Dry season limnological conditions and basin geology exhibit complex relationships with δ13C and δ15N of carbon sources in four Neotropical floodplains

Gustavo H. Zaia Alves; David J. Hoeinghaus; Gislaine I. Manetta; Evanilde Benedito

doi:10.1371/journal.pone.0174499

Abstract

Studies in freshwater ecosystems are seeking to improve understanding of carbon flow in food webs and stable isotopes have been influential in this work. However, variation in isotopic values of basal production sources could either be an asset or a hindrance depending on study objectives. We assessed the potential for basin geology and local limnological conditions to predict stable carbon and nitrogen isotope values of six carbon sources at multiple locations in four Neotropical floodplain ecosystems (Paraná, Pantanal, Araguaia, and Amazon). Limnological conditions exhibited greater variation within than among systems. δ¹⁵N differed among basins for most carbon sources, but δ¹³C did not (though high within-basin variability for periphyton, phytoplankton and particulate organic carbon was observed). Although δ¹³C and δ¹⁵N values exhibited significant correlations with some limnological factors within and among basins, those relationships differed among carbon sources. Regression trees for both carbon and nitrogen isotopes for all sources depicted complex and in some cases nested relationships, and only very limited similarity was observed among trees for different carbon sources. Although limnological conditions predicted variation in isotope values of carbon sources, we suggest the resulting models were too complex to enable mathematical corrections of source isotope values among sites based on these parameters. The importance of local conditions in determining variation in source isotope values suggest that isotopes may be useful for examining habitat use, dispersal and patch dynamics within heterogeneous floodplain ecosystems, but spatial variability in isotope values needs to be explicitly considered when testing ecosystem models of carbon flow in these systems.

Citation: Zaia Alves GH, Hoeinghaus DJ, Manetta GI, Benedito E (2017) Dry season limnological conditions and basin geology exhibit complex relationships with δ¹³C and δ¹⁵N of carbon sources in four Neotropical floodplains. PLoS ONE 12(3): e0174499. https://doi.org/10.1371/journal.pone.0174499

Editor: Hideyuki Doi, University of Hyogo, JAPAN

Received: December 21, 2016; Accepted: March 10, 2017; Published: March 30, 2017

This is an open access article, free of all copyright, and may be freely reproduced, distributed, transmitted, modified, built upon, or otherwise used by anyone for any lawful purpose. The work is made available under the Creative Commons CC0 public domain dedication.

Data Availability: All relevant data are within the paper and its Supporting Information files.

Funding: This study was funded by the Brazilian National Council of Technological and Scientific Development – CNPq/SISBIOTA (grant #503243/2010-4) and CAPES. The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.

Competing interests: The authors have declared that no competing interests exist.

Introduction

Recent studies in freshwater ecosystems are seeking to improve understanding of carbon flow in food webs by testing general conceptual models such as the River Continuum Concept (RCC; [1]), Flood Pulse Concept (FPC; [2]), Riverine Productivity Model (RPM; [3]), Riverine Ecosystem Synthesis [4] and River Wave Concept (RWC; [5]). Stable isotopes, particularly of carbon and nitrogen, have been influential in this work as natural tracers of energy sources and trophic interactions [6–14]. One major issue with testing the aforementioned models using stable isotope analyses (SIA) is the ability of the isotopes to reliably distinguish among potential autotrophic carbon sources and/or size fractions within and among ecosystems. This is often complicated by the diverse suite of potential carbon sources (both autochthonous and allocthonous) in freshwater ecosystems, and the spatially and temporally dynamic nature of carbon source relative abundances (e.g. [15–18]).

In freshwater ecosystems, the substrate for autochthonous photosynthesis is dissolved carbon dioxide or bicarbonate (grouped as dissolved inorganic carbon—DIC). The dominant form of DIC present in aquatic ecosystems is determined largely by pH [19, 20] which also influences the ratio of heavy to light isotopes of carbon (δ¹³C) of the DIC [21]. The δ¹³C of the DIC can also be affected by salinity or nutrient limitation [22, 23], pressure of CO₂ as a result of terrestrial respiration of organic material [24], ecosystem area and metabolism [21, 25], lithology and hydrology [26], and basin geochemistry [27]. Subsequently, the factors that determine the δ¹³C of aquatic primary producers are complex because of the influences of spatial heterogeneity at multiple scales, such as local habitat, reach, watershed, hydrology and geochemistry [7, 14, 28]. Opposite to strictly aquatic primary producers (i.e. algae, periphyton), macrophytes and riparian plants utilize atmospheric CO₂ as the photosynthetic substrate, which they assimilate via leaf stomatal absorption [29]. The δ¹³C values of these plants are mainly influenced by its photosynthetic pathway (i.e. C₃ or C₄; [30]), however, under stressful conditions (i.e. nutrient limitation for macrophytes or water limitation for riparian plants), they can close their stomata, which leads to a lesser enzymatic discrimination against ¹³CO₂ and increasing tissue δ¹³C values [31].

Similarly, δ¹⁵N of basal carbon sources can vary according to many factors, including salinity, basin geochemistry, level of eutrophication and preference for the form of dissolved inorganic nitrogen by plants (NH₄⁺ or NO₃^-; [32–35]). Pollution from urban sewage or agriculture is an important factor affecting δ¹⁵N [36–40], and areas with human wastewater inputs are consistent with high amounts of dissolved inorganic nitrogen and elevated δ¹⁵N in the sediment and organisms [32, 40, 41]. For this reason, nitrogen stable isotope composition is a useful tracer of biogeochemical processes in the water column and of nutrients derived from multiple sources (e.g. animal wastes, septic systems, sewage treatment plants; [40, 42–45]).

Tropical river floodplain ecosystems are well-suited for examining factors affecting stable isotope values of basal carbon sources. Specifically, tropical river floodplains are characterized by high species and functional diversity of carbon sources and consumers, spatial heterogeneity, importance for freshwater biodiversity, and historical use in testing river ecosystem concepts (e.g. [8, 16]). Furthermore, evidence from previous studies in floodplain ecosystems (e.g. [6, 27, 46, 47]) helped to frame the discussion of potential drivers of variability in isotopic values of sources. For example, Jepsen and Winemiller ([47]) found that basin geochemistry (i.e. whitewater vs. blackwater) determined between-river isotopic differences in sources and consumers in tropical rivers of Venezuela, allowing for isotope values to be used as tracers of fish movement between systems [48, 49]. Understanding the factors that affect variability in stable isotope values of sources within and among floodplains is important for tests of the aforementioned river ecosystem concepts. If local limnological conditions distinguish source values within floodplains in a predictable manner, those differences may 1) yield a spatially and seasonally relevant isotopic landscape or “isoscape” enabling stable isotopes to be used as tracers of organism movement among patches within floodplains (e.g. Brosi et al. ([50]) for bees in a fragmented tropical landscape, and Fry et al. ([51]) for fishes moving from marshes to offshore in a freshwater Florida lake), or 2) be used to align baseline values for comparisons within and among systems in a manner analogous to lipid normalization models that correct for lipid concentration effects on isotope values in consumer tissues (e.g. [52, 53]).

In this study, we quantified local limnological conditions and assessed variation in stable carbon and nitrogen isotope values of carbon sources at multiple locations in four Neotropical floodplain river systems. Six carbon sources are analyzed, but we primarily focus on periphyton, phytoplankton and particulate organic carbon as stable isotope ratios of those sources are expected to reflect effects of limnological conditions over a timescale (i.e. hours to days) more suitable for comparison with our field surveys. The Paraná, Pantanal, Araguaia and Amazon, study systems capture continental-scale differences in geological formations as well as include significant within-basin heterogeneity of local limnological conditions. Using the aforementioned dataset, we ask the following questions: 1) Can geological formation (i.e. basin identity) and local limnological conditions (e.g. pH, turbidity, nutrient concentrations) predict among- and within-floodplain differences in δ¹³C and δ¹⁵N of carbon sources?, and 2) What is the relative importance of geology versus local limnology in determining variation in isotopic values of carbon sources?

