Advanced SearchSearch Tips
Effect of Temperature Condition on Nitrogen Mineralization of Organic Matter and Soil Microbial Community Structure in non-Volcanic Ash Soil
facebook(new window)  Pirnt(new window) E-mail(new window) Excel Download
 Title & Authors
Effect of Temperature Condition on Nitrogen Mineralization of Organic Matter and Soil Microbial Community Structure in non-Volcanic Ash Soil
Joa, Jae-Ho; Moon, Kyung-Hwan; Kim, Seong-Cheol; Moon, Doo-Gyung; Koh, Sang-Wook;
  PDF(new window)
This study was carried out to evaluate effect of temperature condition on nitrogen mineralization of organic matter, distribution of microbial group by PLFA profiles, and soil microbial community in non-volcanic ash soil. Dried soil 30 g mixed well each 2 g of pellet (OFPE) organic fertilizers, pig manure compost (PMC), and food waste compost (FWC). And then had incubated at , , and , respectively. Nitrogen mineralization rate increased with increasing temperature and that was in the order of FWC>OFPE>PMC. Distribution ratio of microbial group by PLFA profiles showed that was different significantly according to incubation temperature and the type of organic matter. As incubating time passed, density of microbial group decreased gradually. The Gram-bacteria PLFA/Gram+ bacteria PLFA, Fungi PLFA/Bacteria PLFA, and Unsaturated PLFA/saturated PLFA ratios were decreased according to the increasing temperature gradually. Principal component analysis using PLFA profiles showed that microbial community structures were composed differently by temperature factor at both 75 days () and 270 days (). In conclusion, Soil microbial community structure showed relative sensitivity and seasonal changes as affected by temperature and organic matter type.
Temperature;Nitrogen mineralization;PLFA;Microbial Community;
 Cited by
온도가 화산회토양의 질소무기화와 미생물군집이동에 미치는 영향,좌재호;문두경;고상욱;현해남;

한국토양비료학회지, 2012. vol.45. 4, pp.467-474 crossref(new window)
유기질비료와 화학비료의 사용기간과 사용량에 따른 논토양 화학성 변화와 벼의 수량구성요소에 미치는 영향,오태석;김창호;김성민;장명준;박윤진;조용구;

한국유기농업학회지, 2016. vol.24. 4, pp.969-980 crossref(new window)
양파 파치 추출물이 유기농 양파성에 미치는 영향,이춘희;이상대;이성호;민영봉;김혜란;이영한;

한국토양비료학회지, 2013. vol.46. 1, pp.40-48 crossref(new window)
밭토양 조건에서 유박과 아미노산 비료의 질소 무기화량 추정,임종욱;김송엽;윤영은;김장환;이상범;이용복;

한국유기농업학회지, 2015. vol.23. 4, pp.867-873 crossref(new window)
Effect of Temperature Condition on Nitrogen Mineralization and Soil Microbial Community Shift in Volcanic Ash Soil, Korean Journal of Soil Science and Fertilizer, 2012, 45, 4, 467  crossref(new windwow)
Effect of Defective Onion Extract on the Onion Productivity by Organic Farming, Korean Journal of Soil Science and Fertilizer, 2013, 46, 1, 40  crossref(new windwow)
Agehara, S. and D.D. Warncke. 2004. Soil moisture and temperature effects on nitrogen release from organic nitrogen sources. Am. J. Soil Sci. Soc.69:1844-1855.

Bapiri, A., E. Baath, and J. Rousk. 2010. Drying-rewetting cycles affect fungal and bacterial growth differently in an arable soil. Microb. Ecol. 60:419-428. crossref(new window)

Bardgett, R.D., P.J. Hobbs, and A. Frostegard. 1996. Changes in soil fungal:bacterial biomass ratios following reductions in the intensity of management of an upland grassland. Biol. Fertil. Soils 22:261-264. crossref(new window)

Bligh, E.G. and W.J. Dyer. 1959. A rapid method for total lipid extraction and purification. Can. J. Biochem. Physiol. 37:911-917. crossref(new window)

Bossio, D.A., K.M. Scow, N. Gunapala, and K.J. Graham. 1998. Determinants of soil microbial communities: effects of agricultural management, season, and soil type on phospholipid fatty acid profiles. Microb. Ecol. 36:1-12. crossref(new window)

