Abstract
Environmental pollution caused by the disposal of chemicals or toxins into the environment represent a great threat to amphibians. In this study, it was evaluated which environmental factors of ponds under the influence of coal-mining influence the composition of anuran species. For this purpose, anuran samples were performed in ponds in coal extraction areas in southern Brazil. Physical and chemical characteristics of water, sediment and structural characteristics of the ponds were determined. The content of copper in the sediments of the ponds was the main variable to explain the composition of pond species. Besides copper, it is evident the relevance of number of vegetation strata at pond border and pond area on the composition of anurans. It is shown that the composition of species in ponds under the influence of mineral coal mining activity may be a result of historical perturbations, remaining only the most tolerant towards colonization. From the results obtained in this work it can be suggested that there is a synergistic interaction between environmental factors and the coal mining effects on the anurans fauna of impacted ponds. Thus, efforts should be directed to elucidate the effects of pollutants exposure levels on the species, the understanding of sub-lethal and lethal effects of each pollutant on each species, as well as how local populations can be maintained through recruiting rates of larvae and anurans of the impacted ponds.
Similar content being viewed by others
Explore related subjects
Discover the latest articles, news and stories from top researchers in related subjects.Avoid common mistakes on your manuscript.
Introduction
Environmental changes caused by anthropic actions are considered huge threats to world biodiversity (Ceballos et al. 2015). Based on fossil records and indexes of species extinction, theoretical models have pointed anthropogenic rates as high as one thousand greater than natural rates (de Vos et al. 2014), with losses in the range of 11,000–58,000 species per year (Dirzo et al. 2014). These biodiversity changes may generate dramatic impacts on the stability and functioning of ecosystems (Wang and Loreau 2016) and hence the knowledge of contributing factors by population declines and even extinction comprises one of the greatest ecological challenges (Verdade et al. 2011).
Among vertebrates, amphibians have been the most affected, with probably one-third of all species in the world suffering some extinction degree (Catenazzi 2015). The decline in amphibians and other aquatic vertebrates has been attributed to the presence of heavy metals as a consequence of progressive aquatic ecosystems contamination due to intense agricultural activity and mining (Ficken and Byrne 2013; Hopkins and Rowe 2010). Environmental pollution caused by accidental or deliberate disposal of chemical products or toxins (e.g., heavy metals) is considered a greatest threat to amphibians, with around 20% of all species in the world under such influence (Chanson et al. 2008).
Anurans amphibians are particularly susceptive to impacts caused by heavy metals due to their high permeable skin, allowing fast absorption of metallic ions (Loumbourdis et al. 2007). Though the effects of pollutants on the amphibians are not completely known (Collins and Storfer 2003), some toxicological studies confirm that even low concentrations of heavy metals may be lethal to larvae and adult amphibians (Mahaney 1994; Loumbourdis et al. 1999; Loman and Lardner 2006; Loumbourdis et al. 2007; Barth and Wilson 2010). Besides, some reports suggest that sub-lethal metals concentrations can lead to several deleterious effects on the amphibians, like reduced growth rates, sexual reversion and behavioral changes (Chen et al. 2009; Hayes et al. 2010; Chai et al. 2014; Edge et al. 2014; Babini et al. 2015). The susceptibility of amphibians to lethal and sub-lethal exposure to metals effects may vary depending on the species due to physiological characteristics, habitat demands and reproductive standards (Snodgrass et al. 2004). Thus, it is expected that heavy metals may have an important role in structural and compositional changes of the species in communities of amphibians.
Brazil has the greatest diversity of amphibians of the world, with 1080 species (Segalla et al. 2016), 3.8% (41 species) of them endangered threatened (Ministério Meio Ambiente 2014). Most of endangered species is located in Atlantic forest, which is considered a world biodiversity hotspot (Myers et al. 2000; Mittermeier et al. 2011). The number of endangered amphibians species in the Brazilian Atlantic forest is probably underestimated, as the agropastoral activities, urban/industrial occupation and mining activity have caused a severe reduction in plant cover, down to less than 10% of its original value (Ribeiro et al. 2009). The fast expansion of mining and agricultural activities over the last decades caused severe metal contamination of several aquatic ecosystems of this biome (Schiesari et al. 2007; Zocche et al. 2014). In South Brazil, since the end of XIX century, the extraction and processing of mineral coal led to many sources of acid draining, hence releasing great amount of metals. Residues produced from coal extraction activity are in fact complex mixtures that contain a variety of chemical elements such as hydrocarbons and metals that can cause negative impacts on the ecosystem, especially in the final aquatic receiver environment of such residues (Ferreira et al. 2007; Geremias et al. 2012; Lanctôt et al. 2016).
