Microbial quality of soil from the Pampa biome in response to
					different grazing pressures

Vargas, Rafael S.; Bataiolli, Renata; da Costa, Pedro B.; Lisboa, Bruno; Passaglia, Luciane Maria P.; Beneduzi, Anelise; Vargas, Luciano K.

doi:10.1590/S1415-475738138120140230

Abstract

The aim of this study was to evaluate the impact of different grazing pressures on the activity and diversity of soil bacteria. We performed a long-term experiment in Eldorado do Sul, southern Brazil, that assessed three levels of grazing pressure: high pressure (HP), with 4% herbage allowance (HA), moderate pressure (MP), with 12% HA, and low pressure (LP), with 16% HA. Two reference areas were also assessed, one of never-grazed native vegetation (NG) and another of regenerated vegetation after two years of grazing (RG). Soil samples were evaluated for microbial biomass and enzymatic (β-glucosidase, arylsulfatase and urease) activities. The structure of the bacterial community and the population of diazotrophic bacteria were evaluated by RFLP of the 16S rRNA and nifH genes, respectively. The diversity of diazotrophic bacteria was assessed by partial sequencing of the 16S rDNA gene. The presence of grazing animals increased soil microbial biomass in MP and HP. The structures of the bacterial community and the populations of diazotrophic bacteria were altered by the different grazing managements, with a greater diversity of diazotrophic bacteria in the LP treatment. Based on the characteristics evaluated, the MP treatment was the most appropriate for animal production and conservation of the Pampa biome.

bacterial diversity; diazotrophic bacteria; diversity; grasslands; soil microbial communities

Introduction

The Pampa biome is located between latitudes 24° and 35° S and covers an area of 500,000 km2 in Uruguay, northeastern Argentina, southern Brazil and part of Paraguay (Pallarés et al., 2005Pallarés OR, Berretta EJ and Maraschin GE (2005) The South American Campos ecosystem. In: Proceedings XXXIV Grasslands of the World, Rome, pp. 171–219.). This biome is composed of herbaceous native plants classified as steppe in the international phytogeographic system (Berreta, 2001Berreta E (2001) Ecophysiology and management response of the subtropical grasslands of southern America. In: Gomide JA, Mattos WRS and Silva SC (eds) Proceedings XIX International Grassland Congress, São Pedro, pp 939–946.) and is recognized for its great species diversity that includes approximately 450 grasses and 200 forage legumes (Boldrini, 2007Boldrini II (2007) Grasslands in southern Brazil: Origin, history and modifiers. In: Proceedings II Symposium on Forage and Animal Production, Porto Alegre, pp 7–13.).

Since European immigrants introduced the first herds in the 17^th century (Bilenca and Miñarro, 2004Bilenca D and Miñarro F (2004) Identificación de Áreas Valiosas de Pastizal en las Pampas y Campos de Argentina, Uruguay y Sur de Brasil. Fundación Vida Silvestre, Buenos Aires, 323 pp.), livestock production has been one of the main economic activities of the region, with the natural grassland serving as the feeding basis for animal production (Carvalho and Batello, 2009Carvalho PCF and Batello C (2009) Access to land, livestock production and ecosystem conservation in the Brazilian Campos biome: The natural grasslands dilemma. Livest Sci 120:158–162.). Historically, the natural grasslands of the Pampa biome have been used in extensive systems of beef cattle breeding characterized by low environmental impact, with little or no contribution of external inputs (Viglizzo et al., 2001Viglizzo EF, Lertora F, Pordomingo AJ, Bernardos JN, Roberto ZE and Del Valle H (2001) Ecological lessons and applications from one-century of low external-input farming in the pampas of Argentina. Agric Ecosyst Environ 83:65–81.). However, in recent decades, the ecosystem has been threatened by the introduction of exotic forage species, the exploitation of planted forests and the introduction of annual crops (Carvalho and Batello, 2009Carvalho PCF and Batello C (2009) Access to land, livestock production and ecosystem conservation in the Brazilian Campos biome: The natural grasslands dilemma. Livest Sci 120:158–162.). Even in areas still managed by the traditional livestock system, there are risks associated with overstocking (Carvalho et al., 2006)Carvalho PCF, Fischer V, Santos DT, Ribeiro AML, Quadros FLF, Castilhos ZMS, Poli CHEC, Monteiro ALG, Nabinger C, Genro TCM, et al. (2006) Animal production in the Southern Grasslands Biome. Rev Bras Zootecn 35:156–202.. Conte et al. (2011)Conte O, Wesp CL, Anghinoni I, Carvalho PCF, Levien R and Nabinger C (2011) Soil density, aggregation and carbon fractions of an Alfisol under natural pasture and different herbage allowance. Rev Bras Cienc Solo 35:579–587. claimed that adjustment of the number of animals to herbage allowance is critical to the sustainability of natural pastures. These authors found a decrease in labile carbon and an increase in soil density associated with a reduction in herbage allowance in an area of the Pampa biome. In addition to the loss of soil physical quality, often resulting in water erosion and compaction of the surface layers (Bertol et al., 2000Bertol I, Almeida, JA, Almeida EX and Kurtz C (2000) Soil physic properties related to forage offer levels of dwarf elephant grass cv. Mott. Pesq Agropec Bras 35:1047–1054.), excessive stocking may also result in decreased plant diversity (Soares et al., 2003Soares AB, Carvalho PCF, Garcia E, Boldrini II, Pontes LS, Velleda GL, Freitas MR and Freitas TMS (2003) Herbage allowance and species diversity on native pasture. Afr J Range Forage Sci 20:134–134.).