Material and methods

Ethics statement

All samples were properly collected with all required permissions from the Brazilian Environmental Ministry (Instituto Chico Mendes de Conservação da Biodiversidade (ICMBio), Sistema de autorização e informação em Biodiversidade (SISBIO)), under protocol number 29652.

Study systems and river classifications

This study was conducted in four Brazilian river-floodplain ecosystems: Upper Paraná River floodplain (Paraná, Baía and Ivinheima rivers), Pantanal floodplain (Paraguai and Miranda rivers), Araguaia River floodplain and Amazon floodplain (Solimões and Amazonas rivers) (Fig 1). All of these systems have regular flooding periods during the rainy season of the Neotropics [2], and support high biodiversity of organisms, including autotrophic carbon sources. Rivers can be generally classified as whitewater, clearwater or blackwater [54], based on conditions in the catchment area that affect water color, load of suspended solids, pH, and load of dissolved minerals. Applied to our study systems, only the Solimões/Amazonas is whitewater [55], and the remainder may be primarily considered clearwater (see descriptions of the ecosystems below). That being said, Sioli’s ([54]) classification of large clearwater rivers includes pH values ranging between 6 and 6.7, and combined with the distribution of clearwater rivers over diverse geological zones, demonstrates that ‘clearwater’ is a chemically (and biologically) heterogeneous classification with only a poorness in suspended particles as a common character [54]. Furthermore, floodplain ecosystems have a wide range of the aforementioned parameters due to their inherent spatial heterogeneity (e.g. among channels and floodplain lakes of various size and connectivity), and not all location environments fit nicely into the same general classification applied at the landscape scale.

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Fig 1. Map of the sampling locations in each basin study system.

(i.e. a = Amazon floodplain; b = Araguaia floodplain; c = Pantanal floodplain; d = Paraná floodplain). Each point in the map represents a lake where carbon sources were sampled and limnological parameters were quantified. AM = Amazon; AR = Araguaia; PA = Pantanal; PR = Paraná. This figure is similar but not identical to the original image (i.e. in Arrieira et al. [56]), and is therefore for illustrative purposes only.

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The Upper Paraná River is extensively impounded, with over 130 major reservoirs (dam height ≥ 10 m) [57, 58] that modify hydrology and retain sediment and nutrients, resulting in clear oligotrophic water in the main channel of the Paraná [59]. The floodplain is a mosaic of lakes and channels belonging to the Paraná and two primary tributaries (Baía and Ivinheima rivers). The base of the floodplain is Cretaceous sandstone overlain by gravelly, sandy, colluvial and alluvial unconsolidated deposits [60]. Watercolor ranges from clear to greenish to light brown, pH is 6.16 to 6.93, and watersheds are comprised by a mix of forest, pasture and urban areas.

The Pantanal is one of the world’s largest tropical wetlands, occupying approximately 140,000 km². The flood pulse in the northern region coincides with the rainy season but there is a time lag before flooding in the southern region as water flows southward through the main tributary (Paraguai River), various streams and non-channelized flow paths [61,62,63]. Coarse silty-loam irregular deposits form the lower plain of the Pantanal geologic formation [64,65]. Watercolor across the sampled region ranges between green and brown, with abundant aquatic vegetation, pH 6.04 to 7.44, and a primarily grassland and forested watershed.

The Araguaia River in the eastern Amazon drains an area of 320,290 km², including the middle Araguaia which is accompanied by a well-developed alluvial plain [66]. This plain is considered a complex mosaic of morpho-sedimentary units and the basin is dominated by rocks of various geological ages and formations and sedimentary deposits [66,67]. Approximately 76% of the Araguaia watershed is savannah (locally known as Cerrado). The Cerrado ecoregion is considered a hotspot for biodiversity [68] and is the headwater region of the major rivers of eastern South America. Rivers located in the Cerrado are usually classified as clearwater, and our study locations had light brown to greenish water color and pH from 6.33 to 7.37.

Wetlands on the alluvial floodplains of the Amazon River and tributaries in Brazil cover over 300,000 km² [69]. The Brazilian Amazon floodplain is comprised by the Negro and Solimões Rivers that join to form the Amazonas River. The geologic basin consists of sandstones, siltstones, intercalated lignites and clay conglomerates [70]. The Solimões and Amazonas are classic examples of Amazonian whitewater rivers, with nutrient rich, pH neutral (6.2–7.2), turbid water due to suspended mineral solids primarily originated from the Andes Mountains [54, 71]. Limnological conditions among floodplain lakes in our study (some of which were isolated from the main channel) were heterogeneous, including a range of pH from 5.02 to 8.83.

Sampling

Sampling was conducted in floodplain lakes during the late dry season for each floodplain (i.e. September 2011 for Paraná, March 2012 for Pantanal, November 2011 for Araguaia and October 2011 for Amazon). Samples were collected during the late dry season to incorporate the highest degree of heterogeneity in floodplain limnological conditions [72], which are expected to affect stable isotope values of carbon sources. Temperature, dissolved oxygen concentration, electrical conductivity, turbidity, pH and transparency were measured using handheld probes (YSI 550A, Digimed DM-2) and a 25-cm Secchi disk at each location in each basin (i.e. six in Paraná, nine in Pantanal, 13 in Araguaia and 10 in Amazon; Fig 1). Water samples were collected from the subsurface limnetic region for laboratory analysis of phosphorous and nitrogen concentrations (Table 1).

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Table 1. Mean (±standard deviation) of limnological parameters for each basin.

TN = Total Nitrogen; TP = Total Phosphorous; Turb = Turbidity; Cond = Conductivity. The number of sample sites for each basin are in parentheses.

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Water samples were stored on ice and taken to the nearest field station, where they were filtered through GF 52-C membranes (<10 hours after sampling) and immediately frozen (–20°C) for subsequent analyses of dissolved nutrients. Water was also frozen at –20°C before filtering to measure total nitrogen and total phosphorus. Total nitrogen was analyzed with the persulfate method with oxidations of all nitrogenous compounds to N-nitrate [73]. This ion was determined in a spectrophotometer after reducing N-nitrite in the presence of cadmium, using a flow-injection system [74]. N-ammonium was quantified by the indophenol blue method, also read in a spectrophotometer [75]. Total and reactive dissolved phosphorous (i.e. P) were measured in a spectrophotometer, according to Golterman et al. ([76]).

Primary carbon sources collected in each lake for this study included periphyton (attached algae, mostly filamentous algae), phytoplankton, particulate organic carbon (POC), C₃ aquatic macrophytes, C₄ plants (aquatic and terrestrial grasses), and C₃ riparian vegetation. Three to five replicate samples of each carbon source were collected from each site (i.e. each lake), where available. Periphyton was obtained by gently scraping the stem of aquatic plants and other submerged structure (e.g. woody debris), and was stored in a bottle with distilled water for subsequent filtering. Phytoplankton was sampled in the littoral and limnetic zones of each site using a 15 μm plankton net horizontally dragged twice in each zone, constituting four samples per lake. POC was obtained by filtering water collected directly from the subsurface of littoral and limnetic zones in each lake. Periphyton samples and samples of water containing phytoplankton and POC were individually filtered and retained on pre-combusted (400°C for 4 hours) 47mm glass fiber filters (Whatman GF/C). Aquatic macrophytes (i.e. emergent and floating plants), riparian vegetation and C₄ plants consisted of multiple leaves of the most common and abundant vascular plants in each sample site, clipped directly from the plant, and separated by species. The replicates of plant leaves were composed by one leaf of one plant, i.e. in each lake we sampled 3–5 different plants, each one constituting one replicate.

