不同植物对沟渠沉积物反硝化速率及功能基因的影响研究
Effects of plant species on denitrification and functional genes in ditch sediment
查看参考文献51篇
文摘
|
植物是影响沉积物反硝化作用的重要因素之一,国内外已有不少研究探讨了植物对河口或湖泊沉积物反硝化速率的影响,但关于植物类型对自然沟渠沉积物反硝化速率及其相应功能基因的影响研究不多.因此,本文以7种常见沟渠植物为研究对象,通过室内盆栽试验,利用改进的乙炔抑制法和实时荧光定量PCR 技术研究了不同植物对自然沟渠沉积物反硝化速率和相应功能基因(nirS 和nirK)拷贝数的影响.结果表明,培养至第180d 时,不同植物生长条件下沉积物反硝化速率在2.85~ 13.20μg·m~(-2)·h~(-1)之间,不同植物间反硝化速率差异显著,且大型挺水植物>浮水植物>小型挺水植物.不同植物之间沉积物中nirS 基因拷贝数在2.70×10~8~ 5.02×10~8copies·g~(-1)之间,nirK 基因拷贝数在3.97×10~5~6.91×10~5copies·g~(-1)之间,与培养初期相比,培养180d 后沉积物中nirK、nirS 基因拷贝数明显增多.7种植物中,美人蕉沉积物中的反硝化功能基因拷贝数较高,狐尾藻较低,整体来看,基因拷贝数大小顺序为:挺水植物>浮水植物.nirS 基因拷贝数与NO_3~--N 含量、TN 含量及反硝化速率之间均呈显著性的正相关关系(p<0.05),但nirK 基因拷贝数与沉积物碳氮含量及反硝化速率之间相关性不显著. |
其他语种文摘
|
The influence of plant on the denitrification of sediment in the estuary or lake have been reported by many studies.However,the effects of plant species on the denitrification of sediment and function genes in the natural ditches is still not clear.Here,we explored the effects of seven ditch plants on denitrification and functional genes (nirS,nirK) in ditch sediment via pot experiments by using the chloramphenicol-amended acetylene inhibition procedure and real time-PCR.The results show that the denitrification rates of the sediment under different plant species ranged from 2.85 μg·m~(-2)·h~(-1) to 13.2 μg·m~(-2)·h~(-1) after 180 days.The denitrification rates were as follows:Macrophytes>floating plants>small emerged plants,and there was a significant difference among different plant species.The gene abundances of nirS ranged from 2.70 ×10~8 copies·g~(-1) to 5.02 ×10~8 copies·g~(-1),and the gene abundances of nirK ranged 3.97×10~5 copies·g~(-1) to 6.91×10~5 copies·g~(-1).Furthermore,the gene abandunces of nirK and nirS increased significantly after 180 days of incubation.The denitrification functional gene copies was the highesin the sediment of Canna indica,while the lowest in Myriophyllum spicatum.The gene abundances of emerged plants were higher than that of floating plants.Moreover,pearson correlation analysis showed that there was a significant positive correlation between nirS and NO_3~--N content,TN content,and denitrification rate (p<0.05),but the correlation between nirK and sediment physicochemical properties,denitrification rate were not significant. |
来源
|
环境科学学报
,2019,39(6):1808-1815 【核心库】
|
DOI
|
10.13671/j.hjkxxb.2018.0472
|
关键词
|
植物类型
;
沟渠沉积物
;
反硝化速率
;
nirK
;
nirS
|
地址
|
1.
中国科学院、水利部成都山地灾害与环境研究所, 成都, 610041
2.
中国科学院大学, 北京, 100049
3.
中国科学院山地表生过程与生态调控重点实验室, 中国科学院山地表生过程与生态调控重点实验室, 成都, 610041
|
语种
|
中文 |
文献类型
|
研究性论文 |
ISSN
|
0253-2468 |
学科
|
环境污染及其防治 |
基金
|
国家重点研发计划
;
国家水污染治理与控制专项
;
国家自然科学基金项目
|
文献收藏号
|
CSCD:6503075
|
参考文献 共
51
共3页
|
1.
Annelies J V. Effects of aquatic vegetation type on denitrification.