In natural environments or environments with little human intervention, such as traditional grazing systems of the Pampa biome, the soil microbiota plays a vital role in maintaining the ecosystem. The cycling of organic matter, nutrient availability and formation and stabilization of aggregates are a direct result of microbial activity that in turn influences the productivity, diversity and composition of plant communities (Van Der Heijden et al., 2008Van Der Heijden MGA, Bardgett RD and Van Straalen NM (2008) The unseen majority: Soil microbes as drivers of plant diversity and productivity in terrestrial ecosystems. Ecol Lett 11:296–310.). Pastures grown without fertilization, in soils with low natural fertility (Streck et al., 2008Streck EV, Kampf N, Dalmolin RSD, Klamt E, Nascimento PC and Schneider P (2008) Solos do Rio Grande do Sul. Emater, Porto Alegre, 222 pp.), are nutritionally poor environments in which symbiotic microorganisms are responsible for the acquisition of scarce nutrients by plants (Cleveland et al., 1999Cleveland CC, Townsend AR, Schimel DS, Fisher H, Howarth RW, Hedin LO, Perakis SS, Latty EF, von Fischer JC, Elseroad A et al. (1999) Global patterns of terrestrial biological nitrogen (N2) fixation in natural ecosystems. Global Biogeochem Cycles 13:623–645.; Van Der Heijden et al., 2008Van Der Heijden MGA, Bardgett RD and Van Straalen NM (2008) The unseen majority: Soil microbes as drivers of plant diversity and productivity in terrestrial ecosystems. Ecol Lett 11:296–310.). In such cases, diazotrophic bacteria assume an even more relevant role than in other agricultural systems and are the main source of nitrogen for the vegetation (Van der Heijden et al., 2006Van der Heijden MGA, Bakker R, Verwaal J, Scheublin TR, Rutten M, van Logtestijn R and Staehelin C (2006) Symbiotic bacteria as a determinant of plant community structure and plant productivity in dune grassland. FEMS Microbiol Ecol 56:178–187.).

Like the physical quality, the soil microbiological quality can also be affected by pasture management. Northup et al. (1999)Northup BK, Brown JR and Holt JA (1999) Grazing impacts on the spatial distribution of soil microbial biomass around tussock grasses in a tropical grassland. Appl Soil Ecol 13:259–270. found a decrease in the microbial biomass in soils under intensive grazing and attributed the result to a lower input of organic carbon with increasing grazing intensity. Similarly, Holt (1997)Holt JA (1997) Grazing pressure and soil carbon, microbial bio-mass and enzyme activities in semi-arid northeastern Australia. Appl Soil Ecol 5:143–149. noted that, in addition to the microbial biomass, enzyme activity was also reduced with excessive grazing in an Australian soil. Moreover, changes in the floristic composition of the pasture may result in changes in the structure of the soil microbial community, with consequences in its functionality (Johnson et al., 2003Johnson D, Booth RE, Whiteley AS, Bailey MJ, Read DJ, Grime JP and Leake JR (2003) Plant community composition affects the biomass, activity and diversity of microorganisms in limestone grassland soil. Eur J Soil Sci 54:671–678.). Since pastures are formed by a rich diversity of plants, the consequences of changes in the diversity and activity of soil microorganisms become more unpredictable than in less complex environments, such as annual crops.

In view of the importance of microbiological processes for preservation of the Pampa biome while at the same time allowing adequate economic exploitation, in this study we examined the impact of different grazing pressures on the microbial activity and diversity of soil bacteria.

Materials and Methods

Soil sampling

This study is part of a long-term experiment that has been ongoing at the Agronomic Experimental Station of the Federal University of Rio Grande do Sul (30°05′ S, 51°40′ W, and 46 m altitude), in Eldorado do Sul, Brazil, since 1986. This experiment involves different levels of grazing pressure in an area of natural grassland representative of the phyto-physiognomy of fields in the center of Rio Grande do Sul state (Boldrini et al., 2010Boldrini II, Ferreira PPA, Andrade BO, Schneider AA, Setubal RB, Trevisan R and Freitas EM (2010) Pampa Biome: Floristic Diversity and Physiognomy. Pallotti, Porto Alegre, 64 pp.), which is part of the Pampa biome. The soil of the experimental location is classified as Paleudult. The area has been maintained without any form of human intervention, except for adjustment of the grazing pressures, which are assessed on average every 28 days using the put-and-take technique.