To the best of our knowledge there are few studies in the Brazilian context regarding the relationship of environmental pollution and amphibians reduction (Verdade et al. 2011), mainly due to the lack of data on the concentration of pollutants in nature, their spatial and temporal variation in natural environments, concentrations for which they may be biologically active and the how long the effects of pollutants may persist in certain species (Schiesari et al. 2007). In particular, no reports were found concerning contamination of heavy metals from coal mining on the amphibians communities in South Brazil. In this sense, this work investigates the environmental characteristics of ponds under the influence of coal mining, describing the anurans species, towards elucidating whether coal mining residues affect the characteristics of water and sediment of pond and which extent it may reflect on the anurans species composition around the pond.
Materials and methods
Study area
The present study was performed in several coal extraction areas located in South Brazil, namely in the cities of Criciúma (28°40′40″S; 49°22′12″W), Siderópolis (28°35′52″S; 49°25′26″W) and Treviso (28°30′57″S; 49°27′28″W). Eight ponds (P1, P2, P3, P4, P5, P6, P7 and P8) distant from each other at least 0.7 km and no more than 23 km were chosen near coal wastes, as shown in Fig. 1.
These ponds are inserted in the Coal Region Cities Association, belonging to Atlantic Forest domain. Currently, due to agropastoral activities, urban and industrial occupation and mineral coal extraction, there is only fragments of Submontane Dense Ombrophylous Forest at different succession stages, surrounded by cattle pasture, waste places of coal extraction and forestry areas of Eucalyptus sp. (IBGE—Instituto Brasileiro de Geografia e Estatística 2012).
The study region suffers from mineral coal exploration since the end of XIX century, with the highest production reached in 1940 decade due to governmental politics directed to the use of coal for steel industry. Today, a much smaller amount of mineral coal is locally produced, now directed to electric power generation. Wastes from mineral coal processing are laid out on the ground surface, which together with unsealed underground openings contribute to acid mine drainages (AMD). A vast territory in this region consists in sterile lands, which resembles to lunar landscape hence exposing to weathering hazardous materials, allowing diffusion of contamination sources (Filho et al. 2014).
Water and sediment sample collect
In order to determine the place of collection of water and sediment samples, the pond perimeter was divided in intervals of 2 m and at each month three intervals were drawn for each pond, in the same day that anurans were sampled. Water samples were carried out using 250 PET flasks, acidified (HNO3, pH < 2) at the collection moment and stored in the fridge (−18 °C). Sediment samples were collected in the same intervals of water sampling, using stainless steel Petersen dredge (180 × 200 mm), stored in plastic bags and kept in a freezer prior to processing. Such process was performed by sieving (62 µm) the sediment samples, drying in oven at 80 °C for 24 h, milling, digestion and read of heavy metals.
Water and sediment analyses
Physico-chemical variables measured in water were: pH, electrical conductivity, turbidity, temperature, dissolved oxygen (DO), arsenic (As), cadmium (Cd), chromium (Cr), copper (Cu), iron (Fe), manganese (Mn) and zinc (Zn). Dissolved oxygen, pH and temperature were measured in the field while the other variables were quantified at the laboratory following Public and Association—APHA (1998). For the analysis of heavy metals content, water samples was filtered using cellulose nitrate filters of 0.45 mm (Sartorius®), acidified with HNO3 and analyzed in the atomic absorption spectrophotometer (AANALYST 800 AAS—Perkin Elmer precisely®), air-acetylene method and/or graphite oven. Analytical curves were built using AA Test Mix Standard Perkin Elmer and all analyses were performed in triplicate.
The content of the following metals were determined in the sediment ponds: Cd, Cr, Cu, Fe, Mn and Zn. Analysis of metals in the sediments were carried out according to USEPA (1996). Briefly, three sediment samples (0.5 g) were weighed and homogenized and transferred to flasks for digestion. Afterwards, 5 mL of nitric acid and 5 mL of ultrapure water was added, heating in reflux to 95 ± 5 °C for 15 min. After sample cooling, it was added 5 mL of HNO3 leaving reacting for 30 min. Then, samples were heated again for 2 h (95 ± 5 °C) and after cooling at room temperature, 2 mL of ultra-pure water and 3 mL of H2O2 (30%) were added and wait reacting at natural boiling. Aliquots of 1 mL of H2O2 30% (no more than 10 mL) were added up to boiling was not observed. Afterwards, samples were heated for 4 h at 140 ± 5 °C and after cooling the whole content was diluted in 50 mL ultrapure water, filtered (0.45 µm cellulose nitrate filter), adding 10 mL of hydrochloric acid (HCl) and again heated (95 ± 5 °C) for 15 min. After digestion completion, spectrophotometer readings were performed in the atomic absorption.
