[KSCI] Korea Science Citation Index Service

http://dx.doi.org/10.5141/JEFB.2011.042

Effects of simulated acid rain on microbial activities and litter decomposition

Lim, Sung-Min (Department of Life Science, Chung-Ang University)
Cha, Sang-Seob (Department of Life Science, Chung-Ang University)
Shim, Jae-Kuk (Department of Life Science, Chung-Ang University)

Publication Information

Journal of Ecology and Environment / v.34, no.4, 2011 , pp. 401-410 More about this Journal

Abstract

We assayed the effects of simulated acid rain on the mass loss, $CO_2$ evolution, dehydrogenase activity, and microbial biomass-C of decomposing Sorbus alnifolia leaf litter at the microcosm. The dilute sulfuric acid solution composed the simulated acid rain, and the microcosm decomposition experiment was performed at 23 $^{\circ}C$ and 40% humidity. During the early decomposition stage, decomposition rate of S. alnifolia leaf litter, and microbial biomass, $CO_2$ evolution and dehydrogenase activity were inhibited at a lower pH; however, during the late decomposition stage, these characteristics were not affected by pH level. The fungal component of the microbial community was conspicuous at lower pH levels and at the late decomposition stage. Conversely, the bacterial community was most evident during the initial decomposition phase and was especially dominant at higher pH levels. These changes in microbial community structure resulting from changes in microcosm acidity suggest that pH is an important aspect in the maintenance of the decomposition process. Litter decomposition exhibited a positive, linear relationship with both microbial respiration and microbial biomass. Fungal biomass exhibited a significant, positive relationship with $CO_2$ evolution from the decaying litter. Acid rain had a significant effect on microbial biomass and microbial community structure according to acid tolerance of each microbial species. Fungal biomass and decomposition activities were not only more important at a low pH than at a high pH but also fungal activity, such as $CO_2$ evolution, was closely related with litter decomposition rate.

Keywords

dehydrogenase; litter decomposition; microbial biomass; microcosm; simulated acid rain;

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Times Cited By KSCI : 1 (Citation Analysis)

