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by claude@2026-07, 2026-07-03
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The study investigated ecological differentiation and transgenerational effects in the clonal invasive knotweed Reynoutria japonica across a European latitudinal gradient using a two-phase transplant experiment. Plants from different latitudes were transplanted to sites at the northern range margin, mid-range, and southern range margin, then re-transplanted among sites after two years, with performance assessed via biomass production and allocation. Biomass production and allocation were not linked to latitude of origin, and growth at the same site previously did not enhance performance, leading the authors to report no evidence for adaptive differentiation or transgenerational effects at the population level. At the northern site with a shorter 25% season, plants invested less biomass below-ground—an effect that was stronger when previous-generation growth also occurred in the northern site—and distribution modeling identified mean annual temperature and temperature annual range as main predictors; this paper does not explicitly discuss endometriosis or adenomyosis, and it was included in the corpus via a keyword match in the upstream search index.
Abstract
ABSTRACT The ecological and evolutionary processes determining species range limits remain poorly understood. Ultimately, range limits depend on the species’ abilities to persist under heterogeneous conditions, by adaptive differentiation and phenotypic plasticity, including transgenerational effects. To investigate ecological differentiation and transgenerational effects in the clonal invasive knotweed, Reynoutria japonica , in Europe, we conducted a two-phase transplant experiment: plants sampled along the entire latitudinal gradient were planted in three sites located at the northern range margin, mid-range and near the southern range margin, and then re-transplanted among all three sites after two years. Biomass production and allocation were generally not associated with latitude of origin and previous growth at the same site did not promote performance. We therefore find no evidence that adaptive differentiation or transgenerational effects contribute to the wide distribution of R. japonica in Europe. However, at the northern site, with a 25% shorter season, knotweed plants invested much less biomass below-ground, and the pattern was further strengthened in plants that had grown in the northern site in the previous generation. Overwintering below-ground rhizomes are essential for survival and spread. We further explored limiting climate conditions in a species distribution model for the European range and found that mean annual temperature and temperature annual range are the main predictors of the European distribution of R. japonica . Taken together, our study suggests that low temperatures and associated short seasons may pose a limit to the broad environmental tolerance of R. japonica and restrict its northward spread by reducing below-ground biomass accumulation.
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ABSTRACT
The ecological and evolutionary processes determining species range limits remain poorly understood. Ultimately, range limits depend on the species’ abilities to persist under heterogeneous conditions, by adaptive differentiation and phenotypic plasticity, including transgenerational effects. To investigate ecological differentiation and transgenerational effects in the clonal invasive knotweed, Reynoutria japonica, in Europe, we conducted a two-phase transplant experiment: plants sampled along the entire latitudinal gradient were planted in three sites located at the northern range margin, mid-range and near the southern range margin, and then re-transplanted among all three sites after two years. Biomass production and allocation were generally not associated with latitude of origin and previous growth at the same site did not promote performance. We therefore find no evidence that adaptive differentiation or transgenerational effects contribute to the wide distribution of R. japonica in Europe. However, at the northern site, with a 25% shorter season, knotweed plants invested much less biomass below-ground, and the pattern was further strengthened in plants that had grown in the northern site in the previous generation. Overwintering below-ground rhizomes are essential for survival and spread. We further explored limiting climate conditions in a species distribution model for the European range and found that mean annual temperature and temperature annual range are the main predictors of the European distribution of R. japonica. Taken together, our study suggests that low temperatures and associated short seasons may pose a limit to the broad environmental tolerance of R. japonica and restrict its northward spread by reducing below-ground biomass accumulation.
Competing Interest Statement
The authors have declared no competing interest.
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