Structural characteristics of ponds
For ponds characterization, the following structural characteristic parameters were taken into account: (i) pond area; (ii) minimum distance between pond and coal waste disposal; (iii) number of vegetation types at pond border: herbaceous; arboreal and shrub, where 1 = only one type; 2 = two types, 3 = three types; (iv) plant cover at water surface: 0–24; 25–49; >50%; (v) pond border profile: flat, downhill and ravine, where 1 = only one profile; 2 = two profiles; 3 = three border profiles (Table 1), adapted from Silva et al. (2011). In addition, atmospheric temperature and relative humidity were recorded at the beginning and at the end of each sampling.
Anurans samples
The collection of biological samples was performed from October 2012 to February 2013, period of major reproductive activity of anurans species in South Brazil (Colombo et al. 2008; Both et al. 2009; Bastiani and Lucas 2013). Samples were taken monthly from ponds, with three consecutive nights per month. For species registering of adult anurans, it was adopted hearing and visual observation in reproductive sites (Heyer et al. 1994), from 19 to 00 h. Three ponds were randomly sampled per night, which means that each pond was approached in approximately 1 h and half five times, totalizing 7 h and half for each pond. The abundance of anurans in each pond was estimated from the number of males in vocalization activity and for this purpose, ponds perimeter plus 5 m distance was approached slowly.
Towards taxonomic identification and maintenance of witness material, ten specimens for each species were collected in each sampled pond, being afterwards deposited at Amphibians Collection of Universidade Comunitária da Região de Chapecó (License Number SISBIO No. 35547-1), which is in accordance with Darrel Frost (2016).
Data analysis
To avoid population overestimation, due to recounting of species of different samples in the same site, the maximum abundance of male in active vocalization registered in the sampling period (Conte and Rossa-Feres 2006). The analysis of variance (ANOVA) was performed in order to check possible variations in anurans richness and abundance in each pond. When difference was detected, the Tukey posteriori HSD (Zar 1999) test was applied to identify which pairs differed. The same statistical test was also used to detect differences among variables of pond water and sediment.
To determine the variation of anurans species in the different sampled ponds, a biological matrix was built using the Bray–Curtis index from abundance data. Such matrix was employed to rank the composition variation of anuran species of the ponds through non-metrical multidimensional scaling (NMDS). The relationship between biological and environmental dissimilarity matrices was evaluated using BioEnv analysis (Clarke and Ainsworth 1993). Such analysis makes use of the Mantel test to correlate the biological dissimilarity matrix and a second matrix of environmental variables. Thus, in the BioEnv analysis an environmental dissimilarity matrix is constructed based on different number and combinations of environmental variables. The biological dissimilarity matrix is first correlated to an environmental matrix obtained from a single variable. Then, the analysis uses of a second environmental matrix, but now obtained from two variables, where the highest correlation is indicated. This procedure is repeated with three, four or even more environmental variables up to the total amount of variables have been considered. The combination that leads to the best correlation is selected, in the present work the Spearman coefficient was used to compute the correlation between matrices. The dissimilarity environmental matrix was calculated using Euclidian distances of environmental variables standardized by their standard deviations. The environmental variables used in the BioEnv analysis were: pond area (A), minimum distance between pond and coal waste disposal (D), margin profile (MP), number of vegetation strata in the margin (VSM), percentage of vegetation cover on the water surface (PVC), pH, electrical conductivity, turbidity, temperature, dissolved oxygen (DO), metals in water (As, Cd, Cr, Cu, Fe, Mn and Zn) and in the sediment (Cd, Cr, Cu, Fe, Mn and Zn), atmospheric temperature (ta) and relative air humidity (Rh).
Results
The values of physical and chemical water variables are presented in Table 2. As can be seen from this table, the water pH, dissolved oxygen, electrical conductivity and turbidity differed among ponds: pH: F(7.32) = 48.82; P < 0.0001; OD: F(7.32) = 12.09; P < 0.0001; electrical conductivity: F(7.32) = 13.80; P < 0.0001; turbidity: F(7.32) = 2.84; P = 0.0201). Nevertheless, no difference was found regarding temperature (F(7.32) = 1.58; P = 0.1774) and the concentration of heavy metals in water. In the sediment, copper concentration was different among ponds (F(7.32) = 4.47; P < 0.01), but for cadmium (F(7.32) = 0.17; P > 0.05), chrome (F(7.32) = 0.80; P > 0.05), iron (F(7.32) = 1.40; P > 0.05), manganese (F(7.32) = 2.01; P > 0.05) and zinc (F(7.32) = 2.18; P > 0.05) no significant differences were detected.
