Accounting for transgenerational effects of toxicant exposure in population models alters the predicted long-term population status.

IF 4.8 Q1 GENETICS & HEREDITY
Susanne M Brander, J Wilson White, Bethany M DeCourten, Kaley Major, Sara J Hutton, Richard E Connon, Alvine Mehinto
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引用次数: 1

Abstract

Acute environmental stressors such as short-term exposure to pollutants can have lasting effects on organisms, potentially impacting future generations. Parental exposure to toxicants can result in changes to the epigenome (e.g., DNA methylation) that are passed down to subsequent, unexposed generations. However, it is difficult to gauge the cumulative population-scale impacts of epigenetic effects from laboratory experiments alone. Here, we developed a size- and age-structured delay-coordinate population model to evaluate the long-term consequences of epigenetic modifications on population sustainability. The model emulated changes in growth, mortality, and fecundity in the F0, F1, and F2 generations observed in experiments in which larval Menidia beryllina were exposed to environmentally relevant concentrations of bifenthrin (Bif), ethinylestradiol (EE2), levonorgestrel (LV), or trenbolone (TB) in the parent generation (F0) and reared in clean water up to the F2 generation. Our analysis suggests potentially dramatic population-level effects of repeated, chronic exposures of early-life stage fish that are not captured by models not accounting for those effects. Simulated exposures led to substantial declines in population abundance (LV and Bif) or near-extinction (EE2 and TB) with the exact trajectory and timeline of population decline dependent on the combination of F0, F1, and F2 effects produced by each compound. Even acute one-time exposures of each compound led to declines and recovery over multiple years due to lagged epigenetic effects. These results demonstrate the potential for environmentally relevant concentrations of commonly used compounds to impact the population dynamics and sustainability of an ecologically relevant species and model organism.

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在人口模型中考虑毒物暴露的跨代效应会改变预测的长期人口状况。
急性环境压力因素,如短期暴露于污染物中,可能对生物体产生持久影响,可能影响子孙后代。父母接触有毒物质会导致表观基因组的变化(例如DNA甲基化),这种变化会遗传给随后未接触有毒物质的后代。然而,仅从实验室实验中很难衡量表观遗传效应的累积种群规模影响。在这里,我们开发了一个大小和年龄结构的延迟坐标种群模型来评估表观遗传修饰对种群可持续性的长期影响。该模型模拟了在实验中观察到的F0、F1和F2代的生长、死亡率和繁殖力的变化,在实验中,在亲本代(F0)中,将幼虫暴露于环境相关浓度的联苯菊酯(biif)、炔雌醇(EE2)、左炔诺孕酮(LV)或trenbolone (TB)中,并在清洁水中饲养至F2代。我们的分析表明,在没有考虑这些影响的模型中,反复、长期暴露在早期生命阶段的鱼可能会产生巨大的种群水平影响。模拟暴露导致种群丰度(LV和Bif)大幅下降或接近灭绝(EE2和TB),种群下降的确切轨迹和时间线取决于每种化合物产生的F0、F1和F2效应的组合。即使急性一次性暴露于每种化合物,由于滞后的表观遗传效应,也会导致多年后的下降和恢复。这些结果表明,常用化合物的环境相关浓度可能会影响生态相关物种和模式生物的种群动态和可持续性。
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来源期刊
Environmental Epigenetics
Environmental Epigenetics GENETICS & HEREDITY-
CiteScore
6.50
自引率
5.30%
发文量
0
审稿时长
17 weeks
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