Abstract
A four-gene operon (nrcDEFN) was identified within a conjugative element that allows Thermus thermophilus to use nitrate as an electron acceptor. Three of them encode homologues to components of bacterial respiratory chains: NrcD to ferredoxins; NrcF to iron-sulfur-containing subunits of succinate-quinone oxidoreductase (SQR); and NrcN to type-II NADH dehydrogenases (NDHs). The fourth gene, nrcE, encodes a membrane protein with no homologues in the protein data bank. Nitrate reduction with NADH was catalyzed by membrane fractions of the wild type strain, but was severely impaired in nrc::kat insertion mutants. A fusion to a thermophilic reporter gene was used for the first time in Thermus spp. to show that expression of nrc required the presence of nitrate and anoxic conditions. Therefore, a role for the nrc products as a new type of membrane NDH specific for nitrate respiration was deduced. Consistent with this, nrc::kat mutants grew more slowly than the wild type strain under anaerobic conditions, but not in the presence of oxygen. The oligomeric structure of this Nrc-NDH was deduced from the analysis of insertion mutants and a two-hybrid bacterial system. Attachment to the membrane of NrcD, NrcF, and NrcN was dependent on NrcE, whose cytoplasmic C terminus interacts with the three proteins. Interactions were also detected between NrcN and NrcF. Inactivation of nrcF produced solubilization of NrcN, but not of NrcD. These data lead us to conclude that the Nrc proteins form a distinct third type of bacterial respiratory NDH.
Highlights
Many facultative anaerobes adapt their respiratory electrontransport chains to changing environmental conditions by synthesizing specific primary dehydrogenases and final reductases [1]
In this work we describe the presence of a four-gene operon within this mobile DNA element that confers on the receptor cells the ability to grow anaerobically
We demonstrate that the nrc operon encodes a dedicated new type of primary dehydrogenase that is synthesized in parallel with the nitrate reductase (NR), leading to a complete respiratory chain with nitrate as the final electron acceptor
Summary
E. coli DH5␣ E. coli BL21 (DE3) E. coli BTH101 T. thermophilus HB8 T. thermophilus HB27c T. thermophilus HB27 T. thermophilus HB8nrcF T. thermophilus HB8nrcN T. thermophilus HB8nrc/bgaA T. thermophilus HB8nrcE T. thermophilus HB8nrcF CmR T. thermophilus HB8nrcN CamR T. thermophilus HB8nrc/bgaA CmR T. thermophilus HB8nrcE CmR T. thermophilus HB8gdh T. thermophilus HB8gdh CmR pET22b pUC118/119 pUP3B pKT1 pK18. PRBSgal pKUPRBSgal pT18 pT25 pT18zip pT25zip pET22nrcD pT18nrcD pT25nrcD pT18nrcE pT25nrcE pT18c-nrcE pT25c-nrcE pT18nrcF pT25nrcF pT18nrcN pT25nrcN pT18narG pT25narG pT18narJ pT25narJ pT18gdh pT25gdh
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