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Supplemental results
EBI InterPro Scan (version 4.8) protein domain analysis of RnfC reveals that S.
fumaroxidans strain MPOB RnfC encodes RnfC beta-barrel sandwich hybrid domain
(IPR026902), NADH:ubiquinone oxidoreductase, 51kDa subunit (IPR010208), alphahelical ferredoxin (IPR009051), C-terminal fumarate reductase (IPR012285), and 4Fe-4S
ferredoxin-type, Fe-S binding domains (IPR017896/017900).
In comparison, the strain UI SynarDRAFT_0709 encodes FAD-binding oxidoreductase
(IPR008333), FAD/NAD(P)-binding oxidoreductase (IPR001433), ferredoxin reductasetype FAD-binding domain (IPR017927), riboflavin synthase-like beta-barrel
(IPR017936), and dihydroorotate dehydrogenase, electron transfer subunit, Fe-S cluster
binding-domain (IPR019480), ferredoxin reductase-like C-terminal domain (SSF52343),
and a transmembrane region. In addition, SynarDRAFT_0710 encodes an alpha-helical
ferredoxin (IPR009051), C-terminal fumarate reductase (IPR012285), and 4Fe-4S
ferredoxin-type, Fe-S binding domains (IPR017896/017900).
The RnfC and SynarDRAFT_0710-0709 clearly share features. In particular, both
possess alphahelical ferredoxin, C-terminal fumarate reductase, 4Fe-4S ferredoxin-type
Fe-S binding domain, and transmembrane beta-barrel domains. Strikingly, both betabarrel domains encode seven beta-strands. Transmembrane beta-barrel are known to act
as selective ion channels (Smythies, 1981; Schulz, 2000; Baumeister et al., 2001;
Delcour, 2002; Menestrina et al., 2003; Som et al., 2003; Moroni and Thiel, 2006; Jang et
al., 2010; Mohammad et al., 2011; Garcia-Gimenez et al., 2012). Given that none of the
other Rnf subunits encode discernable transmembrane ion channels, we speculate that the
RnfC beta-barrel may serve as an ion channel driving reverse electron transport.
Furthermore, the RnfC and SynarDRAFT_0709 beta-barrels may select for ions with
similar size and charge because they are both seven-stranded.
References
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