Soil samples were collected in triplicate in the 0–5 cm layer based on a completely randomized design. Some of the samples were used to evaluate microbial soil quality while others were used to characterize the chemical properties of the soil by standard methods described in Sparks (1996)Sparks DL (1996) Methods of Soil Analysis: Chemical Methods. SSSA Book Series, Madison, 1390 pp. (Table 1).

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Table 1
Soil chemical properties under different grazing pressures.

The treatments consisted of three levels of grazing pressure: high grazing pressure (HP), with 4% herbage allowance (HA), moderate grazing pressure (MP), with 12% HA, and low grazing pressure (LP), with 16% HA. Two reference areas were also evaluated: an area of never-grazed native vegetation (NG) and another with regenerated vegetation (RG) that was grazed for two years and then excluded from grazing since 1988. In the experimental unit subjected to HP, there was only one layer of vegetation; this layer was homogeneous and had a low canopy profile, with the most frequent species belonging to the genera Paspalum, Axonopus, Piptochaetium and Coelorachis. In the other experimental units, there was an upper layer formed mainly by species of the genera Aristida, Eryngium, Andropogon, Baccharis and Vernonia that resulted in a bimodal pasture structure and mosaic pattern (Corrêa and Maraschin, 1994Corrêa FL and Maraschin GE (1994) Growth and disappearance in a natural pasture under four levels of forage on offer. Pesq Agropec Bras 29:1617–1623.).

Biochemical characteristics of the soil

Soil samples were evaluated for microbial biomass (MB), according to the method proposed by Horwath et al. (1996)Horwath WR, Paul EA, Harris D, Norton J, Jagger L and Horton KA (1996) Defining a realistic control for the chloroform fumigation incubation method using microscopic counting and 14C substrates. Can J Soil Sci 76:459–467.. The methods proposed by Dick et al. (1996)Dick PR, Breakwell DP and Turco RF (1996) Soil enzyme activities and biodiversity measurements as integrative microbiological indicators. In: Doran JW and Jones AJ (eds) Methods for Assessing Soil Quality. SSSA, Madison, pp 247–271. were used to assess the activities of the enzymes β-glucosidase (carbon cycle), arylsulfatase (sulfur cycle) and urease (nitrogen cycle). Determination of β-glucosidase and arylsulfatase activities was based on the actions of the enzymes on their specific substrates, with the reaction product (ρ-nitrophenol) being quantified colorimetrically. Urease was assessed based on the release of ammonium (NH₄ ⁺) by the action of the enzyme on urea. NH₄ ⁺ was quantified by distillation and titration according to Sparks (1996)Sparks DL (1996) Methods of Soil Analysis: Chemical Methods. SSSA Book Series, Madison, 1390 pp..

A geometric mean of the biochemical characteristics, adapted from Hinojosa et al. (2004)Hinojosa MB, García-Ruiz R, Viñegla B and Carreira JA (2004) Microbiological rates and enzyme activities as indicators of functionality in soils affected by the Aznalcóllar toxic spill. Soil Biol Biochem 36:1637–1644. and used as a general indicator of soil quality, was calculated using the formula GMba = (MB × AS × ßG × Ur), in which MB, AS, ßG and Ur represent the microbial biomass and the activities of arylsulfatase, β-glucosidase and urease, respectively. The data for the biochemical characteristics and GMba were assessed by analysis of variance (ANOVA) and the means were compared using the Scott-Knott test (Sisvar 5.1 Build 72), with p < 0.05 indicating significance (Ferreira, 2011Ferreira DF (2011) Sisvar: A computer statistical analysis system. Cienc Agrotec 35:1039–1042.).

DNA extraction from soil and evaluation of the bacterial community structure

DNA was extracted from 300 mg of soil using a NucleoSpin^® Soil kit (Macherey-Nagel), according to the manufacturer’s instructions. The purified DNA was used for the amplification reactions with primers specific for the 16S rRNA (Felske et al., 1999Felske A, Wolterink A, Van Lis R, De Vos WM and Akkermans ADL (1999) Searching of predominant soil bacteria 16S rDNA cloning vs. strain cultivation. FEMS Microbiol Ecol 30:137–145.) and nifH (Poly et al., 2001Poly F, Monrozier L and Bally R (2001) Improvement in the RFLP procedure for studying the diversity of nifH genes in communities of nitrogen fixers in soil. Res Microbiol 152:95–103.) genes. PCR mixes contained 50 ng of template DNA, 1x reaction buffer, 1 U of Taq DNA polymerase (Invitrogen), 100 μM of each deoxynucleotide, 1 μM of each primer, 50 mM MgCl₂ and ultrapure water to a final volume of 25 μL. Amplifications were done using an initial cycle of denaturation at 94 °C for 5 min, followed by 30 cycles of denaturation at 94 °C for 1 min, annealing for 1 min at 56 °C (for 16S rDNA) or 55 °C (for nifH) and extension at 72 °C for 1 min, followed by a final extension cycle at 72 °C for 5 min. The PCR products were visualized on a 1% agarose gel stained with Blue Green Loading Dye I (LGC Biotecnologia) and then subjected to restriction fragment length polymorphism (RFLP) analysis.