Bossio D.A. and K.M. Scow. 1998. Impacts of carbon and flooding on soil microbial communities: phopholipid fatty acid profiles and substrate utilization patterns. Microb. Ecol. 35:265-278. crossref(new window)

Cobo, J.G., E. Barrios, D.C.L. Kass, and R. Thomas. 2002. Nitrogen mineralization and crop uptake from surfaceapplied leaver of green manure species on a tropical volcanic-ash soil. Biol. Fertil. Soil. 36:87-92. crossref(new window)

Deenik, J. 2006. Nitrogen mineralization potential in important agricultural soils of Hawai'i. Soil Crop Manage. 15:1-5.

Feng, X. and M.J. Simpson. 2009. Temperature and substrate controls on microbial phospholipid fatty acid composition during incubation of grassland soils contrasting in organic matter quality. Soil Biol. Biochem. 41: 804-812. crossref(new window)

Joa, J.H., D.G. Moon, S.J. Chun, C.H. Kim, K.S. Choi, H.N. Hyun, and U.G. Kang.. 2009. Effect of temperature on soil microbial biomass, enzyme activities, and PLFA content during incubation period of soil treated with organic materials. Korean J. Soil Sci. Fert. 42:500-512.

Kaur, A., A. Chaudhary, R. Choudhary, and R. Kaushik. 2005. Phospholipid fatty acid-A bioindicator of environment monitoring and assessment in soil ecosystem. Current Science. 89:1103-1112.

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

Marschner, P., E. Kandeler, and B. Marschner. 2003. Structure and function of the soil microbial community in a long- term fertilizer experiment. Soil Biol. Biochem. 35:453-461. crossref(new window)

Manzoni, S. and A. Porpotato. 2007. A theoretical analysis of nonlinearities and feedbacks in soil carbon and nitrogen cycles. Soil Biol. Biochem. 39:1542-1556. crossref(new window)

Nobili, D.M., M. Contin, and P.C. Brookes. 2006. Microbial biomass dynamics in recently air-dried and rewetted soils compared to others stored air-dry for up to 103 years. Soil Biol. Biochem. 38:2871-2881. crossref(new window)

Rahman, M.H. and S. Sugiyama. 2008. Dynamics of microbial community in Japanese andisol of apple orchard production systems. Comm. Soil Sci. Plant Anal. 39:1630-1657. crossref(new window)

NIAST. 2000. Methods of soil and plant analysis. National Institute of Agricultural Science and Technology, RDA, Suwon, Korea.

Sharifi, M., B.J. Zebarth, D.L. Burton, C.A. Grant, S. Bittman, C.F. Drury, B.G. McConkey, and N. Ziadi. 2008. Response of potentially mineralizable soil nitrogen and indices of nitrogen availability to tillage system. Soil Sci. Soc. Am. J. 72:1124-1131. crossref(new window)

Wang, W., C.J. Smith, P.M. Chalk, and D. Chen. 2001. Evaluation chemical and physical indices of nitrogen mineralization capacity with an unequivocal reference. Soil Sci. Soc. Am. J. 65:368-376. crossref(new window)

Webster, G., L.C. Watt, J. Rinna, J.C. Fry, R.P. Evershed, R.J. Parkes, and A.J. Weightman. 2006. A comparison of stable-isotope probing of DNA and phospholipid fatty acids to study prokaryotic functional diversity in sulfate- reducing marine sediment enrichment slurries. Environ. Microb. 8:1575-1589. crossref(new window)

Wennman, P. and T. Kåtterer. 2006. Effects of moisture and temperature on carbon and nitrogen mineralization in mine tailings mixed with sewage sludge. J. Environ. Qual. 35:1135-1141. crossref(new window)

Wu, Y., X. Yu, H. Wang, N. Ding, and J. Xu. 2010. Does history matter? Temperature effects on soil microbial biomass and community structure based on the phospholipid fatty acid (PLFA) analysis. J. Soils Sediments. 10:223-230. crossref(new window)

Yao, H., Z. He, M.J. Wilson, and C.D. Campbell. 2000. Microbial biomass and community structure in a sequence of soils with increasing fertility and changing land use. Microb. Eco. 40:223-237.