Agricultural ecosystems rather than fertilization strategies drives structure and composition of the ureolytic microbial functional guilds

Ureolytic microorganisms are significant in the transformation of soil nitrogen as they secrete urease to hydrolyze urea. This study aimed to investigate the effects of different fertilization regimes on ureolytic microbial functional guilds (bacteria, fungi, and archaea) in various agricultural eco...

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Published in:Journal of environmental management 2024-12, Vol.372, p.123148, Article 123148
Main Authors: Lv, Na, Gong, Ping, Sun, Hao, Sun, Xiangxin, Liu, Zhiguang, Xie, Xueshi, Xue, Yan, Song, Yuchao, Wu, Kaikuo, Wang, Tingting, Wu, Zhijie, Zhang, Lili
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Language:English
Subjects:
Agriculture
Archaea
Bacteria - genetics
Bacteria - metabolism
Ecosystem
Fertilizers - analysis
Fungi
Metagenome
Nitrogen - metabolism
Paddy and dryland
Soil - chemistry
Soil Microbiology
Urea - metabolism
Urease
Urease - metabolism
ureC gene
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container_title Journal of environmental management
container_volume 372
creator Lv, Na
Gong, Ping
Sun, Hao
Sun, Xiangxin
Liu, Zhiguang
Xie, Xueshi
Xue, Yan
Song, Yuchao
Wu, Kaikuo
Wang, Tingting
Wu, Zhijie
Zhang, Lili
description Ureolytic microorganisms are significant in the transformation of soil nitrogen as they secrete urease to hydrolyze urea. This study aimed to investigate the effects of different fertilization regimes on ureolytic microbial functional guilds (bacteria, fungi, and archaea) in various agricultural ecosystems. Soil samples were collected from a long-term agricultural field experiment involving paddy and dryland soils. The experiment consisted of four fertilization treatments: nitrogen fertilizer (N), nitrogen fertilizer combined with composite urease/nitrification inhibitor (NI), nitrogen fertilizer combined with straw (NS), and nitrogen fertilizer combined with manure (NO). A metagenomic sequencing technique was used to assess the composition of ureolytic microbial functional guilds using the target ureC gene, along with the evaluation of soil physicochemical properties, the abundance of ureC genes from different microbial guilds, and the urease activity. The results showed that the NI treatment significantly increased the abundance of ureC genes from different microbial guilds in the two agricultural ecosystems compared with other fertilization treatments. In dryland soil, the abundance of ureC genes was positively correlated with urease activity. The ureolytic bacterial functional guild exhibits greater dominance at all taxonomic levels compared to the ureolytic fungal and archaeal functional guilds. The alpha diversity of ureolytic microbial functional guilds was greater in dryland soil than in paddy soil. Principal coordinate analysis showed that the structure of the ureolytic microbial functional guilds could be separated into two groups based on agricultural ecosystems. Phosphorus is a key environmental factor affecting the ureolytic microbial functional guilds in two agricultural ecosystems, and the structure of the ureolytic bacteria functional guild is more susceptible to pH. The results suggest that the structure of ureolytic microbial functional guilds is primarily determined by agricultural ecosystems rather than by fertilization treatments. Additionally, fertilization treatments across different agricultural ecosystems significantly impacted the community composition of ureolytic bacteria, fungi, and archaea microorganism. [Display omitted] •Compare the differences among bacteria, fungi, and archaea ureolytic microbial.•Ureolytic bacteria community exhibit the highest OTU, dominant phyla and α-diversity.•NI treatment increased the abundance of t
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This study aimed to investigate the effects of different fertilization regimes on ureolytic microbial functional guilds (bacteria, fungi, and archaea) in various agricultural ecosystems. Soil samples were collected from a long-term agricultural field experiment involving paddy and dryland soils. The experiment consisted of four fertilization treatments: nitrogen fertilizer (N), nitrogen fertilizer combined with composite urease/nitrification inhibitor (NI), nitrogen fertilizer combined with straw (NS), and nitrogen fertilizer combined with manure (NO). A metagenomic sequencing technique was used to assess the composition of ureolytic microbial functional guilds using the target ureC gene, along with the evaluation of soil physicochemical properties, the abundance of ureC genes from different microbial guilds, and the urease activity. The results showed that the NI treatment significantly increased the abundance of ureC genes from different microbial guilds in the two agricultural ecosystems compared with other fertilization treatments. In dryland soil, the abundance of ureC genes was positively correlated with urease activity. The ureolytic bacterial functional guild exhibits greater dominance at all taxonomic levels compared to the ureolytic fungal and archaeal functional guilds. The alpha diversity of ureolytic microbial functional guilds was greater in dryland soil than in paddy soil. Principal coordinate analysis showed that the structure of the ureolytic microbial functional guilds could be separated into two groups based on agricultural ecosystems. Phosphorus is a key environmental factor affecting the ureolytic microbial functional guilds in two agricultural ecosystems, and the structure of the ureolytic bacteria functional guild is more susceptible to pH. The results suggest that the structure of ureolytic microbial functional guilds is primarily determined by agricultural ecosystems rather than by fertilization treatments. Additionally, fertilization treatments across different agricultural ecosystems significantly impacted the community composition of ureolytic bacteria, fungi, and archaea microorganism. [Display omitted] •Compare the differences among bacteria, fungi, and archaea ureolytic microbial.