Study Area

The study was carried out in the Saracá-Taquera National Forest (hereafter STNF; 01°20′–01°55′ S to 56°00′–57°15′ W), a Federal Protected Area located in the municipality of Oriximiná, State of Pará, on the right bank of the Trombetas River (Figure 1). The region presents a warm and humid Equatorial climate; mean annual temperature is 26 °C. The terrain has steep plateaus and slopes around it, with a maximum altitude of 140 m, and sand banks through which run streams (Knowles & Parrotta, 1995; MMA, 2001; Parrotta, 1995). Since 1979, STNF is under concession to a private company for bauxite mining. This activity includes deforestation of native areas located in plateaus and, after the depletion of mines, reforestation with seedlings of native species (Knowles & Parrotta, 1995) (Figure 1).

Figure 1.

Saracá-Taquera National Forest in Oriximiná, Pará, Brazil. Background colors represent elevation, with reddish and green shades indicating high and low elevation, respectively. Map inset shows geographic location of each surveyed site, dark-gray, gray, and purple color represents nonimpacted sites, whereas impacted sites are represented by orange, violet, pink, light-pink, and blue colors. Yellow dots represent the location of each sampling set.

Data Collection

The study was carried out in the areas adjacent to the deforestation resulting from the mining activity of bauxite extraction. The impacted sites and their respective deforested sizes were the following: Almeidas (702.32 ha), Aviso (1,140.06 ha), Papagaio (418.31 ha), Periquito (369.84 ha), and Saracá (1,134.62 ha). For comparison, we studied continuous forests sites, used as a control, which were not impacted by the mining: Bela Cruz, Greig, and Monte Branco sites (Figure 1).

In the impacted sites, we installed two sets of sample units adjacent to the deforested plateaus, whereas in the nonimpacted sites, four sets of sampling unit were installed since the plateaus were not deforested. Each sample set was formed by four parallel sampling lines of 350 m each. The lines were placed at a distance of 50 m, 100 m, 250 m, and 500 m from the forest edge of impacted sites and in the continuous forest in nonimpacted sites (Figure 2). In each parallel line, we installed six pitfall traps, consisting of buckets of 64 liters spaced 50 m from one another and connected by a plastic canvas of 60 cm in height. At the end of each pitfall sequence, 10 live traps were distributed in pairs with 15 m between each pair of traps. Each pair consisted of both a Sherman (430 × 125 × 145 mm) and a Tomahawk (450 × 210 × 210 mm) traps. The traps were placed alternately on the ground and suspended to capture the maximum number of species with different habits (Pardini, 2004; Umetsu et al., 2006).

Figure 2.

Schematic representation of sampling units used to assess nonvolant small mammals at Saracá-Taquera National Forest, Oriximiná, Pará, Brazil. (A) Sampling design used in impacted sites; white circle represent deforested site by mining activities, and black lines represent parallel trap lines at 50 m, 100 m, 250 m, and 500 m from forest edge. (B) Sampling design used at non-impacted sites; black lines represent trap lines at 50 m, 150 m, and 250 m from each other.

All live-catch traps were baited with small portions of an attractant made of banana, peanut powder, corn meal, and sardines. The traps were checked daily, and the baits were replaced to maintain their attractiveness (Pardini, 2004; Pardini et al., 2005; Umetsu & Pardini, 2007). The live-catch traps and the pitfalls remained open for six consecutive nights at each site. Field surveys were conducted during both rainy and dry seasons of the years 2010 and 2011 and during the rainy season of 2012, totaling five field surveys at Almeidas, Aviso, Bela Cruz, Monte Branco, Papagaio, Periquito, and Saracá, whereas, at Greig, data were collected during the dry season of 2011 and during the rainy season of 2012.

Voucher individuals of each species and those unidentified in the field were euthanized using the usual techniques of preservation of biological material (Auricchio, 2002), the others were tagged (Fish and Small Animal Tag, size 1; National Band and Tag Co., Newport, Kentucky) and released at the same capture location. Animal manipulation and marking followed ASM guidelines (Gannon et al., 2007) and was authorized by the Chico Mendes Institute of Biodiversity (ICMBIO; MMA/ICMBio license No. 009/2010, MMA/ICMBio license No. 010/2012, renov. 9 A/2010). The collected animals were deposited in the scientific collection of the Capão da Imbuia Natural History Museum, Curitiba, Paraná, Brazil.

Data Analysis

All analyses were carried out in program R version 3.5.3 (R Core Team, 2015). Using package iNEXT (Hsieh et al., 2016), we evaluated sample completeness and compared the number of species between impacted and nonimpacted sites using sample size rarefaction (interpolation) and prediction of Hill numbers by extrapolating the number of individuals twice.

We performed Generalized Linear Model using a Poisson distribution to assess the relationship between nonvolant small mammals’ species richness in impacted sites, distance to edge, and the size of the deforested area (Bolker et al., 2009). Principal Coordinates Analysis (PCoA) was used to depict variation in assemblage structure between the nonimpacted and impacted sites. To test the differences in species composition between impacted and nonimpacted sites, we used a Multivariate Permutational Analysis of Variance (PerMANOVA). PCoA and PerMANOVA were performed using a Bray Curtis similarity distance matrix (Anderson, 2001). We also used a Multivariate Dispersion Permutation Analysis (PERMDISP) (Anderson, 2006) to look for differences in group’s heterogeneity. Prior to these analyses, we standardized our data set to species abundance/1,000 trap nights when our sampling effort differed between impacted and nonimpacted sites. PerMANOVA and PERMDISP were performed using the vegan package (Oksanen et al., 2015). Finally, to verify if the dissimilarity (β-diversity) between impacted and nonimpacted was driven by species substitution (turnover) or loss of species (nestedness), we calculated β-diversity using the Jaccard presence–absence coefficient. If multiple-site β-diversity calculations based on Jaccard coefficient were sensitive to sample size, we calculated β-diversity values for all sites using a resampling procedure. We took 999 random samples from each site to have comparable measures of turnover and nestedness components. This analysis was performed using Betapart package (Baselga & Orme, 2012).

Conservation Implications

The sustainable exploitation of natural resources within of Brazilian National Forests is permitted by law (Brazil, 2000). However, this study has shown that there are deleterious effects of biodiversity in areas adjacent to mining within the boundaries of the STNF. In this context, we emphasize that for the conservation of tropical forests, it is necessary to analyze and rethink land use concessions, especially within PAs such as National Forests, the main objective of which is to protect biodiversity against the devastating anthropic processes that are largely neglected by Brazilian environmental policy. Currently, PAs in Brazil face major problems with a misguided policy, a consequence of aggressive economic development that puts at risk the delicate functionalities in the different existing PA’s categories, weakening them. Bills for further opening, reduction, and even elimination of PAs for future mining operations are lacking in planning to mitigate any damage and have problematic consequences that disrupt the Amazon biome (De Marques & Peres, 2015; Ferreira et al., 2014; W. F. Laurance et al., 2001). Contrary to what happens with Brazilian environmental policy, it is necessary to strengthen PAs to reduce environmental changes, which are fundamental to both conservation of the world’s largest tropical forest and human well-being.