The restriction procedure was adapted from Widmer et al. (1999)Widmer F, Shaffer BT, Porteous LA and Seidler RJ (1999) Analysis of nifH gene pool complexity in soil and litter at a Douglas fir forest site in the Oregon Cascade Mountain Range. Appl Environ Microbiol 65:374–380. with the addition of 6 μL of PCR product to 40 μL of a mixture of ultrapure water, 2 U of the restriction enzyme and its corresponding buffer. The enzymes used were HaeIII, HindIII and MspI, and the incubation was done at 37 °C for at least 16 h to ensure complete digestion of the PCR products. The digestion products were resolved by electrophoresis for 3 h with a current of 200 V in 10% polyacrylamide gels in 1x TBE buffer stained with silver nitrate. Gel images were analyzed using Gel-Pro Analyzer 3.1 software and used to generate a binary matrix. The matrices were analyzed with Paleontological Statistics (PAST) software (Hammer et al., 2007Hammer O, Harper DAT and Ryan PD (2007) PAST - Paleontological statistics software for education and data analysis. Palaeontol Electron 4:1–9.) and the similarity dendrograms were quantified using the Jaccard coefficient.

Isolation, identification and diversity of culturable diazotrophs

Ten grams of soil sample was suspended in sterile saline solution (0.85% NaCl) and incubated at 28°C with shaking for 16 h. Next, serial dilutions (up to 10⁻³) were done and 0.1 mL aliquots were removed and inoculated on three semi-solid media lacking N: nitrogen-free malate (NFb), LGI and LGI-P. Bacterial isolation was done as described by Döbereiner et al. (1995)Döbereiner J, Baldani VLD and Baldani JI (1995) How to Isolate and Identify Diazotrophs of Non-leguminous Plants. Embrapa, Brasília, 60 pp.. The 16S rRNA gene of 100 bacterial isolates was partially amplified (∼450 bp) by PCR (Felske et al., 1999Felske A, Wolterink A, Van Lis R, De Vos WM and Akkermans ADL (1999) Searching of predominant soil bacteria 16S rDNA cloning vs. strain cultivation. FEMS Microbiol Ecol 30:137–145.). The amplification products were sequenced in the ACT-Gene Laboratory (Center of Bio-technology, UFRGS, RS, Brazil) using an automatic sequencer (ABI-PRISM 3100 Genetic Analyzer 50 cm capillary, Applied Biosystems). The 16S rRNA sequences were analyzed using the BLASTN program (NCBI BLAST) and were deposited in the GenBank database under accession numbers KM032779 to KM032874.

PAST software was used to calculate the Shannon diversity index (H’, Shannon and Weaver, 1949Shannon CE and Weaver W (1949) The Mathematical Theory of Communication. University of Illinois Press, Urbana, 117 pp.), dominance (D) and equitability (J) based on the number of isolates belonging to each taxon. Principal coordinate analysis (PCA) was used to assess the correlation between soil properties and population diversity.

Results

Biochemical characteristics indicative of soil quality

The biochemical properties of the soils were significantly influenced by the different grazing management schemes, as summarized in Table 2. NG vegetation had the lowest values for all biochemical parameters evaluated, similar to those observed in the LP treatment. The overall geometric mean for the biochemical characteristics was significantly higher in the MP and HP treatments.

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Table 2
Biochemical characteristics of the soil under different grazing pressures.

Soil bacterial diversity

The structure of the soil bacterial community was assessed by RFLP based on the amplification products of the 16S rRNA and nifH genes (Figure 1). The diversity of culturable diazotrophic bacteria was also analyzed by partial sequencing of the 16S rRNA gene (Table 3). Analysis of the RFLP profiles of the 16S rRNA gene revealed a distinct structure of bacterial communities in the different treatments. The NG treatment replicates were grouped in an isolated cluster and shared approximately 60% similarity with the other profiles. A second subdivision, with nearly 70% similarity, contained the samples of the HP treatment. Samples of the MP, LP and NG treatments had profiles that were more similar to each other (> 80% similarity) than to the other groups.

Figure 1
Dendrograms generated from RFLP profiles of the 16S rDNA (A) and nifH (B) genes from DNA isolated from soil under different grazing intensities. HP - high grazing pressure, LP - low grazing pressure, MP - moderate grazing pressure, NG - never-grazed native vegetation, RG - regenerated vegetation.

