Responses of Soil Chemical Properties and Microbiota to Elevated Temperature under Flooded Conditions |
Eo, Jinu
(Climate Change & Agroecology Division, Department of Agricultural Environment, National Institute of Agricultural Sciences)
Hong, Seung-Chang (Climate Change & Agroecology Division, Department of Agricultural Environment, National Institute of Agricultural Sciences) Kim, Myung-Hyun (Climate Change & Agroecology Division, Department of Agricultural Environment, National Institute of Agricultural Sciences) Choi, Soon-Kun (Climate Change & Agroecology Division, Department of Agricultural Environment, National Institute of Agricultural Sciences) Kim, Min-Kyeong (Climate Change & Agroecology Division, Department of Agricultural Environment, National Institute of Agricultural Sciences) Jung, Goo-Bok (Climate Change & Agroecology Division, Department of Agricultural Environment, National Institute of Agricultural Sciences) So, Kyu-Ho (Climate Change & Agroecology Division, Department of Agricultural Environment, National Institute of Agricultural Sciences) |
1 | 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. DOI |
2 | 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. DOI |
3 | 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. DOI |
4 | 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. DOI |
5 | 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. DOI |
6 | 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. DOI |
7 | Davidson, E. A., & Janssens, I. A. (2006). Temperature sensitivity of soil carbon decomposition and feedbacks to climate change. Nature, 440(7081), 165-173. DOI |
8 | 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. DOI |
9 | 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. DOI |
10 | 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. DOI |
11 | 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. DOI |
12 | Goodfellow, M., & Williams, S. T. (1983). Ecology of actinomycetes. Annual Reviews in Microbiology, 37(1), 189-216. DOI |
13 | 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. |
14 | 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. DOI |
15 | 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. DOI |
16 | 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. DOI |
17 | 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. DOI |
18 | 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. DOI |
19 | 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. DOI |
20 | 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. DOI |
21 | 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. DOI |
22 | 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. DOI |
23 | 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. DOI |
24 | 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. DOI |
25 | 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. DOI |
26 | 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. DOI |
27 | 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. DOI |
28 | 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. DOI |
29 | 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. DOI |
30 | 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. DOI |
31 | 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. DOI |
32 | 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. DOI |
33 | 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. DOI |
34 | 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. DOI |
35 | 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. DOI |
36 | 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. DOI |