•Ureolytic bacteria community exhibit the highest OTU, dominant phyla and α-diversity.•NI treatment increased the abundance of the ureC gene from different microbial guilds.•Phosphorus is a key factor affecting the ureolytic microbial functional guild.</description><identifier>ISSN: 0301-4797</identifier><identifier>ISSN: 1095-8630</identifier><identifier>EISSN: 1095-8630</identifier><identifier>DOI: 10.1016/j.jenvman.2024.123148</identifier><identifier>PMID: 39566206</identifier><language>eng</language><publisher>England: Elsevier Ltd</publisher><subject>Agriculture ; Archaea ; Bacteria - genetics ; Bacteria - metabolism ; Ecosystem ; Fertilizers - analysis ; Fungi ; Metagenome ; Nitrogen - metabolism ; Paddy and dryland ; Soil - chemistry ; Soil Microbiology ; Urea - metabolism ; Urease ; Urease - metabolism ; ureC gene</subject><ispartof>Journal of environmental management, 2024-12, Vol.372, p.123148, Article 123148</ispartof><rights>2024 Elsevier Ltd</rights><rights>Copyright © 2024 Elsevier Ltd. 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The results showed that the NI treatment significantly increased the abundance of ureC genes from different microbial guilds in the two agricultural ecosystems compared with other fertilization treatments. In dryland soil, the abundance of ureC genes was positively correlated with urease activity. The ureolytic bacterial functional guild exhibits greater dominance at all taxonomic levels compared to the ureolytic fungal and archaeal functional guilds. The alpha diversity of ureolytic microbial functional guilds was greater in dryland soil than in paddy soil. Principal coordinate analysis showed that the structure of the ureolytic microbial functional guilds could be separated into two groups based on agricultural ecosystems. Phosphorus is a key environmental factor affecting the ureolytic microbial functional guilds in two agricultural ecosystems, and the structure of the ureolytic bacteria functional guild is more susceptible to pH. 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This study aimed to investigate the effects of different fertilization regimes on ureolytic microbial functional guilds (bacteria, fungi, and archaea) in various agricultural ecosystems. Soil samples were collected from a long-term agricultural field experiment involving paddy and dryland soils. The experiment consisted of four fertilization treatments: nitrogen fertilizer (N), nitrogen fertilizer combined with composite urease/nitrification inhibitor (NI), nitrogen fertilizer combined with straw (NS), and nitrogen fertilizer combined with manure (NO). A metagenomic sequencing technique was used to assess the composition of ureolytic microbial functional guilds using the target ureC gene, along with the evaluation of soil physicochemical properties, the abundance of ureC genes from different microbial guilds, and the urease activity. The results showed that the NI treatment significantly increased the abundance of ureC genes from different microbial guilds in the two agricultural ecosystems compared with other fertilization treatments. In dryland soil, the abundance of ureC genes was positively correlated with urease activity. The ureolytic bacterial functional guild exhibits greater dominance at all taxonomic levels compared to the ureolytic fungal and archaeal functional guilds. The alpha diversity of ureolytic microbial functional guilds was greater in dryland soil than in paddy soil. Principal coordinate analysis showed that the structure of the ureolytic microbial functional guilds could be separated into two groups based on agricultural ecosystems. Phosphorus is a key environmental factor affecting the ureolytic microbial functional guilds in two agricultural ecosystems, and the structure of the ureolytic bacteria functional guild is more susceptible to pH. The results suggest that the structure of ureolytic microbial functional guilds is primarily determined by agricultural ecosystems rather than by fertilization treatments. Additionally, fertilization treatments across different agricultural ecosystems significantly impacted the community composition of ureolytic bacteria, fungi, and archaea microorganism. [Display omitted] •Compare the differences among bacteria, fungi, and archaea ureolytic microbial.•Ureolytic bacteria community exhibit the highest OTU, dominant phyla and α-diversity.•NI treatment increased the abundance of the ureC gene from different microbial guilds.•Phosphorus is a key factor affecting the ureolytic microbial functional guild.</abstract><cop>England</cop><pub>Elsevier Ltd</pub><pmid>39566206</pmid><doi>10.1016/j.jenvman.2024.123148</doi></addata></record>
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subjects Agriculture
Archaea
Bacteria - genetics
Bacteria - metabolism
Ecosystem
Fertilizers - analysis
Fungi
Metagenome
Nitrogen - metabolism
Paddy and dryland
Soil - chemistry
Soil Microbiology
Urea - metabolism
Urease
Urease - metabolism
ureC gene
title Agricultural ecosystems rather than fertilization strategies drives structure and composition of the ureolytic microbial functional guilds
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