All samples were dried in an oven at 60°C for 72h hours and macerated to obtain a fine and homogeneous powder using a ball-mill grinder or mortar and pestle. Sub-samples of approximately 3–4 mg for C₃ riparian vegetation, C₄ plants and aquatic macrophytes, or half of a filter containing phytoplankton, periphyton or POC were pressed into tin capsules (Costech Analytical, CA, USA) and sent to the University of California at Davis Stable Isotope Facility (USA) for determination of carbon and nitrogen isotope ratios. Results are expressed in delta notation (parts per thousand deviation from a standard material): δ¹³C or δ¹⁵N = [(R_sample/R_standard) -1] *1000; where R = ¹³C/¹²C or ¹⁵N/¹⁴N. The standard material for carbon is Vienna Pee Dee Belemnite (V-PDB) limestone, and the nitrogen standard is atmospheric nitrogen. Standard deviations of δ¹³C and δ¹⁵N for five different replicate analyses of internal standards were between 0.04‰ and 0.13‰ and 0.09 ‰ and 0.22 ‰, respectively.

Subsequent analyses are based on carbon and nitrogen values for 606 samples across all basins and carbon sources. It is important to mention that aquatic macrophytes were absent in the Araguaia floodplain during the sampling period, and thus are not included in our dataset and analyses. Low sample sizes for C₄ plants from the Paraná and Araguaia floodplains (i.e. one in each system) are not expected to bias our analyses of δ¹³C since the values of this source have low variation among ecosystems (e.g. [8]), but would likely change the results for δ¹⁵N analyses because δ¹⁵N of plants is more dependent on nutrient loads of the ecosystem than the photosynthetic pathway of the plant.

Data analysis

In order to answer our two primary questions, we performed a series of analyses with stable isotope values as response variables, and limnological conditions and basin identity as predictors. First, a principal coordinate analysis (PCoA) was performed to reduce the dimensionality of the limnological data, and the broken-stick criteria [77] was used to determine the relevant number of axes for interpretation. Multivariate analysis of variance (MANOVA) was subsequently applied using PC scores of the retained axes to test for differences in limnological conditions among basins. Analysis of variance (ANOVA) was used to test for differences in isotope values (separately for δ¹³C and δ¹⁵N) of each source among basins, with a Tukey HSD posthoc test for distinguishing pairwise relationships among basins following a significant main effect. Pearson correlations were performed between all limnological parameters as well as between those parameters and source isotope values (δ¹³C and δ¹⁵N).

Regression trees were used to predict isotope values (separately for δ¹³C and δ¹⁵N) based on limnological parameters and basin identity (i.e. surrogate for geologic formation). Classification and regression trees are powerful nonparametric approaches to modeling complex ecological data and provide a flexible alternative to linear and additive models [78]. Tree generation involves successively partitioning the response variable into increasingly homogeneous subsets based on fit with predictor variables, including an ability to identify and express non-linear, nested and non-additive relationships. This is particularly appealing in situations where hierarchical interactions are present, and relationships between the response variable and some predictor variables are conditional on the values of other predictors [79]. We used the Gini index to minimize impurity of non-parent nodes, the minimum number of observations at a node in order for a split to be attempted (minsplit) was set at 10, and maximum tree depth (maxdepth) was set at four. The optimum size of the regression trees (pruning) was determined by selecting the tree size with the smallest model error based on repeated cross-validation of the data.

All analyses were conducted using R [80]. Specifically, regression trees were performed using the package Rpart [81] and the other analyses were performed using the packages Stats [80] and Vegan [82]. Significance of statistical tests was assessed at α = 0.05.

Results

The first two PCoA axes explained 59% of the variation in limnological conditions among sites (Fig 2). The first axis separated the sample sites based on turbidity and nutrient concentrations (primarily TN and TP) at positive values, and water clarity (i.e. Secchi depth) at negative values. Secchi depth and ammonia concentration were associated with positive values on PC2, whereas pH, conductivity and phosphate concentration were the primary variables associated with negative values on PC2. Although sampling locations in Amazon had, on average, higher nutrient concentrations and turbidity (Table 1), substantial within basin heterogeneity resulted in broadly overlapping distributions of basins in the PCoA and a non-significant MANOVA (Fig 2; Pillai = 0.32; F_3,34 = 2.14; p = 0.06). Similar to the pattern of axis loadings in the PCoA, several limnological parameters were highly correlated in pairwise comparisons (S1 Fig). Specifically, strong positive correlations were observed among turbidity, TN, TP and NH₄⁺, and between pH and conductivity, whereas Secchi depth was negatively correlated with TP and PO₄^3-.

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Fig 2. Principle coordinates analysis biplot of limnological conditions among sampling locations and basins.

The first two axes explain 59% of the variation among sites (i.e. PC1 explained 36% and 23% was explained by PC2). AM = Amazon; AR = Araguaia; PA = Pantanal; PR = Paraná.

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No significant differences were observed for δ¹³C values of carbon sources among basins, though high within-basin variability was observed for periphyton, phytoplankton and POC (Table 2). In contrast, significant differences in δ¹⁵N were observed among basins for all carbon sources except C₄ plants (Table 2). Sources from the Araguaia floodplain were consistently more ¹⁵N-enriched than in the other basins (Table 2), and exhibited significant differences between the Pantanal for C₃ riparian vegetation, the Paraná floodplain for periphyton and phytoplankton, and among all other basins for POC. C₃ macrophytes had significantly higher δ¹⁵N in the Pantanal than Paraná (Table 2). δ¹⁵N values for sources from the Amazon were intermediate in all cases.

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Table 2. Mean (‰) and standard deviation (±SD) of carbon and nitrogen isotope values for each carbon source, and ANOVA results for the test of differences among basins.

PR = Paraná; PA = Pantanal; AR = Araguaia; AM = Amazon; n = number of samples for each source in each basin. Shared superscript lowercase letters indicate lack of significant differences for the Tukey post-hoc test.

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All significant correlations between δ¹³C or δ¹⁵N and limnological parameters were relatively weak (i.e. | r | < 0.42), and, when significant, were predominantly observed for phytoplankton, POC and periphyton (Table 3). δ¹³C values for phytoplankton and POC were positively correlated with turbidity, TP and PO₄^3- (plus TN for phytoplankton), and negatively correlated with Secchi depth. Periphyton δ¹³C was negatively correlated with NH₄⁺. In contrast, δ¹⁵N values for phytoplankton and POC were positively correlated with pH and NO₃^-, and negatively correlated with turbidity, TN and NH₄⁺ (plus PO₄^3- for POC). Periphyton δ¹⁵N was positively correlated with NO₃^- and NH₄ and negatively correlated with turbidity and PO₄^3-. C₃ aquatic macrophyte δ¹⁵N was negatively correlated with turbidity. No environmental correlates of δ¹³C or δ¹⁵N were found for C₄ plants or C₃ riparian vegetation (except for a very weak positive correlation between turbidity and δ¹³C).

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Table 3. Pearson correlation coefficients between stable isotope values (δ¹³C or δ¹⁵N) and environmental variables for each source.

Significant values are in bold with level of significance denoted using asterisks (* p<0.05; ** p<0.01; *** p<0.001). Turb = Turbitity, Cond = Conductivity, TN = Total Nitrogen, TP = Total Phosphorous.

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Regression trees for both δ¹³C and δ¹⁵N depict complex multivariate and in some cases nested relationships with local limnological conditions and basin identity (Figs 3 and 4). All of the measured limnological parameters and basin identity were included in at least two regression trees, but TP, pH, NH₄⁺ and turbidity together accounted for almost 70% of the splits (including the primary split in seven of the 12 regression trees; Figs 3 and 4). Although PO₄^3- was included in only four models, three of those were primary splits (i.e. δ¹³C of phytoplankton and POC, and periphyton δ¹⁵N). Similarly, basin identity was included in four models but was the primary split for only δ¹⁵N of C₃ aquatic macrophytes, distinguishing samples from the Pantanal from low- and high-pH sites in the Paraná and Amazon floodplains (subsequent splits for the Pantanal were associated with TP, pH and NH₄⁺; Fig 4). Aside from C₃ macrophytes from the Pantanal, almost all other terminal nodes across all trees were comprised by samples from more than one basin (Figs 3 and 4).

