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Responses of Soil Chemical Properties and Microbiota to Elevated Temperature under Flooded Conditions
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 Title & Authors
Responses of Soil Chemical Properties and Microbiota to Elevated Temperature under Flooded Conditions
Eo, Jinu; Hong, Seung-Chang; Kim, Myung-Hyun; Choi, Soon-Kun; Kim, Min-Kyeong; Jung, Goo-Bok; So, Kyu-Ho;
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BACKGROUND: Our study aims to investigate the impact of temperature on the abundance and structure of soil microbial community in a temperature gradient tunnel.METHODS AND RESULTS: To investigate the interaction between temperature and input of C and N, rice straw and urea were applied to the study plots, respectively. We also studied the impact of plants by comparing plots cultivated with rice and unplanted plots. Soil microbial response was measured using the phospholipid fatty acid (PLFA) analysis. Soil chemical properties, including pH and ammonia and phosphate concentrations were influenced by warming and material addition. Microbial PLFA was partially influenced by material inputs, and actinomycetes PLFA was decreased by warming. In cultivated rice plots, an increase in the carbon to nitrogen ratio illustrated the effect of plant on microbiota caused by carbon addition through the root residues. Results from the principal component analysis of PLFA data showed that warmed and control plots applied with rice straw could be separated by principal component analysis.CONCLUSION: Our results suggest that plant influence both the microbial community structure and abundance, and temperature change has a minimal impact on soil microorganisms in flooded soil.
Plant;PLFA;Rice husk;Urea;
 Cited by
Achtnich, C., Schuhmann, A., Wind, T., & Conrad, R. (1995). Role of interspecies H2 transfer to sulfate and ferric iron-reducing bacteria in acetate consumption in anoxic paddy soil. FEMS Microbiology Ecology, 16(1), 61-69. crossref(new window)

Aranjuelo, I., Irigoyen, J. J., Pérez, P., Martinez-Carrasco, R., & Sanchez-Dìaz, M. (2005). The use of temperature gradient tunnels for studying the combined effect of CO2, temperature and water availability in N2 fixing alfalfa plants. Annals of Applied Biology, 146(1), 51-60. crossref(new window)

Baker, J. T., Kim, S. H., & Gitz, D. C., Timlin, D., & Reddy, V. R. (2005). Photosynthesis and yield of southern USA rice cultivars in response to CO2 and temperature. Journal of Agricultural Meteorology, 60(5), 457–462.

Berg, G., & Smalla, K. (2009). Plant species and soil type cooperatively shape the structure and function of microbial communities in the rhizosphere. FEMS Microbiology Ecology, 68(1), 1-13. crossref(new window)

Burger, M., & Jackson, L. E. (2003). Microbial immobilization of ammonium and nitrate in relation to ammonification and nitrification rates in organic and conventional cropping systems. Soil Biology and Biochemistry, 35(1), 29-36. crossref(new window)

Davidson, E. A., & Janssens, I. A. (2006). Temperature sensitivity of soil carbon decomposition and feedbacks to climate change. Nature, 440(7081), 165-173. crossref(new window)

Deslippe, J. R., Hartmann, M., Simard, S. W., & Mohn, W. W. (2012). Long-term warming alters the composition of Arctic soil microbial communities. FEMS microbiology ecology, 82(2), 303-315. crossref(new window)

Drigo, B., Pijl, A. S., Duyts, H., Kielak, A. M., Gamper, H. A., Houtekamer, M. J., Boschker, H. T. S., Bodelier, P. L. E., Whiteley, A. S., van Veen, J. A., & Kowalchuk, G. A. (2010). Shifting carbon flow from roots into associated microbial communities in response to elevated atmospheric CO2. Proceedings of the National Academy of Sciences, 107(24), 10938-10942. crossref(new window)

Fissore, C., Giardina, C. P., Kolka, R. K., Trettin, C. C., King, G. M., Jurgensen, M. F., Barton, C. D., & McDowell, S. D. (2008). Temperature and vegetation effects on soil organic carbon quality along a forested mean annual temperature gradient in North America. Global Change Biology, 14(1), 193-205.

Frey, S. D., Drijber, R., Smith, H., & Melillo, J. (2008). Microbial biomass, functional capacity, and community structure after 12 years of soil warming. Soil Biology and Biochemistry, 40(11), 2904-2907. crossref(new window)

Fu, G., Shen, Z., Zhang, X., & Zhou, Y. (2012). Response of soil microbial biomass to short-term experimental warming in alpine meadow on the Tibetan Plateau. Applied Soil Ecology, 61, 158–160. crossref(new window)

Goodfellow, M., & Williams, S. T. (1983). Ecology of actinomycetes. Annual Reviews in Microbiology, 37(1), 189-216. crossref(new window)

Jiménez, C., Tejedor, M., & Rodríguez, M. (2007). Influence of land use changes on the soil temperature regime of Andosols on Tenerife, Canary Islands, Spain. European Journal of Soil Science, 58(2), 445-449. crossref(new window)

Jones, D. L., Nguyen, C., & Finlay, R. D. (2009). Carbon flow in the rhizosphere: carbon trading at the soil–root interface. Plant and Soil, 321(1), 5-33. crossref(new window)

Jungqvist, G., Oni, S. K., Teutschbein, C., & Futter, M. N. (2014). Effect of climate change on soil temperature in Swedish boreal forests. PloS One, 9(4), e93957. crossref(new window)

Kaur, A., Chaudhary, A., Kaur, A., Choudhary, R., & Kaushik, R. (2005). Phospholipid fatty acid – A bioindicator of environment monitoring and assessment in soil ecosystem. Current Science, 89(7), 1103–1112.