Reference
Cited By KSCI

1	Helrich K. 1990. Official Methods of Analysis of the Association of Official Analytical Chemists. Association of Official Analytical Chemists, Washington DC.
2	Hermle S, Vollenweider P, Gunthardt-Goerg MS, McQuattie CJ, Matyssek R. 2007. Leaf responsiveness of Populus tremula and Salix viminalis to soil contaminated with heavy metals and acidic rainwater. Tree Physiol 27: 1517-1531. DOI ScienceOn
3	Hovland J. 1981. The effect of artificial acid rain on respiration and cellulase activity in Norway spruce needle litter. Soil Biol Biochem 13: 23-26. DOI
4	Hovland J, Abrahanmsen G, Ogner G. 1980. Effects of artificial acid rain on decomposition of spruce needles and on mobilisation and leaching of elements. Plant Soil 56: 365-378. DOI
5	Huang DY, Xu YG, Zhou B, Zhang HH, Lan JB. 2010. Wet deposition of nitrogen and sulfur in Guangzhou, a subtropical area in South China. Environ Monit Assess 171: 429-439. DOI
6	Jezierska-Tys S. 2004. Respiration activity and dehydrogenase activity and number of proteolytic micro-organisms in soil contaminated with sulphur and amended with sewage sludge. Acta Agrophysica 106: 501-508.
7	Baath E, Anderson TH. 2003. Comparison of soil fungal/bacterial ratios in a pH gradient using physiological and PLFA-based techniques. Soil Biol Biochem 35: 955-963. DOI
8	Baath E, Arnebrant K. 1994. Growth rate and response of bacterial communities to pH in limed and ash-treated forest soils. Soil Biol Biochem 26: 995-1001. DOI ScienceOn
9	Baath E, Lundgren B, Soderstrom B. 1979. Effects of artificial acid rain on microbial activity and biomass. Bull Environ Contam Toxicol 23: 737-740. DOI
10	Batty LC, Younger PL. 2007. The effect of pH on plant litter decomposition and metal cycling in wetland mesocosms supplied with mine drainage. Chemosphere 66: 158-164. DOI ScienceOn
11	Beare MH, Neely CL, Coleman DC, Hargrove WL. 1990. A substrate-induced respiration (SIR) method for measurement of fungal and bacterial biomass on plant residues. Soil Biol Biochem 22: 585-594. DOI
12	Berg B, McClaugherty C. 2008. Plant Litter: Decomposition, Humus Formation, Carbon. Springer-Verlag, Berlin.
13	Bewley RJF, Parkinson D. 1985. Bacterial and fungal activity in sulphur dioxide polluted soils. Can J Microbiol 31: 13-15. DOI
14	Burns RG. 1978. Enzyme activity in soil: some theoretical and practical considerations. In: Soil Enzymes (Burns RG, ed). Academic Press, London, pp 295-340.
15	Esher RJ, Marx DH, Ursic SJ, Baker RL, Brown LR, Coleman DC. 1992. Simulated acid rain effects in fine roots, ectomycorrhizae, microorganisms, and invertebrates in pine forests of the southern United States. Water Air Soil Pollut 61: 269-278. DOI
16	Evans LS, Gmur NF, Mancini D. 1982. Effects of simulated acidic rain on yields of Raphanus sativus, Lactuca sativa, Triticum aestivum and Medicago sativa. Environ Exp Bot 22: 445-453. DOI
17	Arao T. 1999. In situ detection of changes in soil bacterial and fungal activities by measuring $^{13}C$ incorporation into soil phospholipid fatty acids from $^{13}C$ acetate. Soil Biol Biochem 31: 1015-1020. DOI ScienceOn
18	Abrahamsen G, Hovland J, Hagvar S. 1980. Effects of artificial acid rain and liming on soil organisms and the decomposition of organic matters. In: Effects of Acid Precipitation on Terrestrial Ecosystems (Hutchinson TC, Havas M, eds). Plenum Press, New York, pp 341-362.
19	Anderson JPE, Domsch KH. 1973. Quantification of bacterial and fungal contributions to soil respiration. Arch Microbiol 93: 113-127. DOI
20	Anderson JPE, Domsch KH. 1978. A physiological method for the quantitative measurement of microbial biomass in soils. Soil Biol Biochem 10: 215-221. DOI
21	Zimmer M. 2002. Is decomposition of woodland leaf litter influenced by its species richness? Soil Biol Biochem 34: 277-284. DOI
22	Wood M, Cooper JE, Holding AJ. 1984. Aluminum toxicity and nodulation of Trifolium repens. Plant Soil 78: 381-391. DOI
23	Wood T, Bormann FH. 1974. The effects of an artificial acid mist upon the growth of Betula alleghaniensis Britt. Environ Pollut 7: 259-268. DOI
24	Zhang JE, Ouyang Y, Ling DJ. 2007. Impacts of simulated acid rain on cation leaching from the latosol in south China. Chemosphere 67: 2131-2137. DOI ScienceOn
25	Sakamoto K, Isobe Y, Dong X, Gao S. 2001. Simulated acid rain leaching characteristics of acid soil amended with bio-briquette combustion ash. Water Air Soil Pollut 130: 1451-1456. DOI
26	Reich PB, Schoettle AW, Stroo HF, Troiano J, Amundson RG. 1987. Effects of ozone and acid rain on white pine (Pinus strobus) seedlings grown in five soils. I. Net photosynthesis and growth. Can J Bot 65: 977-987. DOI
27	Rousk J, Brookes PC, Baath E. 2009. Contrasting soil pH effects on fungal and bacterial growth suggest functional redundancy in carbon mineralization. Appl Environ Microbiol 75: 1589-1596. DOI ScienceOn
28	Rowland AP, Roberts JD. 1994. Lignin and cellulose fractionation in decomposition studies using acid-detergent fibre methods. Commun Soil Sci Plant Anal 25: 269-277. DOI