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Fig 3. Regression trees predicting δ¹³C for each carbon source.

Splits are identified by boxes on branches with the corresponding parameter and value, and terminal nodes are identified by boxes including the mean value for the response variable (i.e. δ¹³C) as well as the number of samples and sampling locations included in the node. Plus and minus signs or basin abbreviations designate the level of parameter to the left or right of a split (e.g. pH less than or greater than 6.09 for the first split for periphyton).

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Fig 4. Regression trees predicting δ¹⁵N for each carbon source.

Splits are identified by boxes on branches with the corresponding parameter and value, and terminal nodes are identified by boxes including the mean value for the response variable (i.e. δ¹⁵N) as well as the number of samples and sampling locations included in the node. Plus and minus signs or basin abbreviations designate the level of parameter to the left or right of a split (e.g. TP less than or greater than 59.65 for the first split for riparian vegetation).

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Tree structures for δ¹³C and δ¹⁵N were never identical for a carbon source, and exhibited limited similarity across sources for δ¹³C and δ¹⁵N. Coarsely comparing models for δ¹³C and δ¹⁵N, model complexity was similar (i.e. similar number of splits), but the importance of a few parameters were more commonly associated with one or the other element. Specifically, turbidity was included four and five times in regression trees for δ¹³C and δ¹⁵N, respectively, but was never a primary or secondary split for δ¹³C whereas four of the five inclusions for δ¹⁵N were either primary or secondary splits (Figs 3 and 4). Seemingly linked to high turbidity, conductivity was a secondary split for the two δ¹⁵N trees with turbidity as the primary split (i.e. phytoplankton and POC), but was never included in δ¹³C models. pH was included twice as many times in regression trees for δ¹³C, including two primary and one secondary split (i.e. C₄ plants, periphyton and phytoplankton) versus two secondary splits for δ¹⁵N (i.e. C₃ macrophytes and periphyton). Nutrient concentrations were frequently included and in similar numbers in trees for both δ¹³C and δ¹⁵N. However, N (i.e. TN, NO₃^-, NH₄⁺) was mostly a secondary split (nine secondary splits, one primary) whereas P (i.e. TP and PO₄^3-) was commonly included as a primary and secondary split (six primary, five secondary).

Discussion

Previous studies demonstrated biogeographic (i.e. among systems) and biochemical (i.e. within systems) effects on carbon and nitrogen stable isotope values (e.g. [27, 83, 84]). In this study, only very minor differences in δ¹⁵N values of sources were observed among basins, and δ¹³C did not differ among basins for any source (although high within-basin variability was observed for periphyton, phytoplankton and POC, likely precluding significant differences among basins). Although δ¹³C and δ¹⁵N values exhibited significant correlations with some limnological factors within and among basins, those relationships differed among carbon sources.

When considering basin identity and local limnological conditions together, regression trees for both δ¹³C and δ¹⁵N for all sources depicted complex and in some cases nested relationships, and only very limited similarity was observed among trees for different carbon sources. Contrary to expectations, nutrient concentrations did not have a consistent directional effect on isotope values (e.g. positive correlation between δ¹⁵N and nitrogen concentration). That being said, some factors were more consistently included in regression trees for δ¹³C or δ¹⁵N and at primary or secondary split locations (i.e. more important in determining isotope values). For example, turbidity was generally more important for δ¹⁵N (two primary and two secondary splits), whereas pH was included twice as many times in regression trees for δ¹³C (including two primary and one secondary split). Nutrient concentrations were frequently included and in similar numbers in trees for both δ¹³C and δ¹⁵N, but N (i.e. TN, NO₃^-, NH₄⁺) was mostly a secondary split (nine secondary splits, one primary) whereas P (i.e. TP and PO₄^3-) was commonly included as a primary and secondary split (six primary, five secondary). Although limnological conditions and basin identity predicted variation in isotope values of carbon sources, in our opinion the resulting models are too complex to provide a reasonable platform for mathematical correction or alignment of isotope values among sites (e.g. source corrections for evaluation of river ecosystem models).

In regards to our second question, our findings indicate a more pronounced effect of local limnological conditions on variation in δ¹³C and δ¹⁵N of basal sources, regardless of floodplain-system (i.e. basin identity). Basin was the primary factor affecting δ¹⁵N of C₃ macrophytes (which generally have high values for δ¹⁵N in Pantanal; [85]) but nutrient concentrations and pH were important in further distinguishing the broad range of variability in δ¹⁵N of macrophytes in the Pantanal. In contrast, Jepsen and Winemiller ([27]), working in four tributaries of the Orinoco River basin, identified basin geochemistry as a primary factor affecting δ¹³C and δ¹⁵N values of sources and consumers (i.e. fishes). In their study, the tributaries exhibited general differences in limnological conditions due to underlying geologic formations (i.e. white, clear and black water types). Significant variability in δ¹³C and δ¹⁵N of sources was observed within each system (i.e. distribution of source values within systems exceeded differences among systems in their Fig 4), but their primary focus was on upper trophic levels and they did not investigate factors affecting isotopic variability of sources within each system. We expect that had they further explored factors affecting source variability among sampling locations, the effect of ‘basin’ on the isotopic baseline would have been greatly diminished. However, that leaves the question of why consumers demonstrated marked differences in isotope values among systems. This is likely due to differences in the relative importance of various sources to the food webs (as discussed by the authors), which would compound any differences in the mean isotope values of specific sources among systems. In comparison, our study lacked the range of limnological conditions (i.e. extreme blackwater) in Jepsen and Winemiller ([27]), and we would anticipate a greater influence of basin geochemistry on source δ¹³C and δ¹⁵N had our study included a classic blackwater river (e.g. the Rio Negro in the Amazon basin).

No significant differences in δ¹³C of carbon sources were observed at the landscape scale, i.e. comparing mean values of sources among floodplains, and mean source values were comparable with previous studies in floodplain ecosystems (e.g. [8, 46, 83, 86]). Although largely conserved by photosynthetic pathway (e.g. C₄ vs. C₃ plants) and by assimilation of atmospheric CO₂ for vascular plants, regression trees identified complex relationships between δ¹³C of carbon sources and local limnological conditions. Somewhat surprisingly, pH was associated with the primary split in δ¹³C regression trees in only two cases (periphyton and C₄ plants). pH is one of the distinguishing characteristics in the classification of water types that previous studies have associated with differences in δ¹³C (e.g. [27]). It also plays a fundamental role in the bicarbonate equilibrium (i.e. determining relative concentrations of dissolved inorganic carbon compounds) and affects δ¹³C of DIC [19–21]. After pH, the subsequent split was associated with NH₄⁺, perhaps indicating an important interaction between nutrient concentrations and pH in determining δ¹³C of the DIC [22, 23] and subsequently δ¹³C of periphyton. For C₄ plants, this is probably a spurious result because the main source of carbon for vascular plants is atmospheric CO₂ [29]. However, pH was included in every δ¹³C regression tree, and was always in combination with nutrient concentrations for autochthonous sources. Autochthonous production sources such as phytoplankton preferentially assimilate dissolved ¹²CO₂ during photosynthesis, thus the rate of photosynthesis (often limited by available nutrients and light) can affect δ¹³C of the DIC by ¹²C depletion.

