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[1] He R, Zeng J*, Zhao D, Wang S, Wu QL. Decreased spatial variation and deterministic processes of bacterial community assembly in the rhizosphere of Phragmites australis across the Middle–Lower Yangtze plain. Molecular Ecology, 2022, 31(4), 1180-1195.
[2] Qin M, Xu H, Zhao D, Zeng J*, Wu QL. Aquaculture drives distinct patterns of planktonic and sedimentary bacterial communities: insights into co-occurrence pattern and assembly processes. Environmental Microbiology, 2022, 24(9), 4079-4093.
[3] Zhou Q, He R, Zhao D, Zeng J*, Yu Z, Wu QL. Contrasting Patterns of the Resident and Active Rhizosphere Bacterial Communities of Phragmites Australis. Microbial Ecology, 2022, 83, 314–327.
[4] Jiao C, Zhao D, Zeng J*, Wu QL. Eutrophication in subtropical lakes reinforces the dominance of balanced-variation component in temporal bacterioplankton community heterogeneity by lessening stochastic processes. FEMS Microbiology Ecology, 2022, 98(6), fiac051.
[5] Wang S, Jiao C, Zhao D, Zeng J*, Xing P, Liu Y, Wu QL. Disentangling the assembly mechanisms of bacterial communities in a transition zone between the alpine steppe and alpine meadow ecosystems on the Tibetan Plateau. Science of the Total Environment, 2022, 847, 157446.
[6] Xu H, Zeng J*, Li C, Zhao D, He R, Wu QL. Distinct microhabitats affect the relative balance of ecological processes shaping the spatial distribution of bacterial communities in lakeshore habitats. Freshwater Biology, 2021, 66, 1475-1489.
[7] Wang YJ, Cao XY, Zeng J*, Li HB, Zhao DY, Wu QL. Distinct shifts in bacterioplankton community composition and functional gene structure between macrophyte- and phytoplankton-dominated regimes in a large shallow lake. Limnology and Oceanography, 2020, 65, S208-S219.
[8] Huang R, Zeng J*, Zhao DY, Yong B, Yu ZB. Co-association of two nir denitrifiers under the influence of emergent macrophytes. Microbial Ecology, 2020, 80(4), 809-821.
[9] Xu HM, Zhao DY, Zeng J*, Jiao CC, Yu ZB, Wu QL. Distinct successional patterns and processes of free-living and particle-attached bacterial communities throughout a phytoplankton bloom. Freshwater Biology, 2020, 65(8), 1363-1375.
[10] Jiao CC, Zhao DY, Zeng J*, Guo L, Yu ZB. Disentangling the seasonal co-occurrence patterns and ecological stochasticity of planktonic and benthic bacterial communities within multiple lakes. Science of the Total Environment, 2020, 740, 140010.
[11] He RJ, Zeng, J*, Zhao DY, Huang R, Yu ZB, Wu QL. Contrasting patterns in diversity and community assembly of Phragmites australis root-associated bacterial communities from different seasons. Applied and Environmental Microbiology, 2020, 86(14), e00379-20.
[12] Zeng J*, Jiao CC, Zhao DY, Xu HM, Huang R, Cao XY, Yu ZB, Wu QL. Patterns and assembly processes of planktonic and sedimentary bacterial community differ along a trophic gradient in freshwater lakes. Ecological Indicators, 2019, 106, 105491.
[13] Xu HM, Zhao DY, Huang R, Cao XY, Zeng J*, Yu ZB, Hooker KV, Hambright KD, Wu QL. Contrasting network features between free-living and particle-attached bacterial communities in Taihu Lake. Microbial Ecology, 2018, 76(2), 303-313.
[14] Zeng J, Zhao DY, Li HB, Huang R, Wang JJ, Wu QL*. A monotonically declining elevational pattern of bacterial diversity in freshwater lake sediments. Environmental Microbiology, 2016, 18(12), 5175-5186.
[15] Zeng J, Bian YQ, Xing P, Wu QL*. Macrophyte species drive the variation of bacterioplankton community composition in a shallow freshwater lake. Applied and Environmental Microbiology, 2012, 78(1), 177-184.
[16] Zeng J, Wang WX*. Temperature and irradiance influences on cadmium and zinc uptake and toxicity in a freshwater cyanobacterium, Microcystis aeruginosa. Journal of Hazardous Materials, 2011, 190(1-3), 922-929.
[17] Zeng J, Yang LY, Wang WX*. High sensitivity of cyanobacterium Microcystis aeruginosa to copper and the prediction of copper toxicity. Environmental Toxicology and Chemistry, 2010, 29(10), 2260-2268.
[18] Zeng J, Yang LY, Wang WX*. Acclimation to and recovery from cadmium and zinc exposure by a freshwater cyanobacterium, Microcystis aeruginosa. Aquatic Toxicology, 2009, 93(1), 1-10.
[19] Zeng J, Yang LY, Wang WX*. Cadmium and zinc uptake and toxicity in two strains of Microcystis aeruginosa predicted by metal free ion activity and intracellular concentration. Aquatic Toxicology, 2009, 91(3), 212-220.
[20] Zeng J, Wang WX*. The importance of cellular phosphorus in controlling the uptake and toxicity of cadmium and zinc in Microcystis aeruginosa, a freshwater cyanobacterium. Environmental Toxicology and Chemistry, 2009, 28(8), 1618-1626. |
