Please use this identifier to cite or link to this item: https://hdl.handle.net/10321/4704
Title: Profiling of key nitrogen converting organisms in wastewater treatment plants with diffused aeration
Authors: Kumalo, Puseletso Constance 
Keywords: Biological nutrient removal;Dissolved oxygen;Nitrogen converting organisms;Wastewater treatment plants;Wastewater
Issue Date: Sep-2022
Abstract: 
Maintaining stable nitrification rates in biological nutrient removal (BNR) systems is difficult
due to the slow growth rates of nitrifying bacteria and their sensitivity to environmental and
operational conditions. Dissolved oxygen (DO) concentration in the aeration tank significantly
affects nitrification and nitrifying bacterial growth. Currently, diffused aeration systems are
gaining popularity over conventional surface aeration systems due to their advantages like
process stability, better control, and lower cost of operation. However, studies regarding the
impact of this aeration type on the selection of functional microbial communities in wastewater
treatment plants are still lacking. This study focused on investigating the community structure
and activity of key nitrogen converting organisms within two different municipal full-scale
wastewater treatment plants (WWTP A and WWTP B) operated with fine bubble diffused
aeration. WWTP A was relatively a large plant with a flow rate of 71 ML/day and consisted of
three parallel BNR systems (reactor 1, 2, and 3), operated using a similar mode whereas WWTP
B was relatively a small plant (0.5 ML/day) with a single BNR system.
Composite sludge samples from aeration tanks, as well as influent and effluent water samples,
were collected monthly from August 2019 to February 2020 and from June 2020 to August
2020. The nutrient removal performance of the plant was estimated from the influent and
effluent chemical analysis. Floc structure analysis and sludge volume index were calculated to
assess the settling characteristics. In addition, nitrifying bacterial population dynamics and
their activities were assessed using quantitative real-time and reverse transcriptase PCR,
respectively in relation to selected plant operational (DO, temperature, substrate concentration)
conditions. The average ammonia removal at WWTP A was 95±5.6% which correlated with
DO concentration in the aeration tank and the nitrification rate of the plant, whereas the WWTP
B recorded 98±02% average ammonia removal efficiency with a more stable DO level in this
plant. The sludge volume index (SVI) values were below 150mL/g in both plants, indicating
good sludge settling under fine bubble diffused aeration. However, the floc structure varied
across the reactors during the study period and ranged from small to medium, open to compact,
and irregular with occasional filaments branching mainly in WWTP A.
The microbial analysis of sludge samples showed that ammonia oxidising bacteria (AOB) 16S
rRNA gene abundance was high in all the three reactors in WWTP A as compared with nitrite oxidising bacteria (NOB). In WWTP B, the average 16S rRNA gene copies for NOB were
observed to be higher than AOB. In addition, in WWTP A, a negative correlation was found
between the AOB 16S rRNA population and DO concentration in reactor 1 (r = -0.40), while
a positive correlation was found in reactor 3 (r = 0.47) with no clear correlation in reactor 2 as
well as in WWTP B. In both plants, Nitrobacter spp. was the dominant NOB, while the relative
abundance of Nitrospira spp. was generally consistent throughout the study. The nxrB copy
number was observed to be higher than that of nxrA (encoding for Nitrobacter spp.). The
highest amoA copy number was observed when the temperatures were high (22 ⁰C -26.1 ⁰C),
implying that increasing temperatures possibly benefited AOB growth.
In terms of functional gene expression, a rapid decrease in expression levels of amoA was
observed in both plants while the expression levels of nxrB were observed to increase rapidly
as the temperature increased. In contrast, expression levels of the nxrA were relatively more
consistent throughout the study period in both plants. At WWTP A, there was a positive
correlation between AOB expression (amoA) and DO concentration in all reactors (reactor 1: r
= 0.49; reactor 2: r = 0.78 and reactor 3: r = 0.32; p = 0.05). However, no clear correlation was
found between NOB expression (nxrA and nxrB) and DO concentration. At WWTP B, a
negative correlation was observed between nxrA expression levels and DO concentration (r =
- 0.34, p = 0.05). However, DO concentration showed no clear correlation with amoA and nxrB
expression levels.
The phylogenetic analysis of nxrB populations in both the plants also revealed similarities that
are closely related to uncultured Nitrospira spp., nitrite oxidoreductase subunit B, which has
been implicated in complete nitrification (COMAMMOX). These observations indicate a need
for more research effort using next-generation sequencing to identify and quantify novel
nitrifying bacterial including COMAMMOX and ANAMMOX in WWTPs that were
previously unachievable using conventional molecular techniques. In conclusion, this study
revealed that the fine bubble diffused aeration operated at relatively high DO concentration
was able to effectively remove ammonia in both plants resulting in stable and high nitrification
rates even at different seasons and loading rates. It also promoted compact flocs with good
settleability as well as facilitated optimal and diverse functional nitrifying bacterial community
structure and activity.
Description: 
This work is submitted in complete fulfillment of the academic requirements for the degree of Masters of Applied Sciences: Biotechnology and Food Sciences, Durban University of Technology, Durban, South Africa, 2002.
URI: https://hdl.handle.net/10321/4704
DOI: https://doi.org/10.51415/10321/4704
Appears in Collections:Theses and dissertations (Applied Sciences)

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