Seventeen anuran species were registered, distributed into six families (Table 3). There was difference in anurans richness among ponds, being 16 the highest and 1 the smallest registered (F(7.32) = 18.231; P < 0.0001). Ponds 1, 2, 5, 7 and 8 showed the greatest richness compared to ponds 3 and 6, whereas pond 4 did not present difference from the others (Fig. 1). Male abundance under vocalization activity differed significantly among ponds (F(7.32) = 9.68; P < 0.01), with the highest found of 190 individuals registered pond 5. Abundance of anurans in pond 5 was higher than those found in ponds 3, 4, 6, 7 and 8, but did not differ from ponds 1 and 2. Ponds 3 and 6 presented the smallest abundance of anurans with regard to ponds 1, 2, 7 and 8, as shown in Fig. 2.
The NMDS was efficient to reduce the dimension of experimental data (stress 0.07) (Fig. 3). Ponds 3, 4 and 6 received the highest values in the first classification axis, while ponds 3 and 6 showed the lowest richness and abundance registered for all ponds.
The best correlation was reached for the dissimilarity matrix that employed two environmental variables: number of vegetation strata and copper in the sediment (r = 0.6065, see Table 4). Another model comprising the number of vegetation strata, copper in the sediment and also pond area produced a similar correlation, r = 0.5977, while the model using only the number of vegetation strata led to a poor correlation, r = 0.4750, thus indicating that copper in the sediment was relevant (Table 4). Ponds with the highest NMDS scores were those which showed reduced composition of species, i.e., pond with high copper concentration (pond 3) and pond with reduced number of vegetation strata (pond 6) presented low abundance and richness.
Discussion
In this investigation, water of ponds under the influence of coal mining activity presented differences regarding pH, dissolved oxygen, electrical conductivity and turbidity. On the other hand, pond sediment showed effect only for copper and the content of copper in the pond sediments was the main variable to explain the composition of anurans species in the ponds. Besides copper, it is evident the relevance of number of vegetation strata at pond border and pond area on the composition of anurans.
Some anuran species may be more pollutant tolerant than others (Snodgrass et al. 2008), but no ecotoxicological studies are available for most of the species registered in this study. Alone, the presence/absence of the species in the ponds does not confirm this tolerance to the pollutants. Indeed, all registered species have reproductive mode associated with water and the tadpole development is aquatic (Haddad et al. 2013). Even the most abundant species (Scinax tymbamirim) recorded in 75% of the studied ponds, presented few or none individuals in the ponds with the highest levels of copper.
Copper is a chemical element recognized for bioaccumulation at different levels in the biota (Vinot and Pihan 2005; Peltier et al. 2009; Soto et al. 2011), including amphibians (Unrine et al. 2007; Taiwo et al. 2014). Zocche et al. (2014), investigating the amount of metals in amphibian Hypsiboas faber tissue, collected in mineral coal areas, showed that copper was the second most abundant metal in the amphibian tissue. Here, copper affected negatively the composition of anurans, as the highest concentrations of such metal was found in ponds with the lowest abundances. Indeed, copper was also pointed as one of the main factors affecting the anurans community in areas under agriculture influence in Australia (Ficken and Byrne 2013).
Several negative and sub-lethal effects in amphibians were associated to copper exposure (Lance et al. 2013; Wang et al. 2016). For example, the toad larvae of Bufo gargarizans exposed to different concentration of copper showed clear increased mortality, inhibition of brooding development and delay in the metamorphosis process (Wang et al. 2016). Lance et al. (2013) evaluated the chronical effect of copper on the larvae and the toad embryos of Anaxyrus terrestris and concluded that spawns exposed to copper showed reduced survival. In the same way, the toad species Lithobates sphanocephalus presented low number of survival larvae when exposed to copper (Lance et al. 2012). Sub lethal effects of copper may vary and be species-specific, with different impact on the recruiting rates and lead to a decrease in the local population. In this sense, more toxicological studies are needed to better understand and detect possible lethal and sub-lethal effect patterns caused by heavy metals, including copper, in the different development stages of anurans exposed to these contaminants, as is the case of mineral coal mining areas in Brazil.
Furthermore, this work demonstrated that the composition of anurans species was affected by the number of vegetation strata and pond size. The relationship between community structure and species tolerance and the biotic/abiotic factors suggests that the niche can overlap in the multidimensional space, limiting the species coexistence inside a community (Ricklefs and Schluter 1995). Relationship between structural characteristics of the environment and its use by anurans has been a matter of intense investigation over decades (Campos and Vaz-Silva 2010; De Fonseca and Jocqué 1982; Prado and Pombal 2005), thus strengthening the hypothesis that species composition depends on the vegetation structure (Peltzer et al. 2006; Vasconcelos et al. 2009) and on the size of reproduction sites (e.g., Iop et al. 2012). Thus, the influence of vegetation and pond area on the composition of species may be related to the availability of sources such as shelter, reproductive sites and food availability. Larger ponds with a greater number of micro-inhabitants will possibly offer better conditions to be colonized (da Silva et al. 2012; Iop et al. 2012) thus showing a greater abundance. On the other hand, other factors like competition and predation can also exert influence on the community structure (Kraus 2015; Anderson and Semlitsch 2016). Yet, there is no consensus on how synergistic effects occur between different factors, since an isolated factor could act distinctly in different communities (Vasconcelos et al. 2009).
