None of the remaining 29 MtrB homologs contained an N-terminal CX

None of the remaining 29 MtrB homologs contained an N-terminal CXXC motif. α- and β-Proteobacteria were represented in 18 of the 29 MtrB homologs lacking an N-terminal CXXC motif, including the MtrB homologs of the Fe(II)-oxidizing β-proteobacteria Dechloromonas aromatica, Gallionella capsiferriformans, and Sideroxydans lithotrophicus (Emerson & Moyer, 1997; Chakraborty et al., 2005; Hedrich et al., 2011). CXXC motifs were also missing from the N-terminus of PioB, the MtrB homolog of the Fe(II)-oxidizing

α-proteobacterium Rhodopseudomonas palustris (Jiao & Newman, 2007), and from the MtrB homolog of the γ-proteobacterium Halorhodospira halophila, a sulfur-oxidizing anoxygenic phototroph (Challacombe OSI-744 datasheet et al., 2013). Three of the 29 MtrB homologs lacking an N-terminal CXXC motif were found in metal-reducing bacteria, including the β-proteobacterium Rhodoferax ferrireducens (Finneran et al., 2003) and the δ-proteobacteria Geobacter sp. M21, G. metallireducens and G. uraniireducens (Shelobolina et al., 2008). These results indicate that MtrB homologs of metal-reducing γ-proteobacteria contain an N-terminal CXXC motif that is missing from MtrB homologs of nonmetal-reducing γ-proteobacteria and from all bacteria outside the γ-proteobacteria, including those catalyzing Osimertinib cell line dissimilatory metal reduction or oxidation reactions. To determine whether the N-terminal

CXXC motif of MtrB was required for dissimilatory metal reduction, the N-terminal CXXC motif of S. oneidensis MtrB was selected for site-directed mutational analysis, and the resulting CXXC mutants were tested for dissimilatory metal reduction activity. S. oneidensis mutant strain C42A was unable to reduce Fe(III) or Mn(IV) as terminal electron acceptor (i.e. displayed metal reduction-deficient phenotypes identical to ∆mtrB; Fig. 2), yet retained wild-type respiratory activity on all nonmetal electron acceptors, including O2, , , , fumarate,

DMSO, and TMAO (Fig. S3). S. oneidensis mutant strain C45A, on the other hand, displayed wild-type reduction activity of all electron acceptors, including Fe(III) and Mn(IV) (Figs 2 and S3). The involvement of C42 in metal reduction activity was confirmed via restoration of wild-type metal Arachidonate 15-lipoxygenase reduction activity to C42A transconjugates provided with wild-type mtrB on pBBR1MCS (Fig. 2). These findings indicate that the first, but not the second, cysteine in the N-terminal CXXC motif of MtrB is required for dissimilatory metal reduction by S. oneidensis. These findings also indicate that overlapping MtrB function is not provided by the MtrB paralogs MtrE, DmsF, and SO4359 or that these paralogs are expressed under metal-reducing conditions different than those employed in the present study (Myers & Myers, 2002; Gralnick et al., 2006). The involvement of C42 in metal reduction by S.

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