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Table 3
Diversity of diazotrophic bacteria in soil under different grazing pressures.

The RFLP profiles of the nifH gene showed a more complex pattern, with greater variability between treatments and between replicates of some treatments. The LP treatment differed from the others and formed a separate cluster, with little more than 20% similarity. The NG treatment also formed an isolated cluster and shared ∼50% similarity with the other treatments; the latter showed > 60% similarity among themselves.

Assessment of the diversity of culturable diazotrophic bacteria confirmed the presence of diverse populations in the different grazing treatments. Burkholderia and Enterobacter were the most ubiquitous bacteria, being identified in all treatments, with 50 and 26 isolates, respectively. The smallest number of taxa was observed in HP, where only these two genera were identified, while in the LP treatment eight taxa were found. The LP treatment also showed the highest H’, the lowest D and the highest J, contrasting again with HP.

Relationships between the chemical properties and biochemical characteristics of the soil

PCA was used to investigate the relationships between the biochemical characteristics and chemical properties of the soil under different treatments. The main components of PCA (PC1 and PC2) explained 86.2% of the total data variation, with PC1 accounting for 49.1% and PC2 for 37.1% (Figure 2). The MP and HP treatments were positioned on the left in PC1 and were more associated with the biochemical characteristics. Urease activity was associated with the soil pH, while the other biochemical characteristics were associated with the organic matter (OM) and phosphorous (P) content of the soil. This observation was supported by the significant positive correlations between OM and the activities of arylsulfatase (r = 0.96; p = 0.0078) and β-glucosidase (r = 0.92; p = 0.0254). In the opposite position in PC1 were the NG and LP treatments. The diversity of diazotrophic bacteria was related to the clay and basic cation (Ca²⁺, Mg²⁺ and K⁺) contents.

Figure 2
Principal component analysis of the chemical, biochemical and microbiological characteristics of soil under different grazing intensities. AS - arylsulfatase, βG - β-glucosidase, HP - high grazing pressure, LP -low grazing pressure, MB - microbial biomass, MP - moderate grazing pressure, NG - never-grazed native vegetation, RG - regenerated vegetation, Ur - urease.

Discussion

In this study, we investigated the long-term effects of increasing grazing pressures on the microbial quality of a soil compared with two control areas maintained without grazing. All of the variables analyzed were significantly affected by the treatments, indicating that the presence of cattle was beneficial in terms of microbiological quality of the soil.

The microbial biomass increased with increasing grazing intensity and with the number of animals per area in the MP and HP plots. Wang et al. (2006)Wang KH, McSorley R, Bohlen P and Gathumbi SM (2006) Cattle grazing increases microbial biomass and alters soil nematode communities in subtropical pastures. Soil Biol Biochem 38:1956–1965. also observed an increase in microbial biomass in areas under intensive grazing compared with an area excluded from grazing. Likewise, Iyyemperumal et al. (2007)Iyyemperumal K, Israel DW and Shi W (2007) Soil microbial bio-mass, activity and potential nitrogen mineralization in a pasture: Impact of stock camping activity. Soil Biol Biochem 39:149–157. reported an increase in microbial biomass with increasing animal waste deposition in grassland ecosystems, which in turn increased with the number of animals per area. The waste deposited in soil by grazing animals may stimulate the microbiota by providing more readily available labile organic matter compared to original plant material (Prieto et al., 2011Prieto LH, Bertiller MB, Carrera AL and Olivera NL (2011) Soil enzyme and microbial activities in a grazing ecosystem of Patagonian Monte, Argentina. Geoderma 162:281–287.). Grazing also promotes the growth and renewal of the plant root system, with a consequent increase in the rhizosphere effect. Hamilton et al. (2008)Hamilton III EW, Frank DA, Hinchey PM and Murray TR (2008) Defoliation induces root exudation and triggers positive rhizospheric feedbacks in a temperate grassland. Soil Biol Biochem 40:2865–2873. observed that defoliation, which simulates what occurs during grazing, increased the production of root exudates in Poapratensis by 1.5 fold, resulting in a proportional increase in the microbial biomass.

