AOA and AOB communities respond differently to changes of soil pH under long-term fertilization

Ruibo Sun; David D. Myrold; Daozhong Wang; Xisheng Guo; Haiyan Chu

doi:10.1007/s42832-019-0016-8

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Soil Ecology Letters ›› 2019, Vol. 1 ›› Issue (3-4) : 126-135. DOI: 10.1007/s42832-019-0016-8

RESEARCH ARTICLE

AOA and AOB communities respond differently to changes of soil pH under long-term fertilization

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Abstract

Archaeal and bacterial ammonia-oxidizers drive the first step of nitrification, ammonia oxidation. Despite their importance, the relative contribution of soil factors influencing the abundance, diversity and community composition of ammonia oxidizing archaea (AOA) and bacteria (AOB) are seldom compared. In this study, the AOA and AOB communities in soils from a long-term fertilization experiment (which formed gradients of pH and nutrients) were measured using 454 pyrosequencing of the amoA gene. Results showed that both AOA and AOB communities were influenced by fertilization practice. Changes of AOA abundance, diversity and community structure were closely correlated with a single factor, soil pH, and the abundance and diversity of AOA were lower under the acidified treatments. By contrast, AOB abundance was higher in the acidified soil than in the control soil while AOB diversity was little impacted by soil acidification, and both the abundance and diversity of AOB were most highly correlated with soil carbon and available phosphorus. These results indicated that AOB diversity seemed more resistant to soil acidification than that of AOA, and also suggested that AOB have greater ecophysiological diversity and broader range of habitats than AOA in this lime concretion black soil, and the potential contribution of AOB to ammonia oxidation in acid environments should not be overlooked.

Keywords

AOA / AOB / Microbial diversity / Soil pH / Long-term fertilization / High-throughput sequencing

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Ruibo Sun, David D. Myrold, Daozhong Wang, Xisheng Guo, Haiyan Chu. AOA and AOB communities respond differently to changes of soil pH under long-term fertilization. Soil Ecology Letters, 2019, 1(3-4): 126‒135 https://doi.org/10.1007/s42832-019-0016-8

References

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[1]	Abascal, F., Zardoya, R., Telford, M.J., 2010. TranslatorX: multiple alignment of nucleotide sequences guided by amino acid translations. Nucleic Acids Research 38, W7-13 CrossRef Pubmed Google scholar

[2]

Caporaso, J.G., Kuczynski, J., Stombaugh, J., Bittinger, K., Bushman, F.D., Costello, E.K., Fierer, N., Peña, A.G., Goodrich, J.K., Gordon, J.I., Huttley, G.A., Kelley, S.T., Knights, D., Koenig, J.E., Ley, R.E., Lozupone, C.A., McDonald, D., Muegge, B.D., Pirrung, M., Reeder, J., Sevinsky, J.R., Turnbaugh, P.J., Walters, W.A., Widmann, J., Yatsunenko, T., Zaneveld, J., Knight, R., 2010. QIIME allows analysis of high-throughput community sequencing data. Nature Methods 7, 335–336

CrossRef Pubmed Google scholar

[3]	Carey, C.J., Dove, N.C., Beman, J.M., Hart, S.C., Aronson, E.L., 2016. Meta-analysis reveals ammonia-oxidizing bacteria respond more strongly to nitrogen addition than ammonia-oxidizing archaea. Soil Biology & Biochemistry 99, 158–166 CrossRef Google scholar

[4]	Cytryn, E., Levkovitch, I., Negreanu, Y., Dowd, S., Frenk, S., Silber, A., 2012. Impact of short-term acidification on nitrification and nitrifying bacterial community dynamics in soilless cultivation media. Applied and Environmental Microbiology 78, 6576–6582 CrossRef Pubmed Google scholar

[5]	De Boer, W., Gunnewiek, P.J.A.K., Veenhuis, M., Bock, E., Laanbroek, H.J., 1991. Nitrification at low pH by aggregated chemolithotrophic bacteria. Applied and Environmental Microbiology 57, 3600–3604 Pubmed

[6]	De’Ath, G., 2002. Multivariate regression trees: a new technique for modeling species-environment relationships. Ecology 83, 1105–1117.