It has long been recognized that lake metabolism plays an important role in influencing the isotope signature of DIC [87]. For example, increasing productivity increases δ¹³C-DIC [88] and respiration is generally considered to be the reason for declining δ¹³C-DIC [89]. Although Bade et al. ([21]) found a weak correlation between TP and δ¹³C-DIC and a strong effect of pH on δ¹³C-DIC for the Highland Lakes (USA), this pattern may be different in highly productive floodplain ecosystems [46]. δ¹³C of autochthonous carbon sources (i.e. phytoplankton, periphyton) are directly dependent on DIC in floodplain-river systems and seem to be governed by a balance between respiration and productivity due to a greater contribution of biogenic CO₂ in these productive watersheds [90]. Unfortunately, we were unable to process samples for determination of δ¹³C-DIC, which would have allowed us to more directly test for relationships between limnological conditions and δ¹³C of DIC and primary production sources among sampling locations.

δ¹⁵N of carbon sources was expected to increase with increasing nutrient concentrations (e.g. [32, 91]). In contrast, our correlation analyses indicated no relationship between δ¹⁵N and nutrient concentrations for some sources as well as both positive and negative correlations between δ¹⁵N and different nutrient species (e.g. NH₄⁺ vs NO₃^-) for the same carbon source. Although nutrient concentrations were frequently included in the regression trees, there was not a consistent pattern of higher δ¹⁵N values with higher nutrient concentrations and all models included other predictor variables not associated with nutrients (e.g. pH, conductivity, basin identity). Thus, the influence of nutrient availability on δ¹⁵N of carbon sources was dependent on other factors and was not consistent among sources. Pollution from anthropogenic activities, such as agriculture (e.g. [38, 92]) and sewage [39, 93] have been shown to affect δ¹⁵N of primary producers and consumers. Although we did not directly incorporate sampling to assess such human activities in this study, we observed enriched δ¹⁵N values of phytoplankton (4.46‰) in the Amazon lake with the highest TN and TP concentrations across all sites (i.e. site AM12, surrounded by an active human community).

It is important to note that there are other potentially important environmental factors that we did not quantify. Specifically, gradients in δ¹³C and δ¹⁵N of algae have been attributed to water velocity [14, 94], high temperatures and light intensity [95, 96]. Our study sites were all located in floodplain lakes with little or no flow, consistently high temperatures (i.e. > 25°C) and open canopy, so inclusion of those additional parameters is unlikely to significantly change our findings. However, seasonal variation may influence stable isotopes values of carbon sources. For example, Cloern et al. ([97]) observed seasonal shifts in carbon and nitrogen isotope values of wetland plants from an estuarine system, which they attributed to species-specific cycles of plant growth and senescence. Freshwater floodplain systems are as complex as estuarine systems, however the primary driving force that accounts for seasonal variation in limnological conditions is the flood pulse [2, 98]. Nutrients from different sources (e.g. main river, sediment, decomposing vegetation; [99]) flow into marginal lakes during the rainy season which can directly influence stable isotope values of aquatic primary producers [21, 100]. At the same time, the flood pulse tends to homogenize limnological conditions across the floodplain [72], therefore the high within floodplain heterogeneity observed in our dry season samples would not be expected during the rainy season.

Landscape-level differences in stable isotope values of production sources have been useful in studies of organism movement [50, 101–103]. For example, differences in δ¹³C of sources of white and black water rivers discussed above allowed Winemiller and Jepsen ([49]) to estimate subsidies to blackwater food webs via consumption of migratory Semaprochilodus kneri by large peacock bass Cichla temensis [104]. For our study systems, high within floodplain variability during the dry season and importance of local conditions in determining those differences, suggest that isotopes may be useful for examining habitat use, dispersal and patch dynamics within heterogeneous floodplain ecosystems rather than just between systems with extreme water types. If validated, this approach could represent a finer scale patch or mesohabitat application than previously utilized ‘isoscape’ approaches [51, 105–107]. Such an application would require relatively consistent differences in basal sources among patches and would likely be more useful for small-bodied consumers or early life stages of larger-bodied species (e.g. young-of-year fishes) that rely on algal sources (due to greater variability in those sources and faster tissue turnover rates in smaller-bodied consumers). In addition to small-bodied species or life stages, specific tissues with relatively fast turnover rates, such as liver and blood, could also be utilized. Movement and dispersal rates are notoriously difficult to quantify in complex and open systems such as floodplains, and the application of natural isotopic tracers would be a welcome addition to the ‘tool kit’ for such studies where artificial isotopic labeling (e.g. [34, 108, 109] is not feasible due to the spatial scale and size of the water bodies. The inclusion of hydrogen stable isotopes along with carbon and nitrogen may further enhance this possibility [110, 111], similar to the utility of sulfur stable isotopes for adding greater resolution along spatial gradients in coastal systems [112, 113], and complement otolith microchemistry (e.g. [114]).

The same heterogeneity that may enable the use of isotopes as tracers of organism movement may complicate their use in other types of investigations. One of our primary interests in understanding factors that affect variation in isotope values of basal carbon sources was to identify when and how that variability may need to be accounted for when comparing isotope values of consumers from across sampling locations or systems. For example, understanding and potentially accounting for such baseline variation is important for testing the aforementioned models of carbon flow in river ecosystems (e.g. [8, 9, 11]). Our findings paint a complex picture of the effects of local conditions versus landscape differences on the carbon and nitrogen isotope values of production sources. At the landscape scale, δ¹³C of different carbon sources was relatively conserved across systems, which is good news for comparing patterns of carbon flow using this tracer. However, δ¹⁵N differed among systems as well as among sources within systems (in some cases more than the expected effect of trophic fractionation) which is a significant concern when working with upper trophic level taxa or multitrophic assemblages. Unfortunately, the complex interactions of multiple factors in determining isotope values of sources among sites likely precludes a simple analytical baseline correction. Such variability in the δ¹⁵N baseline is often accounted for by using relatively large-bodied primary consumers as indicators of baseline values [16, 18, 115]. The relatively greater heterogeneity in source isotope values within versus among systems in our study highlights that the spatial scale of sampling, connectivity among patches and habitat use of potential baseline indicator taxa should be explicitly considered.

Supporting information

S1 Fig. Pearson correlation matrix of limnological parameters.

Coefficients are provided above the diagonal and raw values are provided below the diagonal. Asterisks designate significance level (*p<0.05, **p<0.01, ***p<0.001). Turb = Turbidity, Cond = Conductivity, TN = Total Nitrogen, TP = Total Phosphorous.

https://doi.org/10.1371/journal.pone.0174499.s001

(PDF)

S1 Spreadsheet. Raw carbon and nitrogen stable isotopes data.

Data from of all six carbon sources (i.e. periphyton, phytoplankton, POC, C3 macrophytes, riparian vegetation, and C4 plants) sampled across four Neotropical floodplains (Paraná, Pantanal, Araguaia, and Amazon).

https://doi.org/10.1371/journal.pone.0174499.s002

(XLSX)

Acknowledgments

The authors thank the Research Center for Limnology, Ichthyology and Aquaculture (Nupélia) from State University of Maringá (UEM), the Post-Graduate Program in Ecology of Continental Aquatic Environments (PEA/UEM) and the Long Term Ecological Research Program (LTER-site 6 /UEM) for infrastructure to develop the study. We thank researchers from INPA (National Institute for Amazonian Research) and UnB (Brasília University) for field assistance, and also ICMBio and UFMT for providing infrastructure during sampling in the Araguaia and Pantanal basins, respectively.

Author Contributions

Conceptualization: GHZA DJH EB.
Formal analysis: GHZA DJH.
Funding acquisition: EB.
Investigation: GHZA DJH GIM EB.
Methodology: GHZA DJH GIM EB.
Project administration: GHZA.
Resources: EB.
Supervision: DJH EB.
Validation: GHZA DJH.
Visualization: GHZA DJH GIM EB.
Writing – original draft: GHZA DJH.
Writing – review & editing: GHZA DJH GIM EB.

