Exciting laser intensity, background level contrast, and electronic zoom were maintained at the same level. Stained biofilms were observed and imaged using
the Neofluar 10×/1.65 objective. Each experiment was carried out twice. concentration, an indirect estimator of NO production (Mur et al., 2011), was determined in free cell supernatants using the inNO-T-II system (Innovative Instruments, Inc) following the manufacturer instructions. Real-time Bioactive Compound Library bacterial NO production was determined by amperometric method with a NO-specific amiNO-2000 microelectrode, using the inNO-T-II system. Microelectrode was previously stabilized by 15-min running in PBS buffer pH 7.2, followed by 15-min running in fresh Nfb-malic medium. Microelectrode was inserted 3–4 mm in static bacterial cultures. Recording time of NO production was 40 min per well, and the conversion of picoamperes to μM of NO was carried out according to manufacturer instruction. Active reduction
Selleckchem FDA-approved Drug Library of to NO in Faj164 mutant was determined fluorometrically, according to Molina-Favero et al. (2008). Fluorescence intensity was measured with a Fluoroskan Ascent microplate reader (Labsystems, 480-nm excitation, 525-nm emission) every 4 min for 2 h with 10 μM of the NO-specific fluorescent probe 4,5-diamino-fluorescein diacetate in presence of 0.1 mM NaNO2. To determine the effect of exogenous NO treatment, the NO donor S-nitrosoglutathione (GSNO) was used. GSNO was prepared freshly every day according to Hart (1985), and from the beginning of PJ34 HCl the experiment, the corresponding wells were added with 1, 25, 50, 100 μM, or 10 mM GSNO every 24 h up to d3. Biofilm formation was evaluated using crystal violet staining as described above. The effect of GSNO treatment on cell viability was evaluated by dilution plating
on ACR. All experiments, except amperometric determinations of NO that was determined twice, were performed in three complete independent assays each one with four replicas and repeated at least two times. Media ± SE are presented for each variable determined. Azospirillum brasilense Sp245 and Faj164 isogenic napA::Tn5 mutant were grown in NH4Cl- or KNO3-supplemented minimal Nfb liquid medium in cell culture plates without agitation for d1, d3, or d5. In NH4Cl, both strains grew gradually and to the same extent for the whole period assayed (Fig. 1). The similar growth kinetic showed by both strains indicates that, as was expected, the Nap activity is not required for growth in NH4Cl-supplemented medium. On the other hand, in KNO3 Nfb medium, remarkable differences were observed between both strains. The Sp245 wt strain grew fast the first day and then stopped growing (Fig. 1). However, Faj164 strain grew slowly on d1 and gradually increased its growth surpassing wt strain in d5 (Fig. 1).