[7]	Edgar, R.C., 2010. Search and clustering orders of magnitude faster than BLAST. Bioinformatics (Oxford, England) 26, 2460–2461 CrossRef Pubmed Google scholar

[8]	Erguder, T.H., Boon, N., Wittebolle, L., Marzorati, M., Verstraete, W., 2009. Environmental factors shaping the ecological niches of ammonia-oxidizing archaea. FEMS Microbiology Reviews 33, 855–869 CrossRef Pubmed Google scholar

[9]	Geets, J., Boon, N., Verstraete, W., 2006. Strategies of aerobic ammonia-oxidizing bacteria for coping with nutrient and oxygen fluctuations. FEMS Microbiology Ecology 58, 1–13.

[10]	Gubry-Rangin, C., Nicol, G.W., Prosser, J.I., 2010. Archaea rather than bacteria control nitrification in two agricultural acidic soils. FEMS Microbiology Ecology 74, 566–574 CrossRef Pubmed Google scholar

[11]	Gubry-Rangin, C., Hai, B., Quince, C., Engel, M., Thomson, B.C., James, P., Schloter, M., Griffiths, R.I., Prosser, J.I., Nicol, G.W., 2011. Niche specialization of terrestrial archaeal ammonia oxidizers. Proceedings of the National Academy of Sciences 108, 21206.

[12]	Gubry-Rangin, C., Novotnik, B., Mandič-Mulec, I., Nicol, G.W., Prosser, J.I., 2017. Temperature responses of soil ammonia-oxidising archaea depend on pH. Soil Biology and Biochemistry 106, 61–68

[13]	Hallam, S.J., Mincer, T.J., Schleper, C., Preston, C.M., Roberts, K., Richardson, P.M., DeLong, E.F., 2006. Pathways of Carbon Assimilation and Oxidation Suggested by Environmental Genomic Analyses of Marine Crenarchaeota. Plos Biology 4, e95.

[14]	Hatzenpichler, R., 2012. Diversity, physiology, and niche differentiation of ammonia-oxidizing archaea. Applied and Environmental Microbiology 78, 7501–7510 CrossRef Pubmed Google scholar

[15]	Hayatsu, M., Tago, K., Uchiyama, I., Toyoda, A., Wang, Y., Shimomura, Y., Okubo, T., Kurisu, F., Hirono, Y., Nonaka, K., Akiyama, H., Itoh, T., Takami, H., 2017. An acid-tolerant ammonia-oxidizing g-proteobacterium from soil. ISME Journal 11, 1130–1141 CrossRef Pubmed Google scholar

[16]	Hu, H.W., Zhang, L.M., Dai, Y., Di, H.J., He, J.Z., 2013. pH-dependent distribution of soil ammonia oxidizers across a large geographical scale as revealed by high-throughput pyrosequencing. Journal of Soils and Sediments 13, 1439–1449 CrossRef Google scholar

[17]	Huang, R., Wu, Y., Zhang, J., Zhong, W., Jia, Z., Cai, Z., 2011. Nitrification activity and putative ammonia-oxidizing archaea in acidic red soils. Journal of Soils and Sediments 12, 420–428 CrossRef Google scholar

[18]	Jia, Z., Conrad, R., 2009. Bacteria rather than Archaea dominate microbial ammonia oxidation in an agricultural soil. Environmental Microbiology 11, 1658–1671 CrossRef Pubmed Google scholar

[19]	Kelly, J.J., Policht, K., Grancharova, T., Hundal, L.S., 2011. Distinct responses in ammonia-oxidizing archaea and bacteria after addition of biosolids to an agricultural soil. Applied and Environmental Microbiology 77, 6551–6558 CrossRef Pubmed Google scholar

[20]	Keluskar, R., Nerurkar, A., Desai, A., 2013. Mutualism between autotrophic ammonia-oxidizing bacteria (AOB) and heterotrophs present in an ammonia-oxidizing colony. Archives of Microbiology 195, 737–747.

[21]

Kerou, M., Offre, P., Valledor, L., Abby, S.S., Melcher, M., Nagler, M., Weckwerth, W., Schleper, C., 2016. Proteomics and comparative genomics of Nitrososphaera viennensis reveal the core genome and adaptations of archaeal ammonia oxidizers. Proceedings of the National Academy of Sciences of the United States of America 113, E7937–E7946

CrossRef Pubmed Google scholar

[22]

Kim, J.G., Park, S.J., Sinninghe Damsté, J.S., Schouten, S., Rijpstra, W.I.C., Jung, M.Y., Kim, S.J., Gwak, J.H., Hong, H., Si, O.J., Lee, S., Madsen, E.L., Rhee, S.K., 2016. Hydrogen peroxide detoxification is a key mechanism for growth of ammonia-oxidizing archaea. Proceedings of the National Academy of Sciences of the United States of America 113, 7888–7893