29	von Mersi W, Schinner F. 1991. An improved and accurate method for determining the dehydrogenase activity of soils with iodonitrotetrazolium chloride. Biol Fertil Soils 11: 216-220. DOI
30	Sariyildiz T, Anderson JM. 2003. Interactions between litter quality, decomposition and soil fertility: a laboratory study. Soil Biol Biochem 35: 391-399. DOI
31	Wang C, Guo P, Han G, Feng X, Zhang P, Tian X. 2010. Effect of simulated acid rain on the litter decomposition of Quercus acutissima and Pinus massoniana in forest soil microcosms and the relationship with soil enzyme activities. Sci Total Environ 408: 2706-2713. DOI
32	Wolters V. 1991a. Effects of acid rain on leaf-litter decomposition in a beech forest on calcareous soil. Biol Fertil Soils 11: 151-156. DOI
33	Wolters V. 1991b. Biological processes in two beech forest soils treated with simulated acid rain: a laboratory experiment with Isotoma tigrina (Insecta, Collembola). Soil Biol Biochem 23: 381-390. DOI ScienceOn
34	Monteith DT, Evans CD. 2005. The United Kingdom acid waters monitoring network: a review of the first 15 years and introduction to the special issue. Environ Pollut 137: 3-13. DOI
35	Myrold DD, Nason GE. 1992. Effect of acid rain on soil microbial processes. In: Environmental Microbiology (Mitchell R, ed). Wiley-Liss Inc., New York, pp 59-82.
36	Neufold HS, Jernstedt JA, Haines BL. 1985. Direct foliar effects of simulated acid rain, I. Damage, growth, and gas exchange. New Phytol 99: 389-405. DOI ScienceOn
37	Ouyang XJ, Zhou GY, Huang ZL, Liu JX, Zhang DQ, Li J. 2008. Effect of simulated acid rain on potential carbon and nitrogen mineralization in forest soils. Pedosphere 18: 503-514. DOI ScienceOn
38	Prescott CE, Parkinson D. 1985. Effects of sulphur pollution on rates of litter decomposition in a pine forest. Can J Bot 63: 1436-1443. DOI
39	Pennanen T, Fritze H, Vanhala P, Kiikkila O, Neuvonen S, Baath E. 1998. Structure of a microbial community in soil after prolonged addition of low levels of simulated acid rain. Appl Environ Microbiol 64: 2173-2180.
40	Pennanen T, Liski J, Baath E, Kitunen V, Uotila J, Westman CJ, Fritze H. 1999. Structure of the microbial communities in coniferous forest soils in relation to site fertility and stand development stage. Microbiol Ecol 38: 168-179. DOI
41	Proctor JTA. 1983. Effect of simulated acid sulfuric rain on apple tree foliage, nutrient content, yield, and fruit quality. Environ Exp Bot 23: 167-174. DOI ScienceOn
42	Rechcigl JE, Sparks DL. 1985. Effect of acid rain on the soil environment: a review. Commun Soil Sci Plant Anal 16: 653-680. DOI ScienceOn
43	Reddy MV. 1995. Soil organisms and litter decomposition in the tropics. Oxford & IBH, New Delhi.
44	Killham K, Firestone MK, McCall JG. 1983 Acid rain and soil microbial activity: effects and their mechanisms. J Envithoughron Qual 12: 133-137.
45	Kim YO, Rodriguez RJ, Lee EJ, Redman RS. 2008. Phytolacca Americana from contaminated and noncontaminated soils of south Korea: effects of elevated temperature, $CO_2$ and simulated acid rain on plant growth response. J Chem Ecol 34: 1501-1509. DOI
46	Lee CS, You YH, Kim JH. 1998. Selection of tolerant species among Korean major woody plants to restore Yeocheon Industrial Complex Area. Korea J Ecol 21: 337-344. 과학기술학회마을
47	Lee HY. 1998. The spatial distribution of acid rain in Korea. J Korean Geogr Soc 33: 455-468.
48	Liu J, Zhou G, Zhang D. 2007. Simulated effects of acidic solutions on element dynamics in monsoon evergreen broad-leaved forest at Dinghushan, China. Part 1: dynamics of K, Na, Ca, Mg and P. Environ Sci Pollut Res Int 14: 123-129. DOI
49	Likens GE. 1972. The Chemistry of Precipitation in the Central Finger Lakes Region. Cornell University Water Resources and Marine Science Center, Ithaca, NY.
50	Likens GE, Bormann FH. 1995. Biogeochemistry of a Forested Ecosystem. Springer-Verlag, New York.
51	Matzner E, Murach D, Fortmann H. 1986. Soil acidity and its relationship to root growth in declining forest stands in Germany. Water Air Soil Pollut 31: 278-282.
52	Mayer R, Ulrich B. 1974. Conclusions on the filtering action of forests from ecosystem analysis. Oecol Plant 9: 157-168.
53	Ministry of Environment. 2010. Environmental Statistics Yearbook. Ministry of Environment, Gwacheon.
54	Moldan B, Cerny J. 1994. Biogeochemistry of Small Cachments: A Tool for Environmental Research. SCOPE 51. John Wiley & Sons, New York.
55	Fairfax JAW, Lepp NW. 1975. Effect of simulated 'acid rain' on cation loss from leaves. Nature 255: 324-325. DOI
56	Fritze H. 1992. Effects of environmental pollution on forest soil microflora. Silva Fenn 26: 37-48. DOI
57	Fritze H, Kiikkila O, Pasanen J, Pietikainen J. 1992. Reaction of forest soil microflora to environmental stress along a moderate pollution gradient next to an oil refinery. Plant Soil 140: 175-182. DOI
58	Heal OW, Anderson JM, Swift MJ. 1997. Plant litter quality and decomposition: and historical overview. In: Driven by Nature: Plant Litter Quality and Decomposition (Cadisch G, Giller KE, eds). CAB International, Wallingford, pp 3-45.