Cristian Peña-Ponton scite author profile

Environmental changes can trigger phenotypic variation in plants through epigenetic mechanisms, but strong genetic influences make it difficult to isolate and study epigenetic effects. Clonal trees with low genetic variation, such as the Lombardy poplar (Populus nigracv. Italica Duroi), offer a unique system to study epigenetic variation associated with the environment. We collected cuttings (ramets) of Lombardy poplar along a wide geographical range in Europe. We performed whole-genome-bisulfite sequencing of 164 ramets grown in a common garden and of a subset of 35 of the original parental individuals. Using historical bioclimatic data, we tested the relationship between DNA methylation and climatic gradients. We found that average methylation levels in TEs and promoter regions correlate with biologically relevant climatic variables. Furthermore, we observed that DNA methylation was transmitted to the next clonal generation, but a fraction of the methylome changed relatively fast when comparing the parental individuals with the clonal offspring. Our results suggest that the poplar methylome is a dynamic layer of information that can be transmitted to the clonal offspring and potentially affect how poplars acclimate to new environmental conditions.

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An uncommon garden experiment: microenvironment has stronger influence on phenotypic variation than epigenetic memory in the clonal Lombardy poplar

Rodríguez

Peña-Ponton

Pérez-Bello

et al. 2022

Preprint

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Environmental changes can trigger phenotypic variation in plants through epigenetic mechanisms, but strong genetic influences on epigenetic variation and phenotypes make it difficult to isolate and study these effects. We investigated phenotypic plasticity using the Lombardy poplar (Populus nigra cv. Italica Duroi), a globaly distributed clonal tree. We surveyed 14 functional traits related to tree growth, ecophysiological and phenological processes in poplar ramets collected along a wide geographical range in Europe and planted under common garden conditions. We investigated whether phenotypic variation was related to geography and historical bioclimatic data of the sites of origin of the ramets using linear mixed effect models. We found significant differences in among ramets from different geographic origins in tree height, number of stems per ramet and duration of bud flush. However, microenvironmental variation in the common garden, captured via block effects, had an even bigger impact on phenotypic variation than the environmental conditions at the sites of origin. Our results show that phenotypic variation in the ramets might be associated to the climate origin from different climates, suggesting possible epigenetic memory. However, such legacy effects might be quickly outweighed by new environmental conditions.

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High-resolution methylome analysis in the clonalPopulus nigracv. ‘Italica’ reveals environmentally sensitive hotspots and drought-responsive TE superfamilies

Peña-Ponton

Rodríguez

Pérez-Bello

et al. 2022

Preprint

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ABSTRACT/SUMMARYDNA methylation is environment-sensitive and can mediate plant stress responses. In long-lived trees, changing environments might cumulatively shape the methylome landscape over their lifetime. However, because high-resolution methylome studies usually focus on single environments, it remains unclear to what extent the methylation responses are generic or stress-specific, and how this relates to their long-term stability.Here, we studied the methylome plasticity of a single poplar genotype,Populus nigracv. ‘Italica’. Adult poplar trees with diverse environmental histories were clonally propagated, and the ramets exposed to experimental cold, heat, drought, herbivory, rust infection and salicylic acid treatments. Then, we identified and compared stress-induced vs. naturally occurring DNA methylation changes using whole genome bisulfite sequencing data.Methylation changes mainly targeted transposable elements and when occurring in CG/CHG contexts, the same regions were often affected by multiple stresses, indicating a generic response. Drought triggered a unique CHH hypermethylation response in transposable elements, affecting entire superfamilies and often occurring near drought-responsive genes. Stress-induced methylation variation in CG/CHG contexts showed striking overlap with methylation differences observed between trees from distinct geographical locations.Altogether, our results indicate that generic methylome stress responses can persist as epialleles in nature while some environments trigger more transient but large and specific responses, with possible functional consequences.

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