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Effects of Quicklime Treatment on Survival of Bacteria and Structure of Bacterial Community in Soil
Zo, Young-Gun;
Department of Biology and Institute for Basic Science, Kyungsung University;
생석회 처리가 토양 세균의 생존과 군집구조에 미치는 영향
조영근;
경성대학교 이과대학 생물학과 및 기초과학연구소;

Abstract

When quicklime is added into soil for various purposes, abrupt changes in soil chemistry may affect essential ecological functions played by indigenous bacterial communities in soil. The magnitude of influence was estimated by observing changes in abundance and diversity of soil bacteria after quicklime treatment. When several soil samples were treated up to 20% (w/w) quicklime, plate count of viable cells ranged $10^2{\sim}10^3$ CFU $g^{-1}$, showing a reduction of more than $10^4$ times from viable counts of the untreated sample. Diversity of the bacterial isolates that survived after quicklime treatment was analyzed by conducting $GTG_5$ rep-PCR fingerprinting. There were only two types of fingerprints common to both 5% and 20% quicklime samples, implying that bacteria surviving at different strength of quicklime treatment differed depending on their tolerance to quicklime-treated condition. Isolates surviving the quicklime treatments were further characterized by Gram staining and endospore staining. All isolates were found to be Gram positive bacteria, and 85.4% of them displayed endospores state. In conclusion, most bacteria surviving quicklime treatment appear to be endospores. This finding suggests that most of ecological functions of bacteria in soil are lost with quicklime treatment.

Keywords: Alkalotolerant bacteria;Endospore;Landfill;Soil pH;Quicklime;