CrossRef Pubmed Google scholar

[23]	Könneke, M., Bernhard, A.E., de la Torre, J.R., Walker, C.B., Waterbury, J.B., Stahl, D.A., 2005. Isolation of an autotrophic ammonia-oxidizing marine archaeon. Nature 437, 543–546 CrossRef Pubmed Google scholar

[24]	Kumar, S., Stecher, G., Tamura, K., 2016. MEGA7: Molecular Evolutionary Genetics Analysis Version 7.0 for Bigger Datasets. Molecular Biology and Evolution 33, 1870–1874 CrossRef Pubmed Google scholar

[25]	Leininger, S., Urich, T., Schloter, M., Schwark, L., Qi, J., Nicol, G.W., Prosser, J.I., Schuster, S.C., Schleper, C., 2006. Archaea predominate among ammonia-oxidizing prokaryotes in soils. Nature 442, 806–809 CrossRef Pubmed Google scholar

[26]

Liu, H., Li, J., Zhao, Y., Xie, K., Tang, X., Wang, S., Li, Z., Liao, Y., Xu, J., Di, H., Li, Y., 2018. Ammonia oxidizers and nitrite-oxidizing bacteria respond differently to long-term manure application in four paddy soils of south of China. Science of the Total Environment 633, 641–648

CrossRef Pubmed Google scholar

[27]	Martens-Habbena, W., Berube, P.M., Urakawa, H., de la Torre, J.R., Stahl, D.A., 2009. Ammonia oxidation kinetics determine niche separation of nitrifying Archaea and Bacteria. Nature 461, 976–979 CrossRef Pubmed Google scholar

[28]	Meng, H., Katayama, Y., Gu, J.D., 2017. More wide occurrence and dominance of ammonia-oxidizing archaea than bacteria at three Angkor sandstone temples of Bayon, Phnom Krom and Wat Athvea in Cambodia. International Biodeterioration & Biodegradation 117, 78–88 CrossRef Google scholar

[29]	Milligan, G.W., 1985. Cluster-Analysis for Researchers- Romesburg,Hc. Journal of Classification 2, 133–137 CrossRef Google scholar

[30]	Nicol, G.W., Leininger, S., Schleper, C., Prosser, J.I., 2008. The influence of soil pH on the diversity, abundance and transcriptional activity of ammonia oxidizing archaea and bacteria. Environmental Microbiology 10, 2966–2978 CrossRef Pubmed Google scholar

[31]	Norman, J.S., Barrett, J.E., 2014. Substrate and nutrient limitation of ammonia-oxidizing bacteria and archaea in temperate forest soil. Soil Biology & Biochemistry 69, 141–146 CrossRef Google scholar

[32]	Nunes-Alves, C., 2016. Microbial ecology: Do it yourself nitrification. Nature Reviews Microbiology 14, 61–61 CrossRef Pubmed Google scholar

[33]	Ouyang, Y., Norton, J.M., Stark, J.M., Reeve, J.R., Habteselassie, M.Y., 2016. Ammonia-oxidizing bacteria are more responsive than archaea to nitrogen source in an agricultural soil. Soil Biology & Biochemistry 96, 4–15 CrossRef Google scholar

[34]	Pan, H., Xie, K.X., Zhang, Q.C., Jia, Z.J., Xu, J.M., Di, H.J., Li, Y., 2018. Archaea and bacteria respectively dominate nitrification in lightly and heavily grazed soil in a grassland system. Biology and Fertility of Soils 54, 41–54 CrossRef Google scholar

[35]

Pester, M., Rattei, T., Flechl, S., Gröngröft, A., Richter, A., Overmann, J., Reinhold-Hurek, B., Loy, A., Wagner, M., 2012. amoA-based consensus phylogeny of ammonia-oxidizing archaea and deep sequencing of amoA genes from soils of four different geographic regions. Environmental Microbiology 14, 525–539

CrossRef Pubmed Google scholar

[36]	Prosser, J.I., Nicol, G.W., 2008. Relative contributions of archaea and bacteria to aerobic ammonia oxidation in the environment. Environmental Microbiology 10, 2931–2941 CrossRef Pubmed Google scholar

[37]	Prosser, J.I., Nicol, G.W., 2012. Archaeal and bacterial ammonia-oxidisers in soil: the quest for niche specialisation and differentiation. Trends in Microbiology 20, 523–531 CrossRef Pubmed Google scholar

[38]	Racz, L., Datta, T., Gole, R., 2010. Effect of organic carbon on ammonia oxidizing bacteria in a mixed culture. Bioresource Technology 101, 6454–6460.

