Effects of lomefloxacin and norfloxacin on the biological water denitrification process—an experimental study

doi:10.13745/j.esf.sf.2022.1.22

Abstract

Abstract:

Nitrate and antibiotic pollutions in water have attracted much attention in recent years, but the effects of combination antibiotic pollution on the biological water denitrification process is not clear. To address this issue, we tested norfloxacin and lomefloxacin under simulated experimental conditions. The $\text{NO}_{3}^{-}$-N and $\text{NO}_{2}^{-}$-N degradation results showed that lomefloxacin and norfloxacin had different inhibitory effects on water denitrification: Lomefloxacin promoted denitrification slightly in the early stage but inhibited it later on, whereas norfloxacin only inhibited it. Lomefloxacin combined with norfloxacin were less inhibitory than norfloxacin alone, and the combination showed antagonistic activity. The inhibitory activities of antibiotics ranked as norfloxacin > norfloxacin + lomefloxacin > lomefloxacin. Although the simulated experimental conditions did not fully match the actual water condition, the above results implied that combination antibiotics have antagonistic effects on the denitrification process. Such effects were related largely to the microbial numbers and activities, activities of denitrification enzymes, as well as abundance variations of dominant denitrifying bacteria Achromobacter xylosoxidans, Acinetobacter baumannii, and Pseudomonas sp. KY and the nosZ and aac genes. As reaction time increased, the denitrifying bacteria gradually adapted to the environment of low-level antibiotics and the number of quinolone resistance genes increased; also on the rise were the amount and activities of denitrifying bacteria, activities of denitrification enzymes, and microbial communities.

Key words: nitrate, antibiotic compound, denitrification, antagonism

CLC Number:

X523

ZHANG Yuye, HE Jiangtao, DENG Lu, ZOU Hua, ZHANG Jingang, YANG Meiping. Effects of lomefloxacin and norfloxacin on the biological water denitrification process—an experimental study[J]. Earth Science Frontiers, 2022, 29(5): 497-507.

Figures/Tables 11

Fig.1 Chemical structural formula of antibiotics

Fig.2 Experimental device diagram

Fig.3 Changes of Nitrate, Nitrite and Ammonia in the reaction system

Table 1 Statistical table of Nitrate and Nitrite degradation in each reaction system during the test period

组别		硝氮		亚硝氮
组别		降解时间/d	作用效果	降解时间/d	作用效果
空白周期V	各组	4	—	0	—
投加抗生素VI	Blank	4	—	0	—
	159 ng/L LOM	6	前期轻微促进,后期抑制	0	—
	509 ng/L NOR	10	明显抑制	10	抑制
	LOM+NOR	8	抑制作用减弱	7	轻微抑制
恢复期VII	Blank	4	—	0	—
	159 ng/L LOM	5	抑制作用	0	—
	509 ng/L NOR	7	抑制作用	0	—
	LOM+NOR	7	抑制作用	0	—

Table 2 Changes of gas content in the system during antibiotic administration period (0 days) and (8 days)

组别	N₂含量/%
组别	0d	8d	变化量	0d		8d		变化量		0d		8d		变化量
Blank	69.43	77.63	8.20		778.0		840.2		62.2		44.1		127.0		82.9
LOM	72.20	80.96	8.76		761.1		817.9		56.8		66.6		136.5		69.9
NOR	71.46	73.56	2.10		774.0		817.3		43.3		72.6		123.1		50.5
LOM+NOR	68.83	75.44	6.61		763.9		812.7		48.8		65.1		136.6		71.5

Fig.4 Changes of Denitrifying bacteria OD490 and OD600 in formal tests of each system (Error bar is the standard deviation of test results of three parallel samples)

Fig.5 Inhibition rate of denitrifying bacteria activity and quantity in each system in the VI cycle (Error bar is the standard deviation of test results of three parallel samples)

Fig.6 Variation of OTU quantity in each system in formal test

Fig.7 Cluster heat map of community structure of each sample species in formal test

Fig.8 Nar and Nir activity changes of each reaction system in formal test

Fig.9 Functional gene abundance of each sample in formal test

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