Browsing by Author "Dorry H.E."
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Item Molecular adaptations of bacterial mercuric reductase to the hypersaline Kebrit Deep in the Red Sea(American Society for Microbiology, 2019) Ramadan E.; Maged M.; Hosseiny A.E.; Chambergo F.S.; Setubal J.C.; Dorry H.E.; Department of Biology; School of Sciences and Engineering; The American University in Cairo; New Cairo; Egypt; Escola de Artes Ci�ncias e Humanidades; Universidade de S�o Paulo; S�o Paulo; Brazil; Instituto de Qu�mica; Universidade de S�o Paulo; S�o Paulo; Brazil; Faculty of Pharmacy; Department of Pharmacology and Biochemistry; The British University in Egypt; El-Sherouk City; Egypt; Faculty of Biotechnology; October University for Modern Sciences and Arts; Cairo; EgyptThe hypersaline Kebrit Deep brine pool in the Red Sea is characterized by high levels of toxic heavy metals. Here, we describe two structurally related mercuric reductases (MerAs) from this site which were expressed in Escherichia coli. Sequence similarities suggest that both genes are derived from proteobacteria, most likely the Betaproteobacteria or Gammaproteobacteria. We show that one of the enzymes (K35NH) is strongly inhibited by NaCl, while the other (K09H) is activated in a NaCl-dependent manner. We infer from this difference that the two forms might support the detoxification of mercury in bacterial microorganisms that employ the compatible solutes and salt-in strategies, respectively. Three-dimensional structure modeling shows that all amino acid substitutions unique to each type are located outside the domain responsible for formation of the active MerA homodimer, and the vast majority of these are found on the surface of the molecule. Moreover, K09H exhibits the predominance of acidic over hydrophobic side chains that is typical of halophilic salt-dependent proteins. These findings enhance our understanding of how selection pressures imposed by two environmental stressors have endowed MerA enzymes with catalytic properties that can potentially function in microorganisms that utilize distinct mechanisms for osmotic balance in hypersaline environments. � 2019 American Society for Microbiology. All Rights Reserved.