The fact that different heavy metals can lead to a variety of effects, in different degree, on the anurans fauna is well documented in some experiments (Loumbourdis et al. 1999, 2007; Brown et al. 2012; Lance et al. 2012; Dal-Medico et al. 2014; Wang et al. 2016) but it seems difficult to prove it in natural environment due to the very complex interactions existing. The composition of species in ponds under the influence of mineral coal mining activity may be a result of historical perturbations, remaining only the most tolerant towards colonization. There is a trend in biological communities to become more homogeneous in response to one or various stress agents (Petsch 2016). From the results obtained in this work it can be suggested that there is a synergistic interaction between factors and the coal mining effects on the anurans fauna of impacted ponds, which will be realized in a near future. Thus, efforts should be directed to elucidate the effects of pollutants exposure levels on the species, the understanding of sub-lethal and lethal effects of each pollutant on each species, as well as how local populations can be maintained through recruiting rates of larvae and anurans of the impacted ponds.
Conclusions
It was observed in this work that there is an influence of the coal mining activity on the physical and chemical characteristics of the ponds, which exert effects on the anuran community structure. In this way, we suggest long-term monitoring, considering individual species characteristics to understand the complexity of interactions and possible synergistic effects on species.
References
American Public Health Association (1998) APHA: standard methods for the examination of water and wastewater.
Anderson TL, Semlitsch RD (2016) Top predators and habitat complexity alter an intraguild predation module in pond communities. J Anim Ecol 85:548–558. doi:10.1111/1365-2656.12462
Babini MS, de Bionda CL, Salas NE, Martino AL (2015) Health status of tadpoles and metamorphs of Rhinella arenarum (Anura, Bufonidae) that inhabit agroecosystems and its implications for land use. Ecotoxicol Environ Saf 118:118–125. doi:10.1016/j.ecoenv.2015.04.017
Barth BJ, Wilson RS (2010) Life in acid: interactive effects of pH and natural organic acids on growth, development and locomotor performance of larval striped marsh frogs (Limnodynastes peronii). J Exp Biol 213:1293–1300. doi:10.1242/jeb.028472
Both C, Solé M, Dos Santos TG, Cechin SZ (2009) The role of spatial and temporal descriptors for neotropical tadpole communities in southern Brazil. Hydrobiologia 624:125–138. doi:10.1007/s10750-008-9685-5
Brown MG, Dobbs EK, Snodgrass JW, Ownby DR (2012) Ameliorative effects of sodium chloride on acute copper toxicity among Cope’s gray tree frog (Hyla chrysoscelis) and green frog (Rana clamitans) embryos. Environ Toxicol Chem 31:836–842. doi:10.1002/etc.1751
Campos F, Vaz-Silva W (2010) Distribuição espacial e temporal da anurofauna em diferentes ambientes no município de Hidrolândia, GO, Brasil Central. Neotrop Biol Conserv 5:179–187. doi:10.4013/nbc.2010.53.07
Catenazzi A (2015) State of the World’s Amphibians. Annu Rev Environ Resour 40:91–119. doi:10.1146/annurev-environ-102014-021358
Ceballos G, Ehrlich PR, Barnosky AD, García A, Pringle RM, Palmer TM (2015) Accelerated modern human-induced species losses: entering the sixth mass extinction. Sci Adv 1:1–5. doi:10.1126/sciadv.1400253
Chai L, Wang H, Deng H, Zhao H, Wang W (2014) Chronic exposure effects of copper on growth, metamorphosis and thyroid gland, liver health in Chinese toad, Bufo gargarizans tadpoles. Chem Ecol 30:589–601. doi:10.1080/02757540.2014.894985
Chanson JS, Hoffman M, Cox N, Stuart SN (2008) The state of the world’s amphibians. Threatened amphibians of the world. IUCN, Conservation International, Barcelona, pp 34–52
Chen TH, Gross JA, Karasov WH (2009) Chronic exposure to pentavalent arsenic of larval leopard frogs (Rana pipiens): bioaccumulation and reduced swimming performance. Ecotoxicology 18:587–593. doi:10.1007/s10646-009-0316-3
Clarke KR, Ainsworth M (1993) A method linking multi- variate community structure to environmental variables. Mar Ecol Prog 92:205–212