[39]

Rice, M.C., Norton, J.M., Valois, F., Bollmann, A., Bottomley, P.J., Klotz, M.G., Laanbroek, H.J., Suwa, Y., Stein, L.Y., Sayavedra-Soto, L., Woyke, T., Shapiro, N., Goodwin, L.A., Huntemann, M., Clum, A., Pillay, M., Kyrpides, N., Varghese, N., Mikhailova, N., Markowitz, V., Palaniappan, K., Ivanova, N., Stamatis, D., Reddy, T.B.K., Ngan, C.Y., Daum, C., 2016. Complete genome of Nitrosospira briensis C-128, an ammonia-oxidizing bacterium from agricultural soil. Standards in Genomic Sciences 11, 46

CrossRef Pubmed Google scholar

[40]	Rudisill, M.A., Turco, R.F., Hoagland, L.A., 2016. Fertility practices and rhizosphere effects alter ammonia oxidizer community structure and potential nitrification activity in pepper production soils. Applied Soil Ecology 99, 70–77 CrossRef Google scholar

[41]	Schleper, C., 2010. Ammonia oxidation: different niches for bacteria and archaea? ISME Journal 4, 1092–1094 CrossRef Pubmed Google scholar

[42]

Schloss, P.D., Westcott, S.L., Ryabin, T., Hall, J.R., Hartmann, M., Hollister, E.B., Lesniewski, R.A., Oakley, B.B., Parks, D.H., Robinson, C.J., Sahl, J.W., Stres, B., Thallinger, G.G., Van Horn, D.J., Weber, C.F., 2009. Introducing mothur: open-source, platform-independent, community-supported software for describing and comparing microbial communities. Applied and Environmental Microbiology 75, 7537–7541

CrossRef Pubmed Google scholar

[43]	Segal, L.M., Miller, D.N., McGhee, R.P., Loecke, T.D., Cook, K.L., Shapiro, C.A., Drijber, R.A., 2017. Bacterial and archaeal ammonia oxidizers respond differently to long-term tillage and fertilizer management at a continuous maize site. Soil & Tillage Research 168, 110–117 CrossRef Google scholar

[44]	Stahl, D.A., de la Torre, J.R., 2012. Physiology and diversity of ammonia-oxidizing archaea. Annual Review of Microbiology 66, 83–101 CrossRef Pubmed Google scholar

[45]	Sun, R., Dsouza, M., Gilbert, J.A., Guo, X., Wang, D., Guo, Z., Ni, Y., Chu, H., 2016a. Fungal community composition in soils subjected to long-term chemical fertilization is most influenced by the type of organic matter. Environmental Microbiology 18, 5137–5150 CrossRef Pubmed Google scholar

[46]	Sun, R., Guo, X., Wang, D., Chu, H., 2015a. Effects of long-term application of chemical and organic fertilizers on the abundance of microbial communities involved in the nitrogen cycle. Applied Soil Ecology 95, 171–178 CrossRef Google scholar

[47]	Sun, R., Zhang, X.X., Guo, X., Wang, D., Chu, H., 2015b. Bacterial diversity in soils subjected to long-term chemical fertilization can be more stably maintained with the addition of livestock manure than wheat straw. Soil Biology & Biochemistry 88, 9–18 CrossRef Google scholar

[48]

Tang, Y., Zhang, X., Li, D., Wang, H., Chen, F., Fu, X., Fang, X., Sun, X., Yu, G., 2016. Impacts of nitrogen and phosphorus additions on the abundance and community structure of ammonia oxidizers and denitrifying bacteria in Chinese fir plantations. Soil Biology & Biochemistry 103, 284–293

CrossRef Google scholar

[49]	Tourna, M., Freitag, T.E., Nicol, G.W., Prosser, J.I., 2008. Growth, activity and temperature responses of ammonia-oxidizing archaea and bacteria in soil microcosms. Environmental Microbiology 10, 1357–1364 CrossRef Pubmed Google scholar

[50]	Verhagen, F.J.M., Laanbroek, H.J., Woldendorp, J.W., 1995. Competition for Ammonium between Plant-Roots and Nitrifying and Heterotrophic Bacteria and the Effects of Protozoan Grazing. Plant and Soil 170, 241–250.

