Browse > Article
http://dx.doi.org/10.1186/s41610-016-0004-1

Effect of pH on soil bacterial diversity  

Cho, Sun-Ja (Department of Microbiology, Pusan National University)
Kim, Mi-Hee (Busan Metropolitan City Institute of Health and Environment)
Lee, Young-Ok (Department of Biological Sciences, Daegu University)
Publication Information
Journal of Ecology and Environment / v.40, no.1, 2016 , pp. 75-83 More about this Journal
Abstract
Background: In order to evaluate the effect of pH, known as a critical factor for shaping the biogeographical microbial patterns in the studies by others, on the bacterial diversity, we selected two sites in a similar geographical location (site 1; north latitude 35.3, longitude 127.8, site 2; north latitude 35.2, longitude 129.2) and compared their soil bacterial diversity between them. The mountain soil at site 1 (Jiri National Park) represented naturally acidic but almost pollution free (pH 5.2) and that at site 2 was neutral but exposed to the pollutants due to the suburban location of a big city (pH 7.7). Methods: Metagenomic DNAs from soil bacteria were extracted and amplified by PCR with 27F/518R primers and pyrosequenced using Roche 454 GS FLX Titanium. Results: Bacterial phyla retrieved from the soil at site 1 were more diverse than those at site 2, and their bacterial compositions were quite different: Almost half of the phyla at site 1 were Proteobacteria (49 %), and the remaining phyla were attributed to 10 other phyla. By contrast, in the soil at site 2, four main phyla (Actinobacteria, Bacteroidetes, Proteobacteria, and Cyanobacteria) composed 94 %; the remainder was attributed to two other phyla. Furthermore, when bacterial composition was examined on the order level, only two Burkholderiales and Rhizobiales were found at both sites. So depending on pH, the bacterial community in soil at site 1 differed from that at site 2, and although the acidic soil of site 1 represented a non-optimal pH for bacterial growth, the bacterial diversity, evenness, and richness at this site were higher than those found in the neutral pH soil at site 2. Conclusions: These results and the indices regarding diversity, richness, and evenness examined in this study indicate that pH alone might not play a main role for bacterial diversity in soil.
Keywords
Pyrosequencing; pH; Bacterial diversity; Biodiversity indices;
Citations & Related Records
연도 인용수 순위
  • Reference
1 Ahn, BK, Kim, DH, & Lee, JH (2007). Post harvest cropping impacts on soil properties in continuous Watermelon (Citrullus lanatus Thunb.) cultivation plots (in Korean). Korean Journal of Soil Science and Fertilizer, 40, 98-107.
2 Alexander, M (1977). Introduction to soil microbiology (2nd ed., Vol. 142, pp. 12-13). New York: John Wiley & Sons.
3 Amann, R, & Schleifer, KH (2001). Nucleic acid probes and their application in environmental microbiology. In DR Boone & R Castenholz (Eds.), Bergey's Manual of Systematic Bacteriology (Vol. I, pp. 67-82).: Springer.
4 Brons, JK, & van Elsas, JD (2008). Analysis of bacterial communities in soil by use of denaturing gradient gel electrophoresis and clone libraries, as influenced by different reverse primers. Applied and Environmental Microbiology, 74, 2717-2727.   DOI
5 Cookson, WR, Osman, M, Marschner, P, Abaye, DA, Clark, I, Murphy, DV, Stockdale, EA, & Watson, CA (2007). Controls on soil nitrogen cycling and microbial community composition across land use and incubation temperature. Soil Biology and Biochemistry, 39, 744-756.   DOI
6 DeLong, EF, Wickham, GS, & Pace, NR (1989). Phylogenetic strains; ribosomal RNA-based probes for the identification of single microbial cells. Science, 243, 1360-1363.   DOI
7 Environment standard methods. (2009). 2009-255, ES07400.2. Metals by inductively coupled plasma-atomic emission spectrometry. Korea: Ministry of Environment standard.
8 Fierer, N, & Jackson, B (2006). The diversity and biogeography of soil bacterial communities. PNAS, 103, 626-631.   DOI
9 Green, JL, Bohannan, BJM, & Whitaker, RJ (2008). Microbial biogeography: from taxonomy to traits. Science, 320, 1039-1043.   DOI
10 Haas, BJ, Gevers, D, Earl, AM, Feldgarden, M, Ward, DV, Giannoukos, G, Ciulla, D, Tabbaa, D, Highlander, SK, & Sodergren, E (2011). Chimeric 16S rRNA sequence formation and detection in Sanger and 454-pyro-sequenced PCR amplicons. Genome Research, 21, 494-504.   DOI
11 Han, SI, Cho, MH, & Whang, KS (2008). Comparison of phylogenetic characteristics of bacterial populations in a Quercus and pine humus forest soil. Korean Journal of Microbiology, 44, 237-243.