Biogeochemistry,2011,104(1/2/3):267-274
|
被引
3
次
|
|
|
|
2.
Braker G. Development of PCR primer stems for amplification of nitrite reductase genes(nirK and nirS) to detect denitrifying,bacteria in environment samples.
Applied &Environmental Microbiology,1998,64:3769-3775
|
被引
91
次
|
|
|
|
3.
Braker G. Nitrite reductase genes (nirK and nirS) as functional markers to investigate diversity of denitrifying bacteria in pacific northwest marine sediment communities.
Applied and Environmental Microbiology,2000,66(5):2096-2104
|
被引
77
次
|
|
|
|
4.
Canfield D. The evolution and future of earth's nitrogen cycle.
Science,2010,330:192-196
|
被引
172
次
|
|
|
|
5.
Chen Y N. Nitrite reductase genes as functional markers to investigate diversity of denitrifying bacteria during agricultural waste composting.
Applied Microbiology and Biotechnology,2014,98:4233-4243
|
被引
3
次
|
|
|
|
6.
程建华. 铜陵市河流沉积物中硝化和反硝化微生物分布特征.
环境科学,2016,37(4):1362-1370
|
被引
14
次
|
|
|
|
7.
陈斌泽.
长期施肥条件下青藏高原高寒草甸土壤中反硝化细菌丰度和群落结构的季节性变化研究,2013
|
被引
1
次
|
|
|
|
8.
陈登. 3种沉水植物根际对沉积物中典型氮循环微生物功能基因丰度的影响.
云南农业大学学报(自然科学),2018,33(2):314-323
|
被引
4
次
|
|
|
|
9.
Dang H Y. Diversity and distribution of sediment nirS-encoding bacterial assemblages in response to environmental gradients in the Eutrophied Jiaozhou Bay,China.
Microbial ecology,2008,58(1):161-169
|
被引
1
次
|
|
|
|
10.
Francis C A. Transitions in nirS-type denitrifier diversity, community composition, and biogeochemical activity along the Chesapeake Bay estuary.
Frontiers in Microbiology,2013,4:237
|
被引
10
次
|
|
|
|
11.
Guan X Y. Composition and variation of sediment bacterial and nir S-harboring bacterial communities at representative sites of the Bohai Gulf coastal zone,China.
World Journal of Microbiology and Biotechnology,2014,30:1291-1300
|
被引
3
次
|
|
|
|
12.
郭丽芸. 反硝化菌功能基因及其分子生态学研究进展.
微生物学通报,2011,38(4):583-590
|
被引
36
次
|
|
|
|
13.
Heylen K. The incidence of nirS and nirK and their genetic heterogeneity in cultivated denitrifiers.
Environmental Microbiology,2006,8(11):2012-2021
|
被引
33
次
|
|
|
|
14.
贺纪正. 土壤氮素转化的关键微生物过程及机制.
微生物学通报,2013,40(1):98-108
|
被引
123
次
|
|
|
|
15.
Kalscheur K N. Algal exudates and stream organic matter influence the structure and function of denitrifying bacterial communities.
Microbial Ecology,2012,64:881-892
|
被引
3
次
|
|
|
|
16.
Kong A. Impacts of different N management regimes on nitrifier and denitrifier communities and N cycling in soil microenvironments.
Soil Biology and Biochemistry,2010,42:1523-1533
|
被引
2
次
|
|
|
|
17.
Knops J M H. Mechanisms of Plant Species Impacts on Ecosystem Nitrogen Cycling.
Ecology Letters,2002,5(3):454-466
|
被引
51
次
|
|
|
|
18.
Lefebvre S. Nitrogen dynamics in rural streams: differences between geomorphologic units.
Annales de Limnologie-International Journal of Limnology. EDP Sciences,2006,42(1):43-52
|
被引
3
次
|
|
|
|
19.
刘杏认. 生物炭对华北农田土壤N_2O通量及相关功能基因丰度的影响.
环境科学,2018,39(8):3816-3824
|
被引
18
次
|
|
|
|
20.
鲁如坤.
土壤溶液化学分析方法,1999:308-311
|
被引
1
次
|
|
|
|
|