The soil enzymatic activity controls the cycling of nutrients through the mineralization of OM and constitutes an important indicator of the functional capacity of soil (Mijangos et al., 2006Mijangos I, Pérez R, Albizu I and Garbisu C (2006) Effects of fertilization and tillage on soil biological parameters. Enzyme Microb Technol 40:100–106.). ß-Glucosidase, urease and arylsulfatase participate in the C, N and S cycles, respectively. The activities of these hydrolytic enzymes have been widely used in assessments of soil quality because they are highly sensitive to disturbances in the soil (Bandick and Dick, 1999Bandick AK and Dick RP (1999) Field management effects on soil enzyme activities. Soil Biol Biochem 31:1471–1479.; Matsuoka et al., 2003Matsuoka M, Mendes IC and Loureiro MF (2003) Microbial bio-mass and enzyme activities in soils under native vegetation and annual and perennial cropping systems in the region of Primavera do Leste (MT). Rev Bras Cienc Solo 27:425–433.). Our results show that the activities of these three enzymes followed the same trend as microbial biomass and the geometric mean of the biochemical characteristics (GMba), i.e., higher in the MP and HP treatments compared with the LP and NG treatments. Similar results were obtained by Esch et al. (2013)Esch EH, Hernández DL, Pasari JR, Kantor RSG and Selmants PC (2013) Response of soil microbial activity to grazing, nitrogen deposition, and exotic cover in a serpentine grassland. Plant Soil 366:671–682., who observed a linear increase in enzymatic activity with increasing grazing pressure. As discussed for microbial biomass, enzymatic activity is favored by the deposition of animal waste (Bol et al., 2003Bol R, Kandeler E, Amelung W, Glaser B, Marx MC, Preedy N and Lorenz K (2003) Short-term effects of dairy slurry amendment on carbon sequestration and enzyme activities in a temperate grassland. Soil Biol Biochem 35:1411–1421.) and the rhizosphere effect (Reddy et al., 1987Reddy GB, Faza A and Bennett Jr R (1987) Activity of enzymes in rhizosphere and non-rhizosphere soils amended with sludge. Soil Biol Biochem 19:203–205.). A previous investigation done in the same area showed a linear increase in the root mass of native grassland with increasing grazing pressure (Conte et al., 2011Conte O, Wesp CL, Anghinoni I, Carvalho PCF, Levien R and Nabinger C (2011) Soil density, aggregation and carbon fractions of an Alfisol under natural pasture and different herbage allowance. Rev Bras Cienc Solo 35:579–587.), and this was apparently accompanied by increased enzymatic activity.

The microbial community structure was also altered by the treatments. With regard to the bacterial community in general, the NG area had a completely different structure. Indeed, non-grazed areas often have microbial communities that differ from those of grazed areas (Frank et al., 2003Frank DA, Gehring CA, Machut L and Phillips M (2003) Soil community composition and the regulation of grazed temperate grassland. Oecologia 137:603–609.; Ford et al., 2013Ford H, Rousk J, Garbutt A, Jones L and Jones DL (2013) Grazing effects on microbial community composition, growth and nutrient cycling in salt marsh and sand dune grasslands. Biol Fertil Soils 49:89–98.), and the changes caused by grazing seem to occur more rapidly than an eventual recovery of the original structure after interruption of grazing (Attard et al., 2008Attard E, Degrange V, Klumpp K, Richaume A, Soussana JF and Roux XL (2008) How do grassland management history and bacterial micro-localization affect the response of bacterial community structure to changes in aboveground grazing regime? Soil Biol Biochem 40:1244–1252.).

HP grazing was distinguishable from the other groups in terms of microbial community structure. A similar result was described by Zhou et al. (2010)Zhou X, Wang J, Hao Y and Wang Y (2010) Intermediate grazing intensities by sheep increase soil bacterial diversities in an Inner Mongolian steppe. Biol Fertil Soils 46:817–824., who found that microbial communities of non-grazed areas and intensely grazed areas were different from those of areas under moderate and low intensities of grazing. The presence of grazing animals is expected to alter the microbial community structure mainly by modifying the composition of the plant community and the contribution of organic C, especially the labile fraction (Attard et al., 2008Attard E, Degrange V, Klumpp K, Richaume A, Soussana JF and Roux XL (2008) How do grassland management history and bacterial micro-localization affect the response of bacterial community structure to changes in aboveground grazing regime? Soil Biol Biochem 40:1244–1252.). As revealed by previous studies done in this same experimental area, the treatments applied over the years differed with respect to their floristic composition and in relation to the availability of labile C. In both aspects (considered crucial for microbial community structure), the HP treatment differed dramatically from the others, with lower plant diversity (Corrêa and Maraschin, 1994Corrêa FL and Maraschin GE (1994) Growth and disappearance in a natural pasture under four levels of forage on offer. Pesq Agropec Bras 29:1617–1623.) and a reduction in the soil labile organic C (Conte et al., 2011Conte O, Wesp CL, Anghinoni I, Carvalho PCF, Levien R and Nabinger C (2011) Soil density, aggregation and carbon fractions of an Alfisol under natural pasture and different herbage allowance. Rev Bras Cienc Solo 35:579–587.).

