to-no association with differential gene expression in metazoans at a transcriptome-wide level. It remains unexplored whether associations between environmentally induced differential methylation and expression are contingent upon other epigenomic processes such as chromatin accessibility. We quantified methylation and gene expression in larvae of the purple sea urchinStrongylocentrotus purpuratusexposed to different ecologically relevant conditions during gametogenesis (maternal conditioning) and modeled changes in gene expression and splicing resulting from maternal conditioning as functions of differential methylation, incorporating covariates for genomic features and chromatin accessibility. We detected significant interactions between differential methylation, chromatin accessibility, and genic feature type associated with differential expression and splicing. ResultsDifferential gene body methylation had significantly stronger effects on expression among genes with poorly accessible transcriptional start sites while baseline transcript abundance influenced the direction of this effect. Transcriptional responses to maternal conditioning were 4–13 × more likely when accounting for interactions between methylation and chromatin accessibility, demonstrating that the relationship between differential methylation and gene regulation is partially explained by chromatin state. ConclusionsDNA methylation likely possesses multiple associations with gene regulation during transgenerational plasticity inS. purpuratusand potentially other metazoans,but its effects are dependent on chromatin accessibility and underlying genic features. 

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3. Individual variation in plasticity dulls transgenerational responses to stress

   https://doi.org/10.1111/1365-2435.13409  

   Gillis, Michael K.; Walsh, Matthew R.; Pfrender, ed., Michael (August 2019, Functional Ecology)

   Abstract Much research has shown that environmental stress can induce adaptive and maladaptive phenotypic changes in organisms that persist for multiple generations. Such transgenerational phenotypic plasticity shrouds our understanding of the long‐term consequences of ongoing anthropogenic pressures.Here, we evaluated within‐ and transgenerational phenotypic responses to food stress in the freshwater crustacean,Daphnia. We reared 45 clones ofDaphnia pulicariaeach on high‐qualityScenedesmusand low‐quality (but also non‐toxic) cyanobacteria (generation 1). Offspring produced by generation 1 adults were then reared onScenedesmus(generation 2), and life‐history traits were measured across both generations.The results show thatDaphniain generation 1 exhibited reduced fitness (i.e., delayed maturation, lower reproductive output, increased clutch interval) when reared in the presence of cyanobacteria as opposed to high‐quality food. However, maternal stress had no clear influence on the fitness of offspring. That is,Daphniain the second experimental generation had similar mean trait values, irrespective of whether their mothers were reared on cyanobacteria or high‐quality food.Signals of transgenerational life‐history effects were obscured, in part, by extensive clonal variation amongDaphniain the direction of transgenerational responses to cyanobacteria (i.e., adaptive and maladaptive plasticity). Further analyses demonstrated that such individual variance in plasticity might be open to selection and potentially offer a means of contemporary adaptation to cyanobacteria. Taken together, our results denote a link between the overall strength of transgenerational responses to the environment and the potential for rapid evolution in populations. A freePlain Language Summarycan be found within the Supporting Information of this article. 

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4. Simultaneous warming and acidification limit population fitness and reveal phenotype costs for a marine copepod

   https://doi.org/10.1098/rspb.2023.1033  

   deMayo, James A; Brennan, Reid S; Pespeni, Melissa H; Finiguerra, Michael; Norton, Lydia; Park, Gihong; Baumann, Hannes; Dam, Hans G (September 2023, Proceedings of the Royal Society B: Biological Sciences)

   Phenotypic plasticity and evolutionary adaptation allow populations to cope with global change, but limits and costs to adaptation under multiple stressors are insufficiently understood. We reared a foundational copepod species,Acartia hudsonica, under ambient (AM), ocean warming (OW), ocean acidification (OA), and combined ocean warming and acidification (OWA) conditions for 11 generations (approx. 1 year) and measured population fitness (net reproductive rate) derived from six life-history traits (egg production, hatching success, survival, development time, body size and sex ratio). Copepods under OW and OWA exhibited an initial approximately 40% fitness decline relative to AM, but fully recovered within four generations, consistent with an adaptive response and demonstrating synergy between stressors. At generation 11, however, fitness was approximately 24% lower for OWA compared with the AM lineage, consistent with the cost of producing OWA-adapted phenotypes. Fitness of the OWA lineage was not affected by reversal to AM or low food environments, indicating sustained phenotypic plasticity. These results mimic those of a congener,Acartia tonsa, while additionally suggesting that synergistic effects of simultaneous stressors exert costs that limit fitness recovery but can sustain plasticity. Thus, even when closely related species experience similar stressors, species-specific costs shape their unique adaptive responses. 

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5. Transgenerational plasticity and the capacity to adapt to low salinity in the eastern oyster, Crassostrea virginica

   https://doi.org/10.1098/rspb.2020.3118  

   Griffiths, Joanna S.; Johnson, Kevin M.; Sirovy, Kyle A.; Yeats, Mark S.; Pan, Francis T.; La Peyre, Jerome F.; Kelly, Morgan W. (May 2021, Proceedings of the Royal Society B: Biological Sciences)

   Salinity conditions in oyster breeding grounds in the Gulf of Mexico are expected to drastically change due to increased precipitation from climate change and anthropogenic changes to local hydrology. We determined the capacity of the eastern oyster, Crassostrea virginica , to adapt via standing genetic variation or acclimate through transgenerational plasticity (TGP). We outplanted oysters to either a low- or medium-salinity site in Louisiana for 2 years. We then crossed adult parents using a North Carolina II breeding design, and measured body size and survival of larvae 5 dpf raised under low or ambient salinity. We found that TGP is unlikely to significantly contribute to low-salinity tolerance since we did not observe increased growth or survival in offspring reared in low salinity when their parents were also acclimated at a low-salinity site. However, we detected genetic variation for body size, with an estimated heritability of 0.68 ± 0.25 (95% CI). This suggests there is ample genetic variation for this trait to evolve, and that evolutionary adaptation is a possible mechanism through which oysters will persist with future declines in salinity. The results of this experiment provide valuable insights into successfully breeding low-salinity tolerance in this commercially important species. 

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