(一)期刊文章
[1] yuan m#, guo x#, wu l#, zhang y#, xiao n, ning d, shi z, zhou x, wu l, yang y, tiedje jm, zhou j*. climate warming enhances microbial network complexity and stability. nature climate change (accepted).
[2] lei j#, guo x#, zeng y, zhou j, gao q*, yang y*. temporal changes of global soil respiration since 1987. nature communications 2021, 12: 403
[3] guo x#, gao q#, yuan m#, wang g#, zhou x, feng j, shi z, hale l, wu l, zhou a, tian r, liu f, wu b, chen l, gyo jung c, niu s, li d, xu x, jiang l, escalas a, wu l, he z, van nostrand jd, ning d, liu x, yang y, schuur, eag, konstantinidis kt, cole jr, penton cr, luo y, tiedje jm, zhou j*. gene-informed decomposition model predicts lower soil carbon loss due to persistent microbial adaptation to warming. nature communications 2020, 11: 4897.
[4] guo x#, zhou x#, hale l#, yuan m, ning d, feng j, shi z, li z, feng b, gao q, wu l, shi w, zhou a, fu y, wu l, he z, van nostrand jd, qiu g, liu x, luo y, tiedje jm, yang y, zhou j*. climate warming accelerates temporal scaling of grassland soil microbial biodiversity. nature ecology & evolution 2019, 3(4): 612-619.
[5] guo x#, feng j#, shi z#, zhou x, yuan m, tao x, hale l, yuan t, wang j, qin y, zhou a, fu y, wu l, he z, van nostrand jd, ning d, liu x, luo y, tiedje jm, yang y*, zhou j*. climate warming leads to divergent succession of grassland microbial communities. nature climate change 2018, 8(9):813-818.
[6] guo x#, zhou x#, hale l, yuan m, feng j, ning d, shi z, qin y, liu f, wu l, he z, van nostrand jd, liu x, luo y, tiedje jm, zhou j*. taxonomic and functional responses of soil microbial communities to annual removal of aboveground plant biomass. frontiers in microbiology 2018, 9(954).
[7] guo x, yin h, liang y, hu q, zhou x, xiao y, ma l, zhang x, qiu g, liu x*. comparative genome analysis reveals metabolic versatility and environmental adaptations of sulfobacillus thermosulfidooxidans strain st. plos one 2014, 9(6):e99417.
[8] dai z#, guo x#, yin h, liang y, cong j, liu x*. identification of nitrogen-fixing genes and gene clusters from metagenomic library of acid mine drainage. plos one 2014, 9(2):e87976.
[9] guo x, yin h, cong j, dai z, liang y, liu x*. rubisco gene clusters found in a metagenome microarray from acid mine drainage. applied and environmental microbiology 2013, 79(6):2019.
[10] liu f, wang z, wu b, bjerg jt, hu w, guo x, guo j, nielsen lp, qiu r*, xu m*. cable bacteria extend the impacts of elevated dissolved oxygen into anoxic sediments. the isme journal 2021.
[11] feng j, wang c, lei j, yang y, yan q, zhou x, tao x, ning d, yuan m, qin y, , shi z, guo x, he z, van nostrand jd, wu l, bracho-garillo rg, penton cr, cole jr, konstantinidis kt, luo y, schuur eag, tiedje jm, and zhou j*. warming-induced permafrost thaw exacerbates tundra soil carbon decomposition mediated by microbial community. microbiome 2020, 8:3.
[12] ning d, yuan m, wu l, zhang y, guo x, zhou x, yang y, arkin ap, firestone mk, zhou j*. a quantitative framework reveals ecological drivers of grassland microbial community assembly in response to warming. nature communications 2020, 11:4717.
[13] wu r, chia b, cole r. j, gunturu k. s, guo x, tian r, gu j, zhou j, tiedje m. j*. targeted assemblies of cas1 suggest crispr-cas’s response to soil warming. the isme journal 2020, 14:1651–1662.