[51]	Verhamme, D.T., Prosser, J.I., Nicol, G.W., 2011. Ammonia concentration determines differential growth of ammonia-oxidising archaea and bacteria in soil microcosms. ISME Journal 5, 1067–1071 CrossRef Pubmed Google scholar

[52]	Wang, X., Wang, C., Bao, L., Xie, S., 2015. Impact of carbon source amendment on ammonia-oxidizing microorganisms in reservoir riparian soil. Annals of Microbiology 65, 1411–1418 CrossRef Google scholar

[53]	Wang, Y., Zhu, G., Song, L., Wang, S., Yin, C., 2014. Manure fertilization alters the population of ammonia-oxidizing bacteria rather than ammonia-oxidizing archaea in a paddy soil. Journal of Basic Microbiology 54, 190–197 CrossRef Pubmed Google scholar

[54]	Wessén, E., Nyberg, K., Jansson, J.K., Hallin, S., 2010. Responses of bacterial and archaeal ammonia oxidizers to soil organic and fertilizer amendments under long-term management. Applied Soil Ecology 45, 193–200 CrossRef Google scholar

[55]	Xiang, X., He, D., He, J.S., Myrold, D.D., Chu, H., 2017. Ammonia-oxidizing bacteria rather than archaea respond to short-term urea amendment in an alpine grassland. Soil Biology & Biochemistry 107, 218–225 CrossRef Google scholar

[56]

Xu, X., Liu, X., Li, Y., Ran, Y., Liu, Y., Zhang, Q., Li, Z., He, Y., Xu, J., Di, H., 2017. High temperatures inhibited the growth of soil bacteria and archaea but not that of fungi and altered nitrous oxide production mechanisms from different nitrogen sources in an acidic soil. Soil Biology & Biochemistry 107, 168–179

CrossRef Google scholar

[57]	Yao, H., Gao, Y., Nicol, G.W., Campbell, C.D., Prosser, J.I., Zhang, L., Han, W., Singh, B.K., 2011. Links between ammonia oxidizer community structure, abundance, and nitrification potential in acidic soils. Applied and Environmental Microbiology 77, 4618–4625 CrossRef Pubmed Google scholar

[58]	Ying, J., Li, X., Wang, N., Lan, Z., He, J., Bai, Y., 2017. Contrasting effects of nitrogen forms and soil pH on ammonia oxidizing microorganisms and their responses to long-term nitrogen fertilization in a typical steppe ecosystem. Soil Biology & Biochemistry 107, 10–18 CrossRef Google scholar

[59]	Zhalnina, K., de Quadros, P.D., Camargo, F.A., Triplett, E.W., 2012. Drivers of archaeal ammonia-oxidizing communities in soil. Frontiers in Microbiology 3, 210 CrossRef Pubmed Google scholar

[60]	Zhang, L.M., Hu, H.W., Shen, J.P., He, J.Z., 2012. Ammonia-oxidizing archaea have more important role than ammonia-oxidizing bacteria in ammonia oxidation of strongly acidic soils. ISME Journal 6, 1032–1045 CrossRef Pubmed Google scholar

[61]	Zhang, L.M., Offre, P.R., He, J.Z., Verhamme, D.T., Nicol, G.W., Prosser, J.I., 2010. Autotrophic ammonia oxidation by soil thaumarchaea. Proceedings of the National Academy of Sciences of the United States of America 107, 17240–17245 CrossRef Pubmed Google scholar

[62]	Zheng, Y., Hou, L., Newell, S., Liu, M., Zhou, J., Zhao, H., You, L., Cheng, X., 2014. Community dynamics and activity of ammonia-oxidizing prokaryotes in intertidal sediments of the Yangtze estuary. Applied and Environmental Microbiology 80, 408–419 CrossRef Pubmed Google scholar

Acknowledgments

We thank Yuntao Li, Congcong Shen, Huaibo Sun, Yu Shi, Xingjia Xiang, and Dawei Ma for assistance in soil sampling, Zhibin Guo and Keke Hua for managemant of the filed. The ﬁrst author, Ruibo Sun, appreciates his soul mate Jessy for shining his life. This study was funded by the Strategic Priority Research Program of the Chinese Academy of Sciences (XDB15010101), the Notional Natural Science Foundation of China (31870480), and the National Key Research and Development Program of China (2017YFD0800604).

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