References

1. 노정엽, 이의평, 2011, 생석회에 의한 발화 가능성 연구, 한국화재조사학회 2011년도 제21회 춘계학술대회, 한국화재조사학회, 전주, pp. 102-116.
2. 서장선, 정병간, 권장식, 1998, 우리나라 중부지방 시설재배지 토양 미생물의 다양성에 관한 연구, 한국토양비료학회지, 31(2), 197-203.
3. 성치남, 백근식, 전영문, 김정근, 김종훈, 1998, 남산 주요 식생의 토양 미생물의 분포 및 생리적 특성, 한국생태학회지, 21(5-3), 703-712.
4. 신영오, 1992, 토양생태계와 토양자원, 한림저널사.
5. 한국석회석가공업협동조합, 2006, 석회의 성질, 기능 및 용도, 석회, 11(2), 16-35.
6. Andrade, M.J., Rodriguez, M., Sanchez, B., Aranda, E., and Cordoba, J.J., 2006, DNA typing methods for differentiation of yeasts related to dry-cured meat products, Int. J. Food Microbiol., 107(1), 48-58.
7. Beare, M., Coleman, D., Crossley, D., Hendrix, P., and Odum, E., 1995, A hierarchical approach to evaluating the significance of soil biodiversity to biogeochemical cycling, Plant Soil, 170(1), 5-22.
8. Benken, T., Muller, J.K., and Peschke, K., 1998, Oligonucleotide DNA fingerprinting optimized to determine parentage in three beetle species, Electrophoresis, 19(2), 158-163.
9. Chokesajjawatee, N., Zo, Y.-G., and Colwell, R.R., 2008, Determination of clonality and relatedness of Vibrio cholerae isolates by genomic fingerprinting, using long-range repetitive element sequence-based PCR, Appl. Environ. Microbiol., 74, 5392-5401.
10. Chomczynski, P. and Rymaszewski, M., 2006, Alkaline polyethylene glycol-based method for direct PCR from bacteria, eukaryotic tissue samples, and whole blood, BioTechniques 40, 454-458.
11. Coorevits, A., de Jonghe, V., Vandroemme, J., Reekmans, R., Heyrman, J., Messens, W., de Vos, P., and Heyndrickx, M., 2008, Comparative analysis of the diversity of aerobic sporeforming bacteria in raw milk from organic and conventional dairy farms, Syst. Appl. Microbiol., 31(2), 126-140.
12. Dragon, D.C. and Rennie, R.P., 1995, The ecology of anthrax spores: tough but not invincible, Can. Vet. J., 36(5), 295-301.
13. Epplen, J.T., Ammer, H., Epplen, C. & other authors, 1991, Oligonucleotide fingerprinting using simple repeat motifs: a convenient, ubiquitously applicable method to detect hypervariability for multiple purposes, EXS, 58, 50-69.
14. Fierer, N., Bradford, M.A., and Jackson, R.B., 2007, Toward an ecological classification of soil bacteria, Ecology, 88(6), 1354-1364.
15. Ge, Y., Chen, C., Xu, Z., Eldridge, S., Chan, K., He, Y., and He, J.-Z., 2010, Carbon/nitrogen ratio as a major factor for predicting the effects of organic wastes on soil bacterial communities assessed by DNA-based molecular techniques, Environ. Sci. Pollut. Res., 17(3), 807-815.
16. Gevers, D., Huys, G., and Swings, J., 2001, Applicability of rep-PCR fingerprinting for identification of Lactobacillus species, FEMS Microbiol. Lett., 205(1), 31-36.
17. Hall, H.K., Karem, K.L., and Foster, J.W., 1995, Molecular responses of microbes to environmental pH stress, In: Edited by R. K. Poole, Advances in Microbial Physiology, Academic Press, London, U.K., pp. 229-272.
18. Hartman, W.H., Richardson, C.J., Vilgalys, R., and Bruland, G.L., 2008, Environmental and anthropogenic controls over bacterial communities in wetland soils, Proc. Natl. Acad. Sci. U.S.A., 105(46), 17842-17847.
19. Hugh-Jones, M. and Blackburn, J., 2009, The ecology of Bacillus anthracis, Mol. Aspects Med., 30(6), 356-367.
20. Madigan, M.T., Martinko, J.M., Dunlap, P.V., and Clark, D.P., 2009, Brock Biology of Microorganisms, Pearson Benjamin Cummings, San Francisco, CA.
21. Maier, R.M., Pepper, I.L., and Gerba, C.P., 2009, Environmental Microbiology, 2 edn, Academic Press, Burlington, MA.
22. Mohapatra, B., R. and Mazumder, A., 2008, Comparative efficacy of five different rep-PCR methods to discriminate Escherichia coli populations in aquatic environments, Water Sci. Technol., 58(3), 537-547.
23. Mohapatra, B.R., Broersma, K., and Mazumder, A., 2007, Comparison of five rep-PCR genomic fingerprinting methods for differentiation of fecal Escherichia coli from humans, poultry and wild birds, FEMS Microbiol. Lett., 277(1), 98-106.
24. Mormak, D.A. and Casida, L.E., 1985, Study of Bacillus subtilis endospores in soil by use of a modified endospore stain, Appl. Environ. Microbiol., 49(6), 1356-1360.
25. Moyes, R.B., Reynolds, J., and Breakwell, D.P., 2009, Differential staining of bacteria: Gram stain, Curr. Protoc. Microbiol., 15, A.3C.1-A.3C.8.
26. Polyanskaya, L., Ivanov, K., Guzev, V., and Zvyagintsev, D., 2008, Estimation of abundance dynamics of gram-negative bacteria in soil, Mikrobiologiia, 77(6), 760-764.
27. Rasschaert, G., Houf, K., Imberechts, H., Grijspeerdt, K., De Zutter, L., and Heyndrickx, M., 2005, Comparison of five repetitive-sequence-based PCR typing methods for molecular discrimination of Salmonella enterica isolates, J. Clin. Microbiol., 43(8), 3615-3623.
28. Raven, P.H., Johnson, G.B., Mason, K.A., Losos, J.B., and Singer, S.R., 2010, Biology, 9 edn, McGraw-Hill, New York, NY.
29. Samapundo, S., Heyndrickx, M., Xhaferi, R., and Devlieghere, F., 2011, Incidence, diversity and toxin gene characteristics of Bacillus cereus group strains isolated from food products marketed in Belgium, Int. J. Food Microbiol., 150(1), 34-41.
30. Sampathkumar, B., Khachatourians, G.G., and Korber, D.R., 2003, High pH during trisodium phosphate treatment causes membrane damage and destruction of Salmonella enterica serovar Enteritidis, Appl. Environ. Microbiol., 69(1), 122-129.
31. Svec, P., Novakova, D., Zackova, L., Kukletova, M., and Sedlacek, I., 2008, Evaluation of (GTG)5-PCR for rapid identification of Streptococcus mutans, Antonie van Leeuwenhoek, 94(4), 573-579.
32. Svec, P., Vancanneyt, M., Seman, M., Snauwaert, C., Lefebvre, K., Sedlacek, I., and Swings, J., 2005, Evaluation of (GTG)5-PCR for identification of Enterococcus spp., FEMS Microbiol. Lett., 247(1), 59-63.
33. Thanos, M., Schonian, G., Meyer, W., Schweynoch, C., Graser, Y., Mitchell, T.G., Presber, W., and Tietz, H.J., 1996, Rapid identification of Candida species by DNA fingerprinting with PCR, J. Clin. Microbiol., 34(3), 615-621.

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