电离辐射:真菌如何借助黑色素应对、适应和利用电离辐射。
Ionizing radiation: how fungi cope, adapt, and exploit with the help of melanin.
作者信息
Dadachova Ekaterina, Casadevall Arturo
机构信息
Department of Nuclear Medicine, Albert Einstein College of Medicine, 1695A Eastchester Road, Bronx, NY 10461, USA.
出版信息
Curr Opin Microbiol. 2008 Dec;11(6):525-31. doi: 10.1016/j.mib.2008.09.013. Epub 2008 Oct 24.
Abstract
Life on Earth has always existed in the flux of ionizing radiation. However, fungi seem to interact with the ionizing radiation differently from other inhabitants of the Earth. Recent data show that melanized fungal species like those from Chernobyl's reactor respond to ionizing radiation with enhanced growth. Fungi colonize space stations and adapt morphologically to extreme conditions. Radiation exposure causes upregulation of many key genes, and an inducible microhomology-mediated recombination pathway could be a potential mechanism of adaptive evolution in eukaryotes. The discovery of melanized organisms in high radiation environments, the space stations, Antarctic mountains, and in the reactor cooling water combined with phenomenon of 'radiotropism' raises the tantalizing possibility that melanins have functions analogous to other energy harvesting pigments such as chlorophylls.
摘要
地球上的生命一直存在于电离辐射的通量之中。然而,真菌与电离辐射的相互作用方式似乎与地球上的其他生物不同。最近的数据表明,像来自切尔诺贝利反应堆的那些黑化真菌物种对电离辐射的反应是生长增强。真菌在空间站定殖并在形态上适应极端条件。辐射暴露会导致许多关键基因上调,而一种可诱导的微同源性介导的重组途径可能是真核生物适应性进化的潜在机制。在高辐射环境(空间站、南极山脉以及反应堆冷却水中)发现黑化生物,再加上“向辐射性”现象,引发了一种诱人的可能性,即黑色素具有与其他能量收集色素(如叶绿素)类似的功能。
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