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  • KOREAN
  • P-ISSN2287-8327
  • E-ISSN2288-1220
  • SCOPUS, KCI

The effect of simulated acid rain on microbial community structure in decomposing leaf litter

Journal of Ecology and Environment / Journal of Ecology and Environment, (P)2287-8327; (E)2288-1220
2013, v.36 no.4, pp.223-233
https://doi.org/10.5141/ecoenv.2013.223


Bahitkul Amirasheba (Kazakh National Pedagogical University Named After Abay)

Abstract

Acid deposition is one of the most serious environmental problems in ecosystems. The present study surveyed the effects of simulated acid rain on leaf litter mass loss and microbial community in the decomposing leaf litter of Sorbus anifolia in a microcosm at 23°C and 40% humidity. Microbial biomass was measured by substrate-induced respiration (SIR) and phospholipid fatty acids (PLFAs), and the microbial community structures were determined by composition of PLFAs at each interval of decomposition in litter sample and at each pH treatment. The microbial biomass showed peaks at midstage of decomposition, decreasing at the late stage. The leaf litter mass loss of S. anifolia decreased with decreasing pH during early and mid- decomposition stages; however the mass loss becomes similar between pH treatments at late-decomposition stage. The acidification remarkably lowers the microbial biomass of bacteria and fungi; however, microbial diversity was unchanged between pH treatments at each stage of litter decomposition. With changes of decomposition stage and pH treatment there were considerable differences in replacement and compensation of microbial species. Fungi/bacteria ratio was considerably changed by pH treatment. The PLFA profile showed significantly larger fungi/bacteria ratio at pH 5 than pH 3 at the early stage of decomposition, and the difference becomes smaller at the later decomposition stage. At low pH, pH 3 and pH 4, the fungi/bacteria ratios were stable according to the litter decomposition stages. Simulated acid rain caused decreases of 10Me17:0, 16:1ω7c, 18:1ω7, 15:0, but increase of 24:0. In addition, litter mass loss showed significant positive correlation with microbial biomass measured by SIR and PLFA on the decomposing leaf litter.

keywords
acid rain, litter decomposition, microbial biomass, PLFA

Reference

1.

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.

2.

Anderson JPE, Domsch KH. 1973. Quantification of bacterial and fungal contributions to soil respiration. Arch Microbiol 93: 113–127.

3.

Anderson JPE, Domsch KH. 1978. A physiological method for the quantitative measurement of microbial biomass in soil. Soil Biol Biochem 10: 215–221.

4.

Arao T. 1999. In situ detection of changes in soil bacterial and fungal activities by measuring 13C incorporation into soil phospholipid fatty acids from 13C acetate. Soil Biol Biochem 31: 1015–1020.

5.

Bååth E, Anderson TH. 2003. Comparison of soil fungal/ bacterial ratios in a pH gradient using physiological and PLFA-based techniques. Soil Biol Biochem 35: 995–963.

6.

Bååth 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.

7.

Bååth E, Frostegård Å, Fritze H. 1992. Soil bacterial biomass, activity, phospholipid fatty acid pattern, and pH tolerance in an area polluted with alkaline dust deposition. Appl Envir Microb 58: 4026–4031.

8.

Bååth E, Frostegård Å, Pennanen T, Fritze H. 1995. Microbial community structure and pH response in relation to soil organic matter quality in wood ash fertilized, clear-cut or burned forest soils. Soil Biol Biochem 27: 229–240.

9.

Bååth E, Lundgren B, Söderström B. 1979. Effects of artificial acid rain on microbial activity and biomass. Bull. Environ. Contam Toxicol 23: 737-740.

10.

Bailey VL, Peacock AD, Smith JL, Bolton H Jr. 2002. Relationship between soil microbial biomass determined by chloroform fumigation extraction, substrate-induced respiration, and phospholipid fatty acid analysis. Soil Biol Biochem 34: 1385–1389.

11.

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.

12.

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.

13.

Berg B, Laskowski R. 2006. Litter decomposition: a guide to carbon and nutrient turnover, Advances in ecological research 38. Elsevier Academic Press, San Diego.

14.

Bewley RJF, Parkinson D. 1985. Bacterial and fungal activity in sulphur dioxide polluted soils. Can J Microbiol 31: 13- 15.

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.

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.

17.

Federle TW. 1986. Microbial distribution in soil: new techniques. In: Perspectives in Microbial Ecology (Megusar F, Gantar M, eds). Slovene Society for Microbiology, Ljublana, pp 493–498.

18.

Fritze H. 1992. Effects of environmental pollution on forest soil microflora. Silva Fennica 26: 37–48.

19.

Fritze H, Kiikkilä O, Pasanen J, Pietikäinen 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.

20.

Frostegård Å, Bååth E. 1996. The use of phospholipids fatty analysis to estimate bacterial and fungal biomass in soil. Biol Fertil Soils 22: 59–65.

21.

Frostegård Å, Bååth E, Tunlio A. 1993. Shifts in the structure of soil microbial communities in limed forest as revealed by phospholipid fatty acid analysis. Soil Biol Biochem 25: 723–730.

22.

Gross S, Robbins EI. 2000. Acidophilic and acid-tolerant fungi and yeasts. Hydrobiologia 433: 91–109.

23.

Heal OW, Anderson JM, Swift MJ. 1997. Plant litter quality and decomposition: an historical overview. In: Driven by Nature: Plant litter Quality and decomposition(Cadisch G, Giller KE, eds). CAB International, Wallingford, pp 3-30.