In view of the importance of diazotrophic bacteria for the functioning of a managed ecosystem without the contribution of external inputs, the structure of this bacterial community was assessed as proposed by Poly et al. (2001)Poly F, Monrozier L and Bally R (2001) Improvement in the RFLP procedure for studying the diversity of nifH genes in communities of nitrogen fixers in soil. Res Microbiol 152:95–103.. In a manner similar to those authors, who observed that the nifH gene pool was different in soil under cultivation compared with a natural pasture, we observed that grazing affected the structure of the nitrogen-fixing community. Compared with the 16S rRNA gene, the RFLP amplification of the nifH gene products produced results with greater variability. Additionally, more than the NG treatment, LP soil differed more from the others than did NG treatment. These results are consistent with reports that the composition of the nifH gene pool varies between soils and between micro-environments within a soil (Widmer et al., 1999Widmer F, Shaffer BT, Porteous LA and Seidler RJ (1999) Analysis of nifH gene pool complexity in soil and litter at a Douglas fir forest site in the Oregon Cascade Mountain Range. Appl Environ Microbiol 65:374–380.; Poly et al., 2001Poly F, Monrozier L and Bally R (2001) Improvement in the RFLP procedure for studying the diversity of nifH genes in communities of nitrogen fixers in soil. Res Microbiol 152:95–103.; Soares et al., 2006Soares RA, Roesch LFW, Zanatta G, Camargo FO and Passaglia LMP (2006) Occurrence and distribution of nitrogen fixing bacterial community associated with oat (Avena sativa) assessed by molecular and microbiological techniques. Appl Soil Ecol 33:221–234.).

The presence of a distinct community in the LP treatment was confirmed by the analysis of culturable diazotrophic bacteria. In this treatment, the largest number of genera, the highest H’, the lowest D and the highest J were identified, indicating that the nitrogen-fixing microorganisms benefitted from the diversity of plant species and the presence of animals in this plot. The diversity of diazotrophic bacteria has been attributed to several abiotic factors (Reardon et al., 2014Reardon CL, Gollany HT and Wuest SB (2014) Diazotroph community structure and abundance in wheat-fallow and wheat-pea crop rotations. Soil Biol Biochem 69:406–412.). In this study, PCA revealed an association with the soil texture and aspects related to soil fertility, most notably the presence of the basic cations Ca, Mg and K.

In a previous study done in the same area, Conte et al. (2011)Conte O, Wesp CL, Anghinoni I, Carvalho PCF, Levien R and Nabinger C (2011) Soil density, aggregation and carbon fractions of an Alfisol under natural pasture and different herbage allowance. Rev Bras Cienc Solo 35:579–587. observed an increase in density and a reduction in labile carbon with the most intensive grazing, suggesting that this treatment would result in a loss of soil quality. This trend was not confirmed in our study, possibly because the natural grasslands of the Pampa biome are complex systems in which a reduction in one soil quality indicator will not necessarily be accompanied by a reduction in the others. However, considering the biochemical and microbiological characteristics evaluated here and the history of the area in terms of individual animal performance (Mezzalira et al., 2012Mezzalira JC, Carvalho PCF, Trindade JK, Bremm C, Fonseca L, Amaral MF and Reffatti MV (2012) Livestock and crop production on native pasture managed and different herbage allowances for cattle. Cienc Rural 42:1264–1270.), chemical and physical characteristics of the soil (Conte et al., 2011Conte O, Wesp CL, Anghinoni I, Carvalho PCF, Levien R and Nabinger C (2011) Soil density, aggregation and carbon fractions of an Alfisol under natural pasture and different herbage allowance. Rev Bras Cienc Solo 35:579–587.) and floristic composition (Corrêa and Maraschin, 1994Corrêa FL and Maraschin GE (1994) Growth and disappearance in a natural pasture under four levels of forage on offer. Pesq Agropec Bras 29:1617–1623.), the adoption of MP grazing appears to the most appropriate for animal production and conservation of the Pampa biome.

In conclusion, this study evaluated the microbiological quality of soil from the Pampa biome under different grazing intensities. In general, the presence of grazing animals was beneficial for the soil microbial community. Higher intensities of grazing favored an increase in microbial biomass and enzymatic activity. The lowest grazing level showed a greater diversity of diazotrophic bacteria. Additional studies on the microbial diversity in pastures of the Pampa biome are underway and will improve our understanding of the effects of different grazing intensities on the microbial community in soils of this complex ecosystem.

Acknowledgments

The authors thank Prof. Paulo César de Faccio Carvalho (Faculdade de Agronomia, UFRGS, RS, Brazil) for providing access to the experimental area. This work was financially supported by a grant from Conselho Nacional de Desenvolvimento Científico e Tecnológico (CNPq, Brazil) and Instituto Nacional de Ciência e Tecnologia (INCT) da Fixação Biológica do Nitrogênio (Brazil).

