, 1995, 1997; Lazazzera et al, 1996; Kiley & Beinert, 1998) Und

, 1995, 1997; Lazazzera et al., 1996; Kiley & Beinert, 1998). Under anaerobic conditions, [4Fe–4S]-FNR forms a functional dimer that binds DNA at a 5′-TTGAT(N4)ATCAA-3′ FNR-box

sequence (Eiglmeier et al., 1989), and it activates or represses transcription depending on the location of binding relative to the promoter (Wing et al., 1995; Meng et al., 1997; Marshall et al., 2001). FNR was reported to activate bioluminescence in transgenic E. coli carrying the V. fischeri MJ1 luxR-luxICDABEG PI3K inhibitor region, which encodes the autoinducer-dependent lux activator LuxR, the autoinducer synthase LuxI, and the Lux proteins that produce bioluminescence (Muller-Breikreutz & Winkler, 1993). Although FNR-mediated regulation of luminescence is cited frequently (Meighen, 1994; Spiro, 1994; Sitnikov et al., 1995; Ulitzur & Dunlap, 1995; Stevens & Greenberg, 1999), these data were only presented in preliminary form in a symposium report (Muller-Breikreutz Inhibitor Library & Winkler, 1993). We have examined fnr in two V. fischeri strains: ES114 and

MJ1. ES114′s genome is sequenced, and its symbiosis with the squid Euprymna scolopes can be reconstituted in the laboratory (Ruby et al., 2005; Stabb, 2006); however, like most isolates from these animals, ES114 is not visibly luminescent in culture (Boettcher & Ruby, 1990). In contrast, MJ1 has bright luminescence typical of isolates from the pinecone fish Monocentris japonica, but this symbiosis is not yet experimentally tractable. The genes required for luminescence and autoinduction are similar in the two strains, with the luxICDABEG operon adjacent to and divergently transcribed from luxR (Gray & Greenberg, 1992). However, there are differences in the luxR-luxI intergenic region, and notably there is a putative FNR box upstream of luxR in MJ1 that is absent in ES114. Our goals were to examine V. fischeri to assess FNR’s regulation of luminescence and anaerobic respiration, and to determine whether FNR contributes to symbiotic competence. The bacterial strains used in this study are described in Table 1. Escherichia coli

was grown in Luria–Bertani (Miller, 1992) or in M9 (Sambrook et al., 1989) supplemented with 1 mg mL−1 casamino acids, 40 mM glycerol, and 40 mM of either sodium nitrate or sodium Carteolol HCl fumarate. Vibrio fischeri was grown in Luria broth plus salt (LBS) (Stabb et al., 2001), sea water tryptone (SWT) (Boettcher & Ruby, 1990), wherein seawater was replaced with Instant Ocean (Aquarium Systems, Mentor, OH), sea water tryptone at high osmolarity (SWTO) (Bose et al., 2007), or in a defined salts medium (Adin et al., 2009) with 40 mM glycerol as a carbon source, 1 mg mL−1 casamino acids, and 40 mM of sodium nitrate or sodium fumarate. Agar (15 mg mL−1) was added to solidify media for plating. Anaerobic growth on plates was assessed using the GasPak EZ Anaerobic Container System from Becton, Dickinson and Company (Sparks, MD).

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