The energetic conversion competence of Escherichia coli during aerobic respiration studied by 31P NMR using a circulating fermentation system.

To determine the actual potential of the energetic conversion efficiency of Escherichia coli during aerobic respiration, apparent P/O ratios (P/O(app)) under either limited or standard glucose-feeding conditions were estimated. The previously reported circulating fermentation system (CFS) was used, and (31)P NMR saturation-transfer (ST) techniques were employed. By coupling with on-line NMR observations, CFS allowed us to evaluate cellular energetics directly, with both the dissolved oxygen tension and glucose feeding precisely controlled to prevent the effect of substrate-level phosphorylation based on aerobic or anaerobic acidogenesis in E. coli cells. Phosphate consumption rates under standard and limited glucose-conditions were estimated as 4.62 +/- 0.46 and 1.99 +/- 0.11 micromol/s g of dry cell weight (DCW), respectively. Using simultaneously assessed O(2) consumption rates, the P/O(app) values under these two conditions were estimated as 1.4 +/- 0.3 and 1.5 +/- 0.1, respectively. To correlate the obtained P/O(app) values with the potential efficiency of respiratory enzymes, we determined the activities of two NADH dehydrogenases (NDH 1 and 2) and two ubiquinol oxidases (bo- and bd-type) during the periods when ST was performed. NDH-1 activities in standard or limited glucose cultures were maintained at 57% or 58% of the total NADH oxidizing activity. The percentages of bo-type oxidase activity in relation to the total ubiqinol oxidizing activity under the standard and limited glucose conditions were 32% and 36%, respectively. These percentages of enzymatic activities represent the respiratory competence of E. coli cells, suggesting that, during the NMR observatory period, the enzymatic activity was not at a maximum, which could also explain the estimated P/O(app) values. If this is the case, enhancing the expression of the bo-type oxidase or disrupting of the bd-type oxidase gene could be effective approach to increasing both the P/O ratio and cellular yields.

In vivo NMR system for evaluating oxygen-dependent metabolic status in microbial culture.

To optimize an appropriate microbial culture in a fermentor, precise control of the medium's dissolved oxygen tension (DOT) is crucial. In particular, to study the effect of DOT on cellular metabolic status by using in vivo nuclear magnetic resonance (NMR) measurements, the set-up of the experiment must be optimized to maintain DOT in the culture. In the conventional method, DOT is monitored by a sensor inside a fermentor and is controlled by changing the agitation rate. Here, we report a novel and accurate system that minimizes time lag by an automated aeration flow control device, allowing an NMR spectrometer to monitor representative metabolites in real-time. To fulfill these two objects, the fermentor was composed of a fermentation vessel and two outer tubes, through which the medium was circulated by rotary pumps. One tube monitored DOT in via a sensor, and at the same time the other tube monitored metabolites via an NMR spectrometer. In this study, we used this system to analyze the responses of Escherichia coli cells under various oxygen conditions. The results validated the use of this system in the study of microbial metabolism.