Abstract
Iron acquisition by bacteria is well studied, but iron export from bacteria is less understood. Herein, we identified dr1440 with a P-type ATPase motif as a potential exporter of iron from Deinococcus radiodurans, a bacterium known for its extreme resistance to radiation and oxidants. The DR1440 was located in cell membrane as demonstrated by fluorescence labelling analysis. Mutation of dr1440 resulted in cellular accumulation of iron ions, and expression level of dr1440 was up-regulated significantly under iron ion or hydrogen peroxide stress in the wild-type strain, implicating DR1440 as a potential iron efflux protein. The dr1440 mutant displayed higher sensitivity to iron ions and oxidative stresses including hydrogen peroxide, hypochlorous acid, and gamma-ray irradiation compared with the wild-type strain. The high amount of iron in the mutant strain resulted in severe protein carbonylation, suggesting that DR1440 might contribute to intracellular protein protection against reactive oxygen species (ROS) generated from ferrous ion-mediated Fenton-reaction. Mutations of S297A and C299A led to intracellular accumulation of iron, indicating that S297 and C299 might be important functional residues of DR1440. Thus, DR1440 is a potential iron efflux protein involved in iron homeostasis and oxidative stress-resistance of D. radiodurans.
Highlights
Iron (Fe) ions are essential nutrients required for microorganisms and act as important enzyme cofactors for a number of cellular processes such as DNA synthesis and repair, antioxidant systems and electron transport [1]
DR1440 was identified as a potential iron efflux protein in the extremophilic bacterium D. radiodurans, known for its resistance to oxidative stress
Iron is an essential metal for many cellular functions including N2 fixation, photosynthesis, respiration, trichloroacetic acid (TCA) cycle, oxygen transport, and DNA biosynthesis [25, 26]
Summary
Iron (Fe) ions are essential nutrients required for microorganisms and act as important enzyme cofactors for a number of cellular processes such as DNA synthesis and repair, antioxidant systems and electron transport [1]. These ions are harmful to cells when in excess due to Fenton-reaction which generates harmful hydroxyl radicals (HOÁ) that target DNA, RNA, proteins and lipids [2]. A potential iron efflux protein in Deinococcus radiodurans iron homeostasis and intracellular redox-cycling processes in bacteria. Iron exporters and iron homeostasis in prokaryotes are far from being understood, especially in extremophiles
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