24.

Hermle S, Vollenweider P, Günthardt-Goerg MS, McQuattie CJ, Matyssek R. 2007. Leaf responsiveness of Populus tremula and Salix viminalis to soil contaminated with heavy metals and acidic rain water. Tree Physiol 27: 1517-1531.

25.

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.

26.

Högberg MN, Högberg P, Myrold DD. 2007, Is microbial community composition in boreal forest soils determined by pH, C-toN ratio, the trees, or all three? Oecologia 150: 590-601.

27.

Lee JJ, Weber DE. 1979. The effects of simulated acid rain on seedling emergence and growth of eleven woody species. Forest Sci 25: 393-398.

28.

Lim SM, Cha SS, Shim JK. 2011. Effects of simulated acid rain on microbial activities and litter decomposition. J Ecol Field Biol 34: 401-410.

29.

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.

30.

Mancinelli RL. 1986. Alpine tundra soil bacterial responses to increased soil loading rates of acid precipitation, nitrate, and sulfate Front Range, Colorado, USA. Arctic Alpine Res 18: 269-275.

31.

Matzner E, Murach D, Fortann H. 1986. Soil acidity and its relationship to root growth in declining forest stands in Germany. Water Air Soil Pollut 31: 273-282.

32.

Myrold DD, Nalson GE. 1992. Effect of acid rain on soil microbial processes. In: Environmental Microbiology (Mitchell R, ed). Wiley-Liss Inc., New York, pp 59–81.

33.

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.

34.

Nielsen P, Petersen SO. 2000. Ester-linked polar lipid fatty acid profiles of soil microbial communities: a comparison of extraction methods and evaluation of interference from humic acids. Soil Biol Biochem 32: 1241–1249.

35.

Osonbui O, Oren R, Werk K, Schulze ED, Heilmeier H. 1988. Performance of two Picea abies (L.) Karst stands at different stages of decline IV. Xylem sap concentration of magnesium, calcium, potassium, and nitrogen. Oecologia 77: 1-6.

36.

Ouyang XJ, Zhao 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.

37.

Pennanen T, Fritze H, Vanhala P, Kiikkila O, Neuvonen S, Bååth 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.

38.

Pennanen T, Liski J, Bååth 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.

39.

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.

40.

Raynal DJ, Roman JR, Eichelaub WM. 1982. Response of tree seedlings to acid precipitation II. Effect of simulated canopy throughfall on sugar maple seedling growth. Environ Exp Bot 22: 385-392.

41.

Rechcigl JE, Sparks DL. 1985. Effect or acid rain on the soil environment: a review. Commun Soil Sci Plant Anal 16: 653-680.

42.

Reich PB, Scholettle AW, Stroo HF, Troiano J, Amundson RG. 1987. Effects of ozone and acid rain on white pine (Pinus strobes) seedlings grown in five soils. I. Net photosynthesis and growth. Can J Bot 65: 977-987.

43.

Reith F, Drake HL, Kusel K. 2002. Anaerobic activities of bacteria and fungi moderately acidic conifer and deciduous leaf litter. FEMS Microbiol Ecol 41: 27–35.

44.

Rousk J, Bååth E. 2007. Fungal biomass production and turnover in soil estimated using the acetate-in-ergosterol technique. Soil Biol Biochem. 39: 2173–2177.

45.

Rousk J, Brookkes P, Bååth E. 2009 Contrasting soil pH effects on fungal and bacterial growth suggest functional redundancy in carbon mineralization. Appl Environ Microbiol 75: 1589–1596.

46.

Sariyildiz T, Anderson JM. 2003. Interactions between litter quality, decomposition and soil fertility: a laboratory study. Soil Biol Biochem 35: 391–399.

47.

Shannon CE. 1948. A mathematical theory of communication. Bell Syst Tech J 27: 379-423, 623-656.

48.

Simpson EH. 1949. Measurement of diversity. Nature 163: 688.

49.

Stemmer M, Watzinger A, Blochberger K, Haberhauer G., Gerzabek MH. 2007, Linking dynamics of soil microbial phospholipid fatty acids to carbon mineralization in a 13C natural abundance experiment: Impact of heavy metals and acid rain. Soil Biol Biochem 39: 3177–3186.

50.

Wilkinson SC, Anderson JM, Scardelis SP, Tisiafouli M, Taylor A, Wolters V. 2002. PLFA profiles of microbial communities in decomposing conifer litters subject to moisture stress. Soil Biol Biochem 34: 189–200.

51.

Wolters V. 1991a. Effects of acid rain on leaf-litter decomposition in a beech forest on calcareous soil. Biol Fertil Soils 11: 151–156.

52.

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.

53.

Wood M, Cooper JE, Holding AJ. 1984 Aluminum toxicity and nodulation of Trifolium repens. Plant Soil 78: 381–391.

54.

Wood T, Bormann FH. 1974. Effects of an artificial acid mist upon the growth of Bestula alleghaniensis. britt. Environ Pollut 7: 256–298.

55.

You YH, Lee CS, Kim JH. 1998. Selection of Tolerant Species among Korean Major Woody Plants to Restore Yeocheon Industrial Complex Area. Korean J Ecol 21: 337-344.

56.

Zhang JE, Ouyang Y, Ling DJ. 2007. Impacts of simulated rain on cation leaching from the Latosol in South China. Chemosphere 67: 2131–2137.

57.

Zimmer M. 2002. Is decomposition of woodland leaf litter influenced by its species richness?. Soil Biol Biochem 34: 277–284.

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