Melanism protects alpine zooplankton from DNA damage caused by ultraviolet radiation

C. K. Ulbing, Julia M. Muuse, Brooks E. Miner
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引用次数: 7

Abstract

Melanism is widely observed among animals, and is adaptive in various contexts for its thermoregulatory, camouflaging, mate-attraction or photoprotective properties. Many organisms exposed to ultraviolet radiation show increased fitness resulting from melanin pigmentation; this has been assumed to result in part from reduced UV-induced damage to DNA. However, to effectively test the hypothesis that melanin pigmentation reduces UV-induced DNA damage requires quantification of UV-specific DNA damage lesions following UV exposure under controlled conditions using individuals that vary in pigmentation intensity. We accomplished this using alpine genotypes of the freshwater microcrustacean Daphnia melanica, for which we quantified cyclobutane pyrimide dimers in DNA, a damage structure that can only be generated by UV exposure. For genotypes with carapace melanin pigmentation, we found that individuals with greater melanin content sustained lower levels of UV-induced DNA damage. Individuals with more melanin were also more likely to survive exposure to ecologically relevant levels of UV-B radiation. Parallel experiments with conspecific genotypes that lack carapace melanin pigmentation provide additional support for our conclusion that melanism protects individuals from UV-induced DNA damage. Finally, within-genotype comparisons with asexually produced clonal siblings demonstrate that melanin content influences DNA damage even among genetically identical individuals raised in the same environment.
黑色素瘤保护高山浮游动物免受紫外线辐射造成的DNA损伤
黑化现象在动物中广泛存在,并因其温度调节、伪装、吸引配偶或光保护特性而适应于各种环境。许多暴露于紫外线辐射下的生物体显示出由于黑色素沉着而增加的适应性;这被认为部分是由于紫外线对DNA的损伤减少。然而,为了有效地验证黑色素色素沉着减少紫外线诱导的DNA损伤的假设,需要在控制条件下使用不同色素沉着强度的个体对紫外线照射后的紫外线特异性DNA损伤病变进行量化。我们使用淡水微甲壳类动物黑水蚤的高山基因型完成了这一任务,我们量化了DNA中的环丁烷嘧啶二聚体,这是一种只能由紫外线照射产生的损伤结构。对于具有甲壳黑色素色素沉着的基因型,我们发现黑色素含量较高的个体维持较低水平的紫外线诱导的DNA损伤。拥有更多黑色素的个体也更有可能在与生态相关的UV-B辐射水平下存活下来。对缺乏甲壳黑色素色素沉着的同种基因型进行的平行实验为我们的结论提供了额外的支持,即黑色素病可以保护个体免受紫外线诱导的DNA损伤。最后,与无性繁殖的克隆兄弟姐妹的基因型内比较表明,即使在相同环境中长大的基因相同的个体中,黑色素含量也会影响DNA损伤。
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