12 Hartman, WH, Richardson, CJ, Vilgalys, R, & Bruland, GL (2008). Environmental and anthropogenic controls over bacterial communities in wetland soils. PNAS, 105, 17842-17847.   DOI
13 Herlemann, DPR, Geissinger, O, & Brune, A (2007). The termite group I Phylum is highly diverse and wide-spread in the environment. Applied and Environmental Microbiology, 73, 6682-6685.   DOI
14 Horner-Devine, MC, Carney, KM, & Bohannan, JM (2004). An ecological perspective on bacterial diversity. Proceedings of the Biological Sciences, 271(1535), 113-122.   DOI
15 Hwang, OK, Raveendar, S, Kim, YJ, Kim, JH, Kim, TH, Choi, DY, Jeon, CO, et al. (2014). Deodorization of pig slurry and characterization of bacterial diversity using 16S rDNA sequence analysis. Journal of Microbiology, 52, 918-929.   DOI
16 Kelly, JJ, Håggblom, M, & Tate, RL, III (1999). Changes in soil microbial communities over time resulting from one time application of zinc: a laboratory microcosm study. Soil Biology and Biochemistry, 31, 1455-1465.   DOI
17 Lee, EY, Lim, JS, Oh, KH, Lee, JY, Kim, SK, Lee, YK, & Kim, K (2008). Removal of heavy metals by an enriched consortium. Journal of Microbiology, 46, 23-8. doi:10.1007/s12275-007-0131-6.   DOI
18 Kennedy, AC, & Smith, KL (1995). Soil microbial diversity and the sustainability of agricultural soils. Plant and Soil, 170, 75-86.   DOI
19 Korea Forest Service: http://english.forest.go.kr/newkfsweb/eng/idx/Index.do?mn=ENG_01. Accessed 24 June 2015.
20 Lauber, CL, Hamady, M, Knight, R, & Fierer, N (2009). Pyrosequencing-based assessment of soil pH as a predictor of soil bacterial community structure at the continental scale. Applied and Environmental Microbiology, 75, 5111-5120.   DOI
21 Li, Y, Chen, L, Wen, H, Zhou, T, Zhang, T, & Gao, X (2012). 454 Pyrosequencing analysis of bacterial diversity revealed by a comparative study of soils from mining subsidence and reclamation areas. Journal of Microbiology and Biotechnology, 24, 313-323.
22 Liang, Y, Van Nostrand, JD, Deng, Y, He, Z, Wu, L, Zhang, X, Li, G, & Zhou, J (2011). Functional gene diversity of soil microbial communities from five oilcontaminated fields in China. ISME Journal, 5, 403-413.   DOI
23 Liu, Z, Lozupone, C, Hamady, M, Bushman, FD, & Knight, R (2007). Short pyrosequencing reads suffice for accurate microbial community analysis. Nucleic Acids Research, 35, e120.   DOI
24 Ludwig, W, & Klenk, HP (2001). Overview: a phylogenetic backbone and taxonomic framework for prokaryotic systematics. In DR Boone & RW Castenholz (Eds.), Bergey's Manual of Systematic Bacteriology (Vol. I, pp. 49-65).: Springer.
25 Madigan, MT, Martino, JM, Stahl, DA, & Clark, DP (2010). Brock biology of microorganisms. Global 13th ed (pp. 670-711).: Benjamin Cummings.
26 Roane, TM, & Pepper, IL (2000). Microbial responses to environmentally toxic cadmium. Microbial Ecology, 38, 358-364.
27 Maier, RM, & Pepper, IL (2009). Earth Environments. In R. M. Maier, I. L. Pepper, & C. P. Gerba (Eds.), Environmental microbiology (2nd ed., pp. 57-82).: Academic.
28 Marilley, L, & Aragno, M (1999). Phylogenetic diversity of bacterial communities differing in degree of proximity of Lolium perenne and Trifolium repens roots. Applied Soil Ecology, 13, 127-136.   DOI
29 OTU clustering; mothur (version 1.27.0). (http://www.mothur.org), (http://www.mothur.org), CD-HIT-OTU (http://weizhong-lab.ucsd.edu/cd-hit-otu/) (http://weizhong-lab.ucsd.edu/cd-hit-otu/). Accessed 29 Aug 2013.
30 Sandaa, RA, Torsvik, V, & Enger, O (2001). Influence of long term heavy metal contamination on microbial communities in soil. Soil Biology and Biochemistry, 33, 287-295.   DOI
31 Schramm, A, DE Beer, D, Wagner, M, & Amann, R (1998). 1998. Identification and activities in situ of Nitrosospira and Nitrospira spp. as dominant populations in a nitrifying fluidized bed reactor. Applied and Environmental Microbiology, 64, 3480-3485.
32 Sessitsch, A, Weilharter, A, Gerzabek, MH, Kirchmann, H, & Kandeler, E (2001). Microbial population structures in soil particle size fractions of long-term fertilizer field experiment. Applied and Environmental Microbiology, 67, 4215-4224.   DOI
33 Silva rRNA database (http://www.arb-silva.de/). (http://www.arb-silva.de/). Accessed 29 Aug 2013.
34 Smit, E, Leeflang, P, Gommans, S, van den Broek, J, van Mil, S, & Wernars, K (2001). Diversity and seasonal fluctuations of the dominant members of the bacterial soil community in a wheat field as determined by cultivation and molecular methods. Applied and Environmental Microbiology, 67, 2284-2291.   DOI
35 Will, C, Thurmer, A, Wollherr, A, Nacke, H, Herold, N, Schrumpf, M, Gutknecht, J, Wubet, T, Buscot, F, & Daniel, R (2001). Horizon-specific bacterial community composition of German grassland soils, as revealed by pyrosequencingbased analysis of 16S rRNA genes. Applied and Environmental Microbiology, 76, 6751-6759.
36 Torsvik, V, & Ovreas, L (2002). Microbial diversity and function in soil: from genes to ecosystems. Current Opinion in Microbiology, 5, 240-245.   DOI
37 Torsvik, V, Salte, K, Sorheim, R, & Goksoyr, J (1990). Comparison of phenotypic diversity and DNA heterogeneity in a population of soil bacteria. Applied and Environmental Microbiology, 56, 776-781.