Black fungi withstand extreme stresses partly due to the presence of melanin. Melanin is associated with structural integrity and resistance to chemical and radiation stress. This results in improved health and fitness, specifically in extreme conditions. Our goal was to exploit the radiation sensing nature of melanized fungus in order to develop a radioadapted strain capable of responding to radiation in the environment. The protracted exposure of a melanized fungus, Wangiella dermatitidis, to a mixed source of radiation altered the electron transport properties. There was no effect in an albino mutant wdpsk1. We then tested the growth response to radiation in the environment, with shielding from direct exposure to the radiation. Gamma radiation caused increased colony growth irrespective of exposure history in melanized fungus. Beta particles produced growth inhibition. The previously exposed melanized strain demonstrated colony growth in response to alpha particles in the environment. Alpha particles have a higher linear energy transfer, which produces more reactive oxygen species. Our previously exposed melanized strain was resistant to the toxic effects of H2O2, while the naïve and non-melanized strains were sensitive. We propose that previous radiation exposure introduces adaptations that equip melanized fungi to tolerate, sense, and respond to radiation byproducts.
Keywords: Alpha particles; Fungus; ROS; Radioadaptation; Radiostimulation.
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