References

1. Vannote RL, Minshall G, Cummins KW, Sedell JR, Cushing CE. The river continuum concept. Can J Fish Aquat Sci. 1980; 37: 130–137.
- View Article
- Google Scholar
2. Junk WJ, Bayley PB, Sparks RE. The flood pulse concept in river-floodplain systems. In: Dodge DP, editor. Proceedings of the International Large River Symposium. Canadian Special Publications Fisheries and Aquatic Sciences; 1989. pp. 110–127.
3. Thorp JH, Delong MD. The riverine productivity model: an heuristic view of carbon sources and organic processing in large river ecosystems. Oikos. 1994; 70: 305–308.
- View Article
- Google Scholar
4. Thorp JH, Thoms MC, Delong MD. The riverine ecosystem synthesis: Biocomplexity in river networks across space and time. River Res Appl. 2006; 22: 123–147.
- View Article
- Google Scholar
5. Humphries P, Keckeis H, Finlayson B. The River Wave Concept: Integrating River Ecosystem Models. BioScience. 2014; 64: 870–882.
- View Article
- Google Scholar
6. Bunn SE, Davies PM, Winning M. Sources of organic carbon supporting the food web of an arid zone floodplain river. Freshw Biol. 2003; 48: 619–635.
- View Article
- Google Scholar
7. Doi AH, Takemon Y, Ohta T, Ishida Y, Kikuchi E. Effects of reach-scale canopy cover on trophic pathways of caddisfly larvae in a Japanese mountain stream. Mar Freshw Res. 2007; 58: 811–817.
- View Article
- Google Scholar
8. Hoeinghaus DJ, Winemiller KO, Agostinho AA. Landscape-scale hydrologic characteristics differentiate patterns of carbon flow in large-river food webs. Ecosystems. 2007; 10: 1019–1033.
- View Article
- Google Scholar
9. Medeiros ESF, Arthington AH. Allochthonous and autochthonous carbon sources for fish in floodplain lagoons of an Australian dryland river. Environ Biol Fishes. 2011; 90: 1–17.
- View Article
- Google Scholar
10. Jardine TD, Pusey BJ, Hamilton SK, Pettit NE, Davies PM, Douglas MM, et al. Fish mediate high food web connectivity in the lower reaches of a tropical floodplain river. Oecologia. 2012; 168: 829–838. pmid:21983712
- View Article
- PubMed/NCBI
- Google Scholar
11. Fellman JB, Pettit NE, Kalic J, Grierson PF. Influence of stream-floodplain biogeochemical linkages on aquatic food web structure along a gradient of stream size in a tropical catchment. Freshw Sci. 2013; 32: 217–229.
- View Article
- Google Scholar
12. Jardine TD, Hunt RJ, Faggotter SJ, Valdez D, Burford MA, Bunn SE. Carbon from periphyton supports fish biomass in waterholes of a wet—dry tropical river. River Res Appl. 2013; 29: 560–573.
- View Article
- Google Scholar
13. Roach K. A. Environmental factors affecting incorporation of terrestrial material into large river food webs. Freshw Sci. 2013; 32: 283–298.
- View Article
- Google Scholar
14. Costas N, Pardo I. Isotopic variability in a stream longitudinal gradient: implications for trophic ecology. Aquat Sci. 2014; 77: 231–260.
- View Article
- Google Scholar
15. Benedito-Cecilio E, CARM Araujo-Lima, Fosberg BR, Bittencourt MM, Martinelli LC. Carbon sources of Amazonian fisheries. Fish Manag Ecol. 2000; 7: 305–315.
- View Article
- Google Scholar
16. Hoeinghaus DJ, Winemiller KO, Agostinho AA. Hydrogeomorphology and river impoundment affect food-chain length of diverse Neotropical food webs. Oikos. 2008; 117: 984–995.
- View Article
- Google Scholar
17. Hadwen WL, Spears M, Kennard MJ. Temporal variability of benthic algal δ¹³C signatures influences assessments of carbon flows in stream food webs. Hydrobiologia. 2010; 651: 239–251.
- View Article
- Google Scholar
18. Jardine TD, Hadwen WL, Hamilton SK, Hladyz S, Mitrovic SM, Kidd KA, Tsoi WY, et al. Understanding and overcoming baseline isotopic variability in running waters. River Res Appl. 2014; 165: 155–165.
- View Article
- Google Scholar
19. Stumm W, Morgan JJ. Aquatic chemistry: an introduction emphasizing chemical equilibria in natural waters. New York: Wiley Inter-science; 1981.
20. Gray DP, Harding JS, Elberling B, Horton T, Clough TJ, Winterbourn MJ. Carbon cycling in floodplain ecosystems: out-gassing and photosynthesis transmit soil δ¹³C gradient through stream food webs. Ecosystems. 2011; 14: 583–597.
- View Article
- Google Scholar
21. Bade DL, Carpenter SR, Cole JJ, Hanson PC, Hesslein RH. Controls of δ¹³C-DIC in lakes: Geochemistry, lake metabolism, and morphometry. Limnol Oceanogr. 2004; 49: 1160–1172.
- View Article
- Google Scholar
22. Lin G, Sternberg LDSL. Effect of growth form, salinity, nutrient and sulfide on photosynthesis, carbon isotope discrimination and growth of red mangrove (Rhizophora mangle L.). Aust J Plant Physiol. 1992; 19: 509–517.
- View Article
- Google Scholar
23. McKee KL, Feller IC, Popp M, Wanek W. Mangrove isotopic (δ¹³C and δ¹⁵N) fractionation across a nitrogen vs. phosphorus limitation gradient. Ecology. 2002; 83: 1065–1075.
- View Article
- Google Scholar
24. Striegl RG, Kortelainen P, Chanton JP, Wickland KP. Carbon dioxide partial pressure and ¹³C content of north temperate and boreal lakes at spring ice melt. Limnol Oceanogr. 2001; 46: 941–945.
- View Article
- Google Scholar
25. Finlay J. Controls of streamwater dissolved inorganic carbon dynamics in a forested watershed. Biogeochemistry. 2003; 62: 231–252.
- View Article
- Google Scholar
26. Bullen TD, Kendall C. Tracing of weathering reactions and water flowpaths: a multi-isotope approach. In: Kendall C, McDonnell JJ, editors. Isotope Tracers in Catchment Hydrology. Amsterdan: Elsevier; 1998. pp. 611–646.
27. Jepsen DB, Winemiller KO. Basin geochemistry and isotopic ratios of fishes and basal production sources in four Neotropical rivers. Ecol Freshw Fish. 2007; 16: 267–281.
- View Article
- Google Scholar
28. Casey MM, Post DM. The problem of isotopic baseline: Reconstructing the diet and trophic position of fossil animals. Earth Sci Rev. 2011; 106: 131–148.
- View Article
- Google Scholar
29. Marshall JD, Brooks JR, Lajtha K. Sources of variation in the stable isotopic composition of plants. In: Michener R, Lajtha K, editors. Stable Isotopes in Ecology and Environmental Science. Oxford: Blackwell publishing; 2007. pp. 22–60.
30. Fry B. Stable isotope ecology. New York: Springer Science; 2006.
31. Iglett PW, Reddy KR. Investigating the use of macrophyte stable C and N isotopic ratios as indicators of wetland eutrophication: Patterns in the P-affected Everglades. Limnol Oceanogr. 2006; 51:2380–2387.
- View Article
- Google Scholar
32. Cabana G, Rasmussen JB. Comparison of aquatic food chains using nitrogen isotopes. Proc Natl Acad Sci U S A. 1996; 93: 10844–10847. pmid:8855268
- View Article
- PubMed/NCBI
- Google Scholar
