Escola de Engenharia de Lorena, Universidade de São Paulo (EEL/USP), Lorena, SP, 12602-810, Brazil.
Instituto de Investigaciones Bioquímicas de La Plata (CCT La Plata, Consejo Nacional de Investigaciones Científicas y Técnicas-Universidad Nacional de La Plata), Facultad de Ciencias Médicas, La Plata, 1900, Argentina.
Fungal Biol. 2020 May;124(5):263-272. doi: 10.1016/j.funbio.2019.04.007. Epub 2019 May 10.
Fungi sense light and utilize it as a source of environmental information to prepare against many stressful conditions in nature. In this study, Metarhizium robertsii was grown on: 1) potato dextrose agar medium (PDA) in the dark (control); 2) under nutritive stress in the dark; and 3) PDA under continuous (A) white light; (B) blue light lower irradiance = LI; (C) blue light higher irradiance = HI; (D) green light; and (E) red light. Conidia produced under these treatments were tested against osmotic stress and UV radiation. In addition, a suite of genes usually involved in different stress responses were selected to study their expression patterns. Conidia produced under nutritive stress in the dark were the most tolerant to both osmotic stress and UV radiation, and the majority of their stress- and virulence-related genes were up-regulated. For osmotic stress tolerance, conidia produced under white, blue LI, and blue HI lights were the second most tolerant, followed by conidia produced under green light. Conidia produced under red light were the least tolerant to osmotic stress and less tolerant than conidia produced on PDA medium in the dark. For UV tolerance, conidia produced under blue light LI were the second most tolerant to UV radiation, followed by the UV tolerances of conidia produced under white light. Conidia produced under blue HI, green, and red lights were the least UV tolerant and less tolerant than conidia produced in the dark. The superoxide dismutases (sod1 and sod2), photolyases (6-4phr and CPDphr), trehalose-phosphate synthase (tps), and protease (pr1) genes were highly up-regulated under white light condition, suggesting a potential role of these proteins in stress protection as well as virulence after fungal exposure to visible spectrum components.
真菌能够感知光线,并将其作为环境信息的来源,以应对自然界中许多压力条件。在这项研究中,玫烟色棒束孢(Metarhizium robertsii)在以下条件下进行了培养:1)在黑暗中的土豆葡萄糖琼脂培养基(PDA)上(对照);2)在黑暗中的营养胁迫下;3)在连续的(A)白光下的 PDA 上;(B)蓝光低辐照度(LI);(C)蓝光高辐照度(HI);(D)绿光;和(E)红光。在这些处理下产生的分生孢子用于测试其对渗透胁迫和 UV 辐射的抗性。此外,选择了一套通常涉及不同应激反应的基因,以研究它们的表达模式。在黑暗中营养胁迫下产生的分生孢子对渗透胁迫和 UV 辐射最具耐受性,并且它们的大多数应激和毒力相关基因都上调。对于渗透胁迫耐受性,在白光、蓝光 LI 和蓝光 HI 下产生的分生孢子是第二耐受的,其次是在绿光下产生的分生孢子。在红光下产生的分生孢子对渗透胁迫的耐受性最低,比在黑暗中 PDA 培养基上产生的分生孢子的耐受性差。对于 UV 耐受性,在蓝光 LI 下产生的分生孢子对 UV 辐射的耐受性第二高,其次是在白光下产生的分生孢子的 UV 耐受性。在蓝光 HI、绿光和红光下产生的分生孢子对 UV 的耐受性最低,比在黑暗中产生的分生孢子的耐受性差。超氧化物歧化酶(sod1 和 sod2)、光解酶(6-4phr 和 CPDphr)、海藻糖-6-磷酸合酶(tps)和蛋白酶(pr1)基因在白光条件下高度上调,表明这些蛋白质在真菌暴露于可见光谱成分后的应激保护和毒力方面可能具有潜在作用。