Lauber, C. L., Strickland, M. S., Bradford, M. A., & Fierer, N. (2008). The influence of soil properties on the structure of bacterial and fungal communities across land-use types. Soil Biology and Biochemistry, 40(9), 2407-2415. crossref(new window)

Li, W. H., Zhang, C. B., Jiang, H. B., Xin, G. R., & Yang, Z. Y. (2006). Changes in soil microbial community associated with invasion of the exotic weed, Mikania micrantha HBK. Plant and Soil, 281(1), 309-324. crossref(new window)

Marschner, P., Yang, C. H., Lieberei, R., & Crowley, D. E. (2001). Soil and plant specific effects on bacterial community composition in the rhizosphere. Soil Biology and Biochemistry, 33(11), 1437-1445. crossref(new window)

Matsuyama, T., Nakajima, Y., Matsuya, K., Ikenaga, M., Asakawa, S., & Kimura, M. (2007). Bacterial community in plant residues in a Japanese paddy field estimated by RFLP and DGGE analyses. Soil Biology and Biochemistry, 39(2), 463-472. crossref(new window)

Nakamura, A., Tun, C. C., Asakawa, S., & Kimura, M. (2003). Microbial community responsible for the decomposition of rice straw in a paddy field: estimation by phospholipid fatty acid analysis. Biology and Fertility of Soils, 38(5), 288-295. crossref(new window)

Noll, M., Matthies, D., Frenzel, P., Derakshani, M., & Liesack, W. (2005). Succession of bacterial community structure and diversity in a paddy soil oxygen gradient. Environmental Microbiology, 7(3), 382-395. crossref(new window)

Pan, G., Li, L., Wu, L., & Zhang, X. (2003). Storage and sequestration potential of topsoil organic carbon in China's paddy soils. Global Change Biology, 10(1), 79-92. crossref(new window)

Poll, C., Marhan, S., Back, F., Niklaus, P. A., & Kandeler, E. (2013). Field-scale manipulation of soil temperature and precipitation change soil CO2 flux in a temperate agricultural ecosystem. Agriculture, Ecosystems and Environment, 165, 88–97. crossref(new window)

Rui, J., Peng, J., & Lu, Y. (2009). Succession of bacterial populations during plant residue decomposition in rice field soil. Applied and Environmental Microbiology, 75(14), 4879–4886. crossref(new window)

Rustad, L. E., Campbell, J. L, Marion, G. M., Norby, R. J., Mitchell, M. J., Hartley, A. E., Cornelissen, J. H. C., & Gurevitch, J. (2001). A meta-analysis of the response of soil respiration, net nitrogen mineralization, and aboveground plant growth to experimental ecosystem warming. Oecologia, 126(4), 543–562. crossref(new window)

Schindlbacher, A., Wunderlich, S., Borken, W., Kitzler, B., Zechmeister‐Boltenstern, S., & Jandl, R. (2012). Soil respiration under climate change: prolonged summer drought offsets soil warming effects. Global Change Biology, 18(7), 2270-2279. crossref(new window)

Schuerings, J., Jentsch, A., Hammerl, V., Lenz, K., Henry, H. A. L., Malyshev, A. V., & Kreyling, J. (2014). Increased winter soil temperature variability enhances nitrogen cycling and soil biotic activity in temperate heathland and grassland mesocosms. Biogeosciences, 11(23), 7051-7060. crossref(new window)

Shi, F., Chen, H., Chen, H., Wu, Y., & Wu, N. (2012). The combined effects of warming and drying suppress CO2 and N2O emission rates in an alpine meadow of the eastern Tibetan Plateau. Ecological Research, 27(4), 725-733. crossref(new window)

Ström, L., Mastepanov, M., & Christensen, T. R. (2005). Species-specific effects of vascular plants on carbon turnover and methane emissions from wetlands. Biogeochemistry, 75(1), 65-82. crossref(new window)

Wang, W., Lai, D. Y. F., Sardans, J., Wang, C., Datta, A., Pan, T., Zeng, C., Bartrons, M., & Penuelas, J. (2015). Rice Straw incorporation affects global warming potential differently in early vs. late cropping seasons in Southeastern China. Field Crops Research, 181, 42–51. crossref(new window)

Yin, H., Xu, Z., Chen, Z., Wei, Y., & Liu, Q. (2012). Nitrogen transformation in the rhizospheres of two subalpine coniferous species under experimental warming. Applied Soil Ecology, 59, 60–67. crossref(new window)

Zhang, X., Zhang, G., Chen, Q., & Han, X. (2013). Soil bacterial communities respond to climate changes in a temperate steppe. PloS One, 8(11), e78616. crossref(new window)

Zhao, J., Ni, T., Li, Y., Xiong, W., Ran, W., Shen, B., ... & Zhang, R. (2014). Responses of bacterial communities in arable soils in a rice-wheat cropping system to different fertilizer regimes and sampling times. PloS One, 9(1), e85301. crossref(new window)

Zheng, D., Hunt Jr, E. R., & Running, S. W. (1993). A daily soil temperature model based on air temperature and precipitation for continental applications. Climate Research, 2(3), 183-191. crossref(new window)

Zhou, X., Chen, C., Wang, Y., Xu, Z., Duan, J., Hao, Y., & Smaill, S. (2013). Soil extractable carbon and nitrogen, microbial biomass and microbial metabolic activity in response to warming and increased precipitation in a semiarid Inner Mongolian grassland. Geoderma, 206, 24–31. crossref(new window)