33. Finlay JC, Kendall C. 2007. Stable isotope tracing of temporal and spatial variability in organic matter sources to freshwater ecosystems. In: Michener R, Lajtha K, editors. Stable isotopes in ecology and environmental science. London: Blackwell Publishing; 2007. pp. 283–333.
34. Yu J, He H, Liu Z, Li K, Hu Y, Zhong P, et al. Cyanobacteria-derived nitrogen uptake by benthic invertebrates in Lake Taihu: a mesocosm study using ¹⁵N labeling. Knowl Manag Aquat Ecosyst. 2014; 415: 1–7.
- View Article
- Google Scholar
35. Viana IG, Bode A. Variability in δ¹⁵N of intertidal brown algae along a salinity gradient: Differential impact of nitrogen sources. Sci Total Environ. 2015; 513: 167–176.
- View Article
- Google Scholar
36. deBruyn AMH, Rasmussen JB. Quantifying assimilation of sewage-derived organic matter by riverine benthos. Ecol Appl. 2002; 12: 511–520.
- View Article
- Google Scholar
37. Bouillon S, Connolly RM, Lee SY. Organic matter exchange and cycling in mangrove ecosystems: Recent insights from stable isotope studies. J Sea Res. 2008; 59: 44–58.
- View Article
- Google Scholar
38. Winemiller KO, Hoeinghaus DJ, Pease AA, Esselman PC, Honeycutt RL, Gbanaador D, et al. Stable isotope analysis reveals food web structure and watershed impacts along the fluvial gradient of a Mesoamerican coastal river. River Res Appl. 2011; 27: 791–803.
- View Article
- Google Scholar
39. Schubert PR, Karez R, Reusch TBH, Dierking J. Isotopic signatures of eelgrass (Zostera marina L.) as bioindicator of anthropogenic nutrient input in the western Baltic Sea. Mar Pollut Bull. 2013; 72: 64–70. pmid:23711843
- View Article
- PubMed/NCBI
- Google Scholar
40. Rožič RP, Dolenec T, Lojen S, Kniewald G, Dolenec M. Use of stable isotope composition variability of particulate organic matter to assess the anthropogenic organic matter in coastal environment (Istra Peninsula, Northern Adriatic). Environ Earth Sci. 2014; 73: 3109–3118.
- View Article
- Google Scholar
41. Lake JL, McKinney RA, Osterman FA, Pruell RJ, Kiddon J, Ryba SA, et al. Stable nitrogen isotopes as indicators of anthropogenic activities in small freshwater systems. Can J Fish Aquat Sci. 2001; 58: 870–878.
- View Article
- Google Scholar
42. Sigleo AC, Macko SA. 2002. Carbon and nitrogen isotopes in suspended particles and colloids, Chesapeake and San Francisco Estuaries. Estuar Coast Shelf Sci. 2002; 54: 701–711.
- View Article
- Google Scholar
43. Sarà G, Scilipoti D, Mazzola A, Modica A. Effects of fish farming waste to sedimentary and particulate organic matter in a southern Mediterranean area (Gulf of Castellammare, Sicily): a multiple stable isotope study δ¹³C and δ¹⁵N. Aquaculture. 2004; 234: 199–213.
- View Article
- Google Scholar
44. Chen ZX, Yu L, Liu WG, Lam MHW, Liu GJ, Yin XB. Nitrogen and oxygen isotopic composition of water-soluble nitrate in Taihu Lake water system, China: implication for nitrate sources and biogeochemical process. Environ Earth Sci. 2014; 71: 217–223.
- View Article
- Google Scholar
45. Kumar BSK, Sarma VVSS, Krishna MS. Distribution of biochemical constituents in the surface sediments of western coastal Bay of Bengal: influence of river discharge and water column properties. Environ Earth Sci. 2014; 69: 1033–1043.
- View Article
- Google Scholar
46. Lewis WM, Hamilton SK, Rodriguez MA, Saunders JF, Lasi MA. Food web analysis of the Orinoco floodplain based on production estimates and stable isotope data. J North Am Benthol Soc. 2001; 20: 241–254.
- View Article
- Google Scholar
47. Fellerhoff C, Voss M, Wantzen KM. Stable carbon and nitrogen isotope signatures of decomposing tropical macrophytes. Aquat Ecol. 2003; 37: 361–375.
- View Article
- Google Scholar
48. Benedito-Cecilio E, Araujo-Lima CARM. Variation in the carbon isotope composition of Semaprochilodus insignis, a detritivorous fish associated with oligotrophic and eutrophic Amazonian rivers. J Fish Biol. 2002; 60: 1603–1607.
- View Article
- Google Scholar
49. Winemiller KO, Jepsen DB. Migratory Neotropical fish subsidize food webs of oligotrophic blackwater rivers. In: Polis GA, Power ME, Huxel GR, editors. Food webs at the landscape level. Chicago: University of Chicago Press; 2004. pp. 115–132.
50. Brosi BJ, Daily GC, Chamberlain CP, Mills M. Detecting changes in habitat-scale bee foraging in a tropical fragmented landscape using stable isotopes. For Ecol Manage. 2009; 258: 1846–1855.
- View Article
- Google Scholar
51. Fry B, Mumford PL, Tam F, Fox DD, Warren GL, Havens KE, et al. Trophic position and individual feeding histories of fish from Lake Okeechobee, Florida. Can J Fish Aquat Sci. 1999; 56: 590–600.
- View Article
- Google Scholar
52. Post DM, Layman CA, Arrington DA, Takimoto G, Quattrochi J, Montana CG. Getting to the fat of the matter: models, methods and assumptions for dealing with lipids in stable isotope analyses. Oecologia. 2007; 152: 179–189. pmid:17225157
- View Article
- PubMed/NCBI
- Google Scholar
53. Logan JM, Jardine TD, Miller TJ, Bunn SE, Cunjak RA, Lutcavage ME. Lipid corrections in carbon and nitrogen stable isotope analyses: comparison of chemical extraction and modelling methods. J Anim Ecol. 2008; 77: 838–846. pmid:18489570
- View Article
- PubMed/NCBI
- Google Scholar
54. Sioli H. The Amazon and its main affluents: hydrography, morphology of the rivers courses, and river types. In: Sioli H, editor. The Amazon: limnology and landscape ecology of a mighty tropical river and its basin. Dordrecht: Dr. Junk Publishers; 1984. pp. 127–165.
55. Sioli H. Tropical rivers as an expression of their terrestrial environment. In: Golly FB, editor. Tropical Ecological Systems. Berlin: Springer-Verlag, Stallard; 1975. pp. 275–288.
56. Arrieira RL, Schwind LTF, Bonecker CC, Lansac-Tôha . Temporal dynamics and environmental predictors on the structure of planktonic testate amoebae community in four Neotropical floodplains. J Freshw Ecol. 2016;
- View Article
- Google Scholar
57. Agostinho AA, Thomaz SM, Minte-Vera CV, Winemiller KO. Biodiversity in the high Paraná River floodplain. In: Gopal B, Junk WJ, Davis JA, editors. Biodiversity in wetlands: assessment, function and conservation. Leiden: Backhuys Publishers; 2000. pp. 89–118.
58. Gomes LC, Miranda LE. Riverine characteristics dictate composition of fish assemblages and limit fisheries in reservoirs of the upper Paraná River basin. River Res Appl. 2001; 17: 67–76.
- View Article
- Google Scholar
59. Souza-Filho EE. Evaluation of the Upper Paraná River discharge controlled by reservoirs. Braz J Biol. 2009; 69: 707–716. pmid:19738976
- View Article
- PubMed/NCBI
- Google Scholar