Collins JP, Storfer A (2003) Global amphibian declines: sorting the hypotheses. Divers Distrib 9:89–98
Colombo P, Kindel A, Vinciprova G, Krause L (2008) Composição e ameaças à conservação dos anfíbios anuros do Parque Estadual de Itapeva, município de Torres, Rio Grande do Sul, Brasil. Biota Neotrop 8:229–240. doi:10.1590/S1676-06032008000300020
Conte CE, Rossa-Feres DC (2006) Diversidade e ocorrência temporal da anurofauna (Amphibia, Anura) em São José dos Pinhais, Paraná, Brasil. Rev Bras Zool 23:162–175. doi:10.1590/S0101-81752006000100008
Da Silva FR, Candeira CP, Rossa-Feres DC (2012) Dependence of anuran diversity on environmental descriptors in farmland ponds. Biodivers Conserv 21:1411–1424. doi:10.1007/s10531-012-0252-z
Dal-Medico SE, Rissoli RZ, Gamero FU, Victório JA, Salla RF, Abdalla FC, Silva-Zacarin EC, Carvalho CS, Costa MJ (2014) Negative impact of a cadmium concentration considered environmentally safe in Brazil on the cardiac performance of bullfrog tadpoles. Ecotoxicol Environ Saf 104:168–174. doi:10.1016/j.ecoenv.2014.03.003
De Bastiani VIM, Lucas EM (2013) Anuran diversity (Amphibia, Anura) in a seasonal forest fragment in southern Brazil. Biota Neotrop 13:255–264. doi:10.1590/S1676-06032013000100025
de Fonseca PH, Jocqué R (1982) The palmate newt triturus helveticus helveticus (Raz.) in flanders (Belgium). Distribution and habitat preferences. Biol Conserv 23:297–307. doi:10.1016/0006-3207(82)90086-6
de Vos JM, Hughes CE, Schneeweiss GM, Moore BR, Conti E (2014) Heterostyly accelerates diversification via reduced extinction in primroses. Proc R Soc B 281:1–9. doi:10.1098/rspb.2014.0075
Dirzo R, Young HS, Galetti G, Ceballos G, Isaac NJB, Collen B (2014) Defaunation in the Anthropocene. Science 345(6195):401–406. doi:10.1126/science.1251817
Edge C, Thompson D, Hao C, Houlahan J (2014) The response of amphibian larvae to exposure to a glyphosate-based herbicide (Roundup WeatherMax) and nutrient enrichment in an ecosystem experiment. Ecotoxicol Environ Saf 109:124–132. doi:10.1016/j.ecoenv.2014.07.040
Ferreira RB, Monteiro S, Freitas R, Santos CN, Chen Z, Batista LM, Duarte J, Borges A, Teixeira AR (2007) The role of plant defence proteins in fungal pathogenesis. Mol Plant Pathol 8:677–700
Ficken KLG, Byrne PG (2013) Heavy metal pollution negatively correlates with anuran species richness and distribution in south-eastern Australia. Aust Ecol 38:523–533. doi:10.1111/j.1442-9993.2012.02443.x
Filho LCIO, Baretta D, Santos JCP (2014) Influência dos processos de recuperação do solo após mineração de carvão sobre a mesofauna edáfica em Lauro Müller, Santa Catarina, Brasil. Biotemas 27:69–77. doi:10.5007/2175-7925.2014v27n2p69
Frost D (2016) Amphibian species of the world: an online reference. Version 6.0. In: American Museum of Natural History. http://research.amnh.org/herpetology/amphibia/index.html.
Geremias R, Bortolotto T, Wilhelm-Filho D, Pedrosa RC, de Fávere VT (2012) Efficacy assessment of acid mine drainage treatment with coal mining waste using Allium cepa L. as a bioindicator. Ecotoxicol Environ Saf 79:116–121. doi:10.1016/j.ecoenv.2011.12.010
Haddad CF, Toledo LF, Prado CPA, Loebmann D, Gasparini JL, Sazima I (2013) Guia dos Anfíbios da Mata Atlântica: diversidade e biologia. Anolis Books, São Paulo
Hayes TB, Khoury V, Narayan A, Nazir M, Park A, Brown T, Adame L, Chan E, Buchholz D, Stueve T, Gallipeau S (2010) Atrazine induces complete feminization and chemical castration in male African clawed frogs (Xenopus laevis). Proc Natl Acad Sci 107:4612–4617. doi:10.1073/pnas.0909519107
Heyer WR, Donnelly MA, McDiarmid RW, Hayek LAC, Foster MS (1994) Measuring and monitoring biological diversity: standard methods for amphibians. Smithsonian, Washington, DC
Hopkins WA, Rowe CL (2010) 11 Interdisciplinary and hierarchical approaches for studying the effects of metals and metalloids on amphibians. In: Sparling DW, Linder G, Bischop CA, Krest SK (eds) Ecotoxicology of amphibians and reptiles, 2nd edn. Wiley, New York, p 325
IBGE—Instituto Brasileiro de Geografia e Estatística (2012) Manual Técnico da Vegetação Brasileira. 2a edição revista e ampliada. Sistema Fitogeográfico. Inventário das Formações Florestais e Campestres. Técnicas e Manejo de Coleções Botânicas. Procedimentos para Mapeamentos.
