Part:BBa_K1067006

Denitrification operon from Pseudomonas aeruginosa

This biobrick is the whole denitrification region from Pseudomonas aeruginosa PAO1 excluding only the enzyme in last step; Nitrous-oxide reductase ([http://ecocyc.org/PAER941193/NEW-IMAGE?type=LOCUS-POSITION&object=GLIQ-518&chromosome=CHROMOSOME-1 link to Biocyc]).

Usage and Biology

This brick has been shown hard to work with because it is a large region, all under one promoter. We purpose that splitting it into the 3 operons; like the conformation natively in P. aeruginosa and adding a separate promoter for each would make it easier to work with. If trying to to control the whole region under the same promoter one might experience premature mRNA transcripts because RNAP will fall of before the end of the region.

Sequence and Features

Characterization

To characterize this biobrick, we ran an anaerobic experiment in which we added a known amount of nitrite to an anaerobic flask, and measured the nitrous oxide produced using a microsensor. We had a lot of trouble with the microsensor (see especially hour 4 on the below graph) and were not able to conclusively prove that we were producing nitrous oxide. We would recommend rerunning the experiment with a more reliable sensor.

Contribution

Group: NAU-CHINA iGEM 2020

The problem is that N₂O couldn’t be detected precisely during the denitrification reaction, but we have discovered a new method.

Fig.1. Schematic diagram of SBR device(Liu Guohua, et al.,Environmental Engineering. 2020)

The gas samples are collected by the portable gas sampling pump every 30 min within one operating cycle and collected in a 1L gas sampling bag. The concentration of N₂O was determined by Agilent 6890N gas chromatography (GC) equipped with ECD detector.

According to the changes of DO (Dissolved Oxygen), pH and ORP (Oxidation-Reduction Potential) in A/O-SBR biological denitrification system during one operating cycle, DO, ORP and pH have A good indicator effect on the process of nitrification and denitrification, and thus the accumulation of N₂O--N can be judged and controlled.

Fig.2. Parameters change in the A/O- SBR system (Liu Guohua, et al., Environmental Engineering. 2020)

Here are the three equations to calculate the release rate, cumulative release and conversion rate of N₂O during the operating period.

The N₂O accumulation released in aerobic stage was 8.2 mg, about 6 times of that released in anoxic stage. According to the calculation, the conversion of N₂O occurs mainly in the aerobic stage, and its conversion rate is 2.84%.

Fig.3. N₂O emission rates and N₂O cumulative emission in A/O- SBR system(Liu Guohua, et al., Environmental Engineering. 2020)

This study got some conclusions:

①The release of N₂O occured mainly in the aerobic stage of A/O-SBR sewage treatment pilot system.

②The maximum release rate of N₂O was 2.02 μgmin^-1 gmLSS^-1 during one operating cycle of the A/O-SBR small scale test system. The cumulative release rate reached 8.2 mg after 300 min of operation, and the accumulation of nitrite also reached the maximum value of 7.5 mg/L.

Although the equipment is a little big to use in the laboratory, we can improve it in the future.