Associate Editor: Célia Maria de Almeida Soares

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Publication Dates

Publication in this collection
01 May 2015
Date of issue
Apr-Jun 2015

History

Received
31 July 2014
Accepted
30 Oct 2014

License information: This is an open-access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

[1] Associate Editor: Célia Maria de Almeida Soares

Sample	Clay (%)	OM (%)	pH (H₂O)	P_exc (mg/dm³)	K_exc (mg/dm³)	Al_exc (Cmol_c/dm³)	Ca_exc (Cmol_c/dm³)	Mg_exc (Cmol_c/dm³)
NG	21	1.9	4.8	1.4	104	0.9	0.1	0.6
RG	30	2.9	4.4	2.2	128	1.4	0.3	0.7
LP	28	2.5	4.7	1.4	138	0.8	0.9	0.8
MP	19	3.6	5.0	2.2	79	1.3	0.1	0.5
HP	22	2.5	4.9	1.4	75	1.2	0.3	0.7

Sample	Microbial biomass (mg kg⁻¹)	Arylsulfatase (mg ρ-nitrophenol kg soil⁻¹h⁻¹)	β-Glucosidase (mg ρ-nitrophenol kg soil⁻¹h⁻¹)	Urease (mg NH₄ ⁺ kg soil⁻¹h⁻¹)	GMba
NG	165^b	12.9^c	3.1^b	29.4^b	21.0^b
RG	255^a	20.2^a	5.0^a	21.2^b	27.2^b
LP	191^b	16.3^b	3.4^b	31.1^b	23.9^b
MP	249^a	21.6^a	6.9^a	31.1^b	32.7^a
HP	250^a	16.2^b	5.0^a	46.7^a	31.1^a

Taxa	Sample

	NG	RG	LP	MP	HP	Total

	Number of individuals
Achromobacter sp.	-	2	-	-	-	2
Burkholderia sp.	6	10	6	13	15	50
Enterobacter sp.	7	5	5	5	4	26
Klebsiella sp.	1	-	-	-	-	1
Gluconacetobacter sp.	-	-	2	-	-	2
Ochrobactrum sp.	-	-	3	-	-	3
Pantoea sp.	1	1	-	-	-	2
Pseudomonas sp.	-	1	1	1	-	3
Serratia sp.	4	-	-	-	-	4
Stenotrophomonas sp.	-	-	-	-	1	1
Uncultured Enterobacteriaceae	1	-	1	1	-	3
Uncultured	-	-	1	-	-	1
Unidentified	-	1	1	-	-	2
Total	20	20	20	20	20	100
Diversity index
H’	1.5	1.37	1.82	0.93	0.69
D	0.26	0.33	0.19	0.49	0.60
J	0.84	0.77	0.88	0.67	0.63

Sample	Clay (%)	OM (%)	pH (H₂O)	P_exc (mg/dm³)	K_exc (mg/dm³)	Al_exc (Cmol_c/dm³)	Ca_exc (Cmol_c/dm³)	Mg_exc (Cmol_c/dm³)
NG	21	1.9	4.8	1.4	104	0.9	0.1	0.6
RG	30	2.9	4.4	2.2	128	1.4	0.3	0.7
LP	28	2.5	4.7	1.4	138	0.8	0.9	0.8
MP	19	3.6	5.0	2.2	79	1.3	0.1	0.5
HP	22	2.5	4.9	1.4	75	1.2	0.3	0.7

Sample	Clay (%)	OM (%)	pH (H₂O)	P_exc (mg/dm³)	K_exc (mg/dm³)	Al_exc (Cmol_c/dm³)	Ca_exc (Cmol_c/dm³)	Mg_exc (Cmol_c/dm³)
NG	21	1.9	4.8	1.4	104	0.9	0.1	0.6
RG	30	2.9	4.4	2.2	128	1.4	0.3	0.7
LP	28	2.5	4.7	1.4	138	0.8	0.9	0.8
MP	19	3.6	5.0	2.2	79	1.3	0.1	0.5
HP	22	2.5	4.9	1.4	75	1.2	0.3	0.7

Brasil

Brasil

Microbial quality of soil from the Pampa biome in response to different grazing pressures

Abstract

Introduction

Materials and Methods

Soil sampling

Biochemical characteristics of the soil

DNA extraction from soil and evaluation of the bacterial community structure

Isolation, identification and diversity of culturable diazotrophs

Results

Biochemical characteristics indicative of soil quality

Soil bacterial diversity

Relationships between the chemical properties and biochemical characteristics of the soil

Discussion

Acknowledgments

References

Publication Dates

History

Sample	Clay (%)	OM (%)	pH (H₂O)	P_exc (mg/dm³)	K_exc (mg/dm³)	Al_exc (Cmol_c/dm³)	Ca_exc (Cmol_c/dm³)	Mg_exc (Cmol_c/dm³)
NG	21	1.9	4.8	1.4	104	0.9	0.1	0.6
RG	30	2.9	4.4	2.2	128	1.4	0.3	0.7
LP	28	2.5	4.7	1.4	138	0.8	0.9	0.8
MP	19	3.6	5.0	2.2	79	1.3	0.1	0.5
HP	22	2.5	4.9	1.4	75	1.2	0.3	0.7