Iop S, Caldart VM, Dos Santos TG, Cechin SZ (2012) What is the role of heterogeneity and spatial autocorrelation of ponds in the organization of frog communities in southern Brazil? Zool Stud 51:1094–1104
Kraus F (2015) Impacts from invasive reptiles and amphibians. Annu Rev Ecol Evol Syst 46:75–97. doi:10.1146/annurev-ecolsys-112414-054450
Lance SL, Erickson MR, Flynn RW, Mills GL, Tuberville TD, Scott DE (2012) Effects of chronic copper exposure on development and survival in the southern leopard frog (Lithobates [Rana] sphenocephalus). Environ Toxicol Chem 31:1587–1594. doi:10.1002/etc.1849
Lance SL, Flynn RW, Erickson MR, Scott DE (2013) Within- and among-population level differences in response to chronic copper exposure in southern toads, Anaxyrus terrestris. Environ Pollut 177:135–142. doi:10.1016/j.envpol.2013.02.009
Lanctôt C, Wilson SP, Fabbro L, Leusch FD, Melvin SD (2016) Comparative sensitivity of aquatic invertebrate and vertebrate species to wastewater from an operational coal mine in central Queensland, Australia. Ecotoxicol Environ Saf 129:1–9. doi:10.1016/j.ecoenv.2016.03.003
Loman J, Lardner B (2006) Does pond quality limit frogs Rana arvalis and Rana temporaria in agricultural landscapes? A field experiment. J Appl Ecol 43:690–700. doi:10.1111/j.1365-2664.2006.01172.x
Loumbourdis NS, Kostaropoulos I, Theodoropoulou B, Kalmanti D (2007) Heavy metal accumulation and metallothionein concentration in the frog Rana ridibunda after exposure to chromium or a mixture of chromium and cadmium. Environ Pollut 145:787–792. doi:10.1016/j.envpol.2006.05.011
Loumbourdis NS, Kyriakopoulou-Sklavounou P, Zachariadis G (1999) Effects of cadmium exposure on bioaccumulation and larval growth in the frog Rana ridibunda. Environ Pollut 104:429–433. doi:10.1016/S0269-7491(98)00172-9
Mahaney PA (1994) Effects of freshwater petroleum contamination on amphibian hatching and metamorphosis. Environ Toxicol Chem 13:259–265. doi:10.1002/etc.5620130210
Ministério Meio Ambiente (2014) Portaria MMA No 444, de 17 de Dezembro de 2014. Portaria 53:1689–1699
Mittermeier RA, Turner WR, Larsen FW, Brooks TM, Gascon C (2011) Global biodiversity conservation: the critical role of hotspots. In: Zachos FE, Habel JC (eds) Biodiversity hotspots: distribution and protection of conservation priority areas. Springer, Berlin, pp 3–22
Myers N, Mittermeier RA, Mittermeier CG, da Fonseca GAB, Kent J (2000) Biodiversity hotspots for conservation priorities. Nature 403:853–858. doi:10.1038/35002501
Peltier GL, Wright MS, Hopkins WA, Meyer JL (2009) Accumulation of trace elements and growth responses in Corbicula fluminea downstream of a coal-fired power plant. Ecotoxicol Environ Saf 72:1384–1391. doi:10.1016/j.ecoenv.2009.01.011
Peltzer PM, Lajmanovich RC, Attademo AM, Beltzer AH (2006) Diversity of anurans across agricultural ponds in Argentina. Biodivers Conserv 15:3499–3513. doi:10.1007/s10531-004-2940-9
Petsch DK (2016) Causes and consequences of biotic homogenization in freshwater ecosystems. Int Rev Hydrobiol 101:113–122. doi:10.1002/iroh.201601850
Prado GM, Pombal JP (2005) Distribuição espacial e temporal dos anuros em um brejo da Reserva Biológica de Dua Bocas, Sudeste do Brasil. Arquivos do Museu Nacional 6:685–705. doi:10.1590/S0101-81752000000100023
Ribeiro MC, Metzger JP, Martensen AC, Ponzoni FJ, Hirota MM (2009) The Brazilian Atlantic Forest: how much is left, and how is the remaining forest distributed? Implications for conservation. Biol Conserv 142:1141–1153. doi:10.1016/j.biocon.2009.02.021
Ricklefs RE, Schluter D (1995) Species diversity in ecological communities: historical and geographical perspectives. Madrono 42:523–528. doi:10.1046/j.1420-9101.1994.7050635.x
Schiesari L, Grillitsch B, Grillitsch H (2007) Biogeographic biases in research and their consequences for linking amphibian declines to pollution. Conserv Biol 21:465–471. doi:10.1111/j.1523-1739.2006.00616.x