[14] johnston e, hatt j, he z, wu l, guo x, luo y, schuur e, tiedje jm, zhou j, konstantinidis kt*. responses of tundra soil microbial communities to half a decade of warming at two critical depths. proceedings of the national academy of science 2019, 116(30): 15096-15105.
[15] hale l, feng w, yin h, guo x, zhou x, bracho r, pegoraro e, penton cr, wu l, cole jr, konstantinidis kt, luo y, tiedje jm, schuur e, zhou j*. tundra microbial community taxa and traits predict decomposition parameters of stable, old soil organic carbon. the isme journal 2019, 13(12): 2901-2915.
[16] gao q, yang y, feng j, tian r, guo x, ning d, hale l, wang m, cheng j, wu l, zhao m, zhao j, wu l, qin y, qi q, liang y, sun b, chu h, zhou j*. the spatial scale dependence of diazotrophic and bacterial community assembly in paddy soil. global ecology and biogeography 2019, 0: 1-13.
[17] feng j, penton cr, he z, van nostrand jd, yuan mm, wu l, wang c, qin y, shi zj, guo x, schuur eag, luo y, bracho r, konstantinidis kt, cole jr, tiedje jm, yang y, zhou j. long-term warming in alaska enlarges the diazotrophic community in deep soils. mbio 2019, 10(1):e02521-02518.
[18] shi z*, lin y, wilcox kr, souza l, jiang l, jiang j, jung cg, xu x, yuan m, guo x, wu l, zhou j, luo y. successional change in species composition alters climate sensitivity of grassland productivity. global change biology 2018, 24(10):4993-5003.
[19] zhang x, liu x, liang y, guo x, xiao y, ma l, miao b, liu h, peng d, huang w, zhang y, yin h. adaptive evolution of extreme acidophile sulfobacillus thermosulfidooxidans potentially driven by horizontal gene transfer and gene loss. applied and environmental microbiology 2017, 83(7):e03098-03016.
[20] zhang x, liu x, liang y, xiao y, ma l, guo x, miao b, liu h, peng d, huang w, yin h. comparative genomics unravels the functional roles of co-occurring acidophilic bacteria in bioleaching heaps. frontiers in microbiology 2017, 8(790).
[21] guo y, guo x, wu h, li s, wang g, liu x*, qiu g, wang d. a novel bio-oxidation and two-step thiourea leaching method applied to a refractory gold concentrate. hydrometallurgy 2017, 171:213-221.
[22] liu y, yang h, zhang x, xiao y, guo x, liu x. genomic analysis unravels reduced inorganic sulfur compound oxidation of heterotrophic acidophilic acidicaldus sp. strain dx-1. biomed research international 2016:8.
[23] hu q, guo x, liang y, hao x, ma l, yin h, liu x*. comparative metagenomics reveals microbial community differentiation in a biological heap leaching system. research in microbiology 2015, 166(6):525-534.
[24] li q, ding d, sun j, wang q, hu e, shi w, ma l, guo x, liu x. community dynamics and function variation of a defined mixed bioleaching acidophilic bacterial consortium in the presence of fluoride. annals of microbiology 2015, 65(1):121-128.
[25] jiang h, liang y, yin h, xiao y, guo x, xu y, hu q, liu h, liu x. effects of arsenite resistance on the growth and functional gene expression of leptospirillum ferriphilum and acidithiobacillus thiooxidans in pure culture and coculture. biomed research international 2015.
[26] yin h, zhang x, li x, he z, liang y, guo x, hu q, xiao y, cong j, ma l, niu j, liu x. whole-genome sequencing reveals novel insights into sulfur oxidation in the extremophile acidithiobacillus thiooxidans. bmc microbiology 2014, 14(1):179.
[27] xu y, yin h, jiang h, liang y, guo x, ma l, xiao y, liu x. comparative study of nickel resistance of pure culture and co-culture of acidithiobacillus thiooxidans and leptospirillum ferriphilum. archives of microbiology 2013, 195(9):637-646.
[28] liang y, gao h, guo x, chen j, qiu g, he z, zhou j, liu x. transcriptome analysis of pellicle formation of shewanella oneidensis. archives of microbiology 2012, 194(6):473-482.