Segalla MV, Caramaschi U, Cruz CAG, Grant T, Garcia PCA, Berneck BVM, Langone JA (2016) Brazilian amphibians—list of species. Soc Bras Herpetol 5:34–46
Silva RA, Martins IA, Rossa-Feres DC (2011) Environmental heterogeneity: anuran diversity in homogeneous environments. Zoologia (Curitiba) 28:610–618. doi:10.1590/S1984-46702011000500009
Snodgrass JW, Hopkins WA, Broughton J, Gwinn D, Baionno JA, Burger J (2004) Species-specific responses of developing anurans to coal combustion wastes. Aquat Toxicol 66:171–182. doi:10.1016/j.aquatox.2003.09.002
Snodgrass JW, Casey RE, Joseph D, Simon JA (2008) Microcosm investigations of stormwater pond sediment toxicity to embrionic and larval amphibians: variation in sensitivity among species. Environ Pollut 154:291–297. doi:10.1016/j.envpol.2007.10.003
Soto DX, Roig R, Gacia E, Catalan J (2011) Differential accumulation of mercury and other trace metals in the food web components of a reservoir impacted by a chlor-alkali plant (Flix, Ebro River, Spain): Implications for biomonitoring. Environ Pollut 159:1481–1489. doi:10.1016/j.envpol.2011.03.017
Taiwo IE, Henry AN, Imbufe AP (2014) Heavy metal bioaccumulation and biomarkers of oxidative stress in the wild African tiger frog, Hoplobatrachus occipitalis. Afr J Environ Sci Technol 8:6–15. doi:10.5897/AJEST2013
Unrine JM, Hopkins WA, Romanek CS, Jackson BP (2007) Bioaccumulation of trace elements in omnivorous amphibian larvae: implications for amphibian health and contaminant transport. Environ Pollut 149:182–192. doi:10.1016/j.envpol.2007.01.039
USEPA - US Environmental Protection Agency (1996) Soil screening guidance: technical background document. USEPA Rep. 540/R-95/128. US Gov. Print. Office, Washington, DC
Vasconcelos TS, Santos TG, Rossa-Feres DC, Haddad CFB (2009) Influence of the environmental heterogeneity of breeding ponds on anuran assemblages from southeastern Brazil. Can J Zool 87:699–707. doi:10.1139/Z09-058
Verdade, VK, Carnaval AC, Rodrigues MT, Schiesari L, Pavan D, Bertoluci J (2011) Decline of amphibians in Brazil
Vinot I, Pihan JC (2005) Circulation of copper in the biotic compartments of a freshwater dammed reservoir. Environ Pollut 133:169–182. doi:10.1016/j.envpol.2004.03.002
Wang C, Liang G, Chai L, Wang H (2016) Effects of copper on growth, metamorphosis and endocrine disruption of Bufo gargarizans larvae. Aquat Toxicol 170:24–30. doi:10.1016/j.aquatox.2015.10.023
Wang S, Loreau M (2016) Biodiversity and ecosystem stability across scales in metacommunities. Ecol Lett 19:510–518
Zar J (1999) Biostatistical analysis. Princeton-Hall, New Jersey
Zocche JJ, Da Silva LA, Damiani AP, Mendonça RA, Peres PB, dos Santos CE, Debastiani R, Dias JF, de Andrade VM, Pinho RA (2014) Heavy-metal content and oxidative damage in Hypsiboas faber: the impact of coal-mining pollutants on amphibians. Arch Environ Contam Toxicol 66:69–77. doi:10.1007/s00244-013-9949-6
Acknowledgements
This study was funded by Fundação O Boticário de Proteção à Natureza through the Project 0929_20121. The authors thank CNPq, CAPES, FAPESC/SC and MCTI-FINEP for financial support and scholarships. The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.
Author information
Authors and Affiliations
Corresponding author
Ethics declarations
Conflict of interest
The authors declare that they have no conflict of interest.
Rights and permissions
About this article
Cite this article
De Lucca, G.S., Barros, F.A.P., Oliveira, J.V. et al. The role of environmental factors in the composition of anuran species in several ponds under the influence of coal mining in southern Brazil. Wetlands Ecol Manage 26, 285–297 (2018). https://doi.org/10.1007/s11273-017-9573-8
Received:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s11273-017-9573-8