60. Souza-Filho EE, Stevaux JC. Geology of the Paraná River valley in the vicinity of Porto Rico. In: Agostinho AA, Gomes LC, Rodrigues L, editors. Structure and functioning of the Paraná River and its floodplain, LTER-site 6. Maringá: EDUEM; 2004. pp. 101–106.
61. Hamilton SK. Hydrological controls of ecological structure and function in the Pantanal wetland (Brazil). In: McClain M, editor. The Ecohydrology of South American Rivers and Wetlands. Oxfordshire: International Association of Hydrological Science, Special publications; 2002. pp. 133–158.
62. Junk WJ, Cunha CN, Wantzen KM, Petermann P, Strüssmann C, Marques MI, et al. Biodiversity and its conservation in the Pantanal of Mato Grosso, Brazil. Aquat Sci. 2006; 68: 278–309.
- View Article
- Google Scholar
63. Alvarenga SM, Brasil AE, Pinheiro R, Kux HJH. Estudo geomorfológico aplicado à Bacia do alto Rio Paraguai e Pantanais Matogrossenses. Boletim Técnico Projeto RADAM/ BRASIL. Série Geomorfologia. 1984; 187: 89–183.
- View Article
- Google Scholar
64. Lacerda Filho JW, Brito RSC, Silva MG, Oliveira CC, Moreton LC, Martins EG, et al. Geologia e Recursos Minerais do Estado de Mato Grosso do Sul. Programa Integração, Atualização e Difusão de Dados de Geologia do Brasil. Convênio: CPRM/SICME—MS, Ministério do Meio Ambiente, Brasil; 2006.
65. Figueiredo AJA, Olivatti A. Projeto Alto Guaporé. Final report. Goiânia: DNPM/CPRM. 1974; pp. 173.
66. Latrubesse EM, Stevaux JC. Geomorphology and Environmental Aspects of Araguaia Fluvial Basin, Brazil. Z Geomorphol. 2002; 129: 109–127.
- View Article
- Google Scholar
67. Aquino S, Latrubesse EM, Souza-Filho EE. Caracterização hidrológica dos afluentes da bacia do rio Araguaia. Rev Bras Geomorf. 2009; 10: 43–54.
- View Article
- Google Scholar
68. Myers N, Mittermeier RA, Mittermeier CG, Fonseca GAB, Kent J. Biodiversity hotspots for conservation priorities. Nature. 2000; 403: 853–858 pmid:10706275
- View Article
- PubMed/NCBI
- Google Scholar
69. Klinge H, Junk WJ, Revilla CJ. Status and distribution of forested wetlands in tropical South America. For Ecol Manage. 1990; 33/34: 81–101.
- View Article
- Google Scholar
70. Souza EL, Galvão PHF, Pinheiro CSS, Baessa MPM, Demétrio JGA, Brito WRR. Síntese da hidrogeologia nas bacias sedimentares do Amazonas e do Solimões: Sistemas Aquíferos Içá-Solimões e Alter do Chão. Geol USP Sér Cient. 2013; 13: 107–117.
- View Article
- Google Scholar
71. Furch K, Junk WJ. Physicochemical conditions in the floodplains. In: Junk WJ, editor. The central Amazon floodplain: ecology of a pulsing system. Berlin: Springer Ecological Studies; 1997. pp. 69–108.
72. Thomaz SM, Bini LM, Bozelli RL. Floods increase similarity among aquatic habitats in river-floodplain system. Hydrobiologia. 2007; 579: 1–13.
- View Article
- Google Scholar
73. Bergamin H, Reis BF, Zagatto EAG. A new device for improving sensitivity and stabilization in flow injection analysis. Anal Chim Acta. 1978; 97: 427–431.
- View Article
- Google Scholar
74. Giné MF, Bergamin FH, Zagatto EAG, Reis BF. Simultaneous determination of nitrate and nitrite by flow injection analysis. Anal Chim Acta. 1980; 114: 191–197.
- View Article
- Google Scholar
75. MacKereth FYH, Heron J, Talling JJ. Water analysis: some revised methods for Limnologists. Freshw Rev. 1978; 36: 1–120.
- View Article
- Google Scholar
76. Golterman HL, Clymo RS, Ohmstad MAM. Methods for physical and chemical analysis of fresh water. Oxford: Blackwell Scientific; 1978.
77. Peres-Neto PR, Jackson DA, Somers KM. How many principal components? Stopping rules for determining the number of non-trivial axes revisited. Comput Stat Data Anal. 2005; 49: 974–997.
- View Article
- Google Scholar
78. De'ath G, Fabricius KE. Classification and regression trees: a powerful yet simple technique for the analysis of complex ecological data. Ecology. 2000; 81: 3178–3192.
- View Article
- Google Scholar
79. Joel M, David SS, Mark FA, Frank DW, Ralph DC. Regression Tree Analysis of satellite and terrain data to guide vegetation sampling and surveys. J Veg Sci. 1994; 5: 673–686.
- View Article
- Google Scholar
80. R Core Team. R: A language and environment for statistical computing. R Foundation for Statistical Computing, Vienna, Austria. 2014. http://www.R-project.org/.
81. Therneau T, Atkinson B, Ripley B. rpart: Recursive Partitioning and Regression Trees. R package version 4.1–10. 2015. http://CRAN.R-project.org/package=rpart.
82. Oksanen JF, Blanchet B, Kindt R, Legendre P, Minchin PR, O'Hara RB, et al. vegan: Community Ecology Package. R package version 2.3–0. 2015. http://CRAN.R-project.org/package=vegan.
83. Hill JM, McQuaid CD. δ¹³C and δ¹⁵N biogeographic trends in rocky intertidal communities along the coast of South Africa: Evidence of strong environmental signatures. Estuar Coast Shelf Sci. 2008; 80: 261–268.
- View Article
- Google Scholar
84. Hobson KA, Ofukany A, Soto DX, Wassenaar LI. An isotopic baseline (δ¹³C, δ¹⁵N) for fishes of Lake Winnipeg: Implications for investigating impacts of eutrophication and invasive species. J Great Lakes Res. 2012; 38: 58–65.
- View Article
- Google Scholar
85. Wantzen KM, Machado FA, Voss M, Boriss H, Junk WJ. Seasonal isotopic shifts in fish of the Pantanal wetland, Brazil. Aquat Sci. 2002; 64: 239–251.
- View Article
- Google Scholar
86. Hamilton SK, Lewis WM. Stable carbon and nitrogen isotopes in algae and detritus from the Orinoco river floodplain, Venezuela. Geochim Cosmochim Acta. 1992; 56: 4237–4246.
- View Article
- Google Scholar
87. Oana S, Deevey ES. Carbon 13 in lake waters and its possible bearing on paleolimnology. Am J Sci. 1960; 258: 253–272.
- View Article
- Google Scholar
88. Wang X, Veizer J. Respiration-photosynthesis balance of terrestrial aquatic ecosystems, Ottawa area, Canada. Geochim Cosmochim Acta. 2000; 64: 3775–3786.
- View Article
- Google Scholar
89. Miyajima T, Yamada Y, Wada E, Nakajkima T, Koitabashi T, Hanba YT, et al. Distribution of greenhouse gases, nitrite, and ¹³C of dissolved inorganic carbon in Lake Biwa: Implications for hypolimnetic metabolism. Biogeochemistry. 1997; 36: 205–221.
- View Article
- Google Scholar
90. Tan FC, Edmond JM. Carbon isotope geochemistry of the Orinoco Basin. Estuar Coast Shelf Sci. 1993; 36: 541–547.
- View Article
- Google Scholar
91. Inglett PW, Reddy KR, Newman S, Lorenzen B. Increased soil stable nitrogen isotopic ratio following phosphorus enrichment: Historical patterns and tests of two hypotheses in a phosphorus-limited wetland. Oecologia. 2007; 153: 99–109. pmid:17375325
- View Article
- PubMed/NCBI
- Google Scholar
92. Como S, Magni P, Van Der Velde G, Blok FS, Van De Steeg MFM. Spatial variations in δ¹³C and δ¹⁵N values of primary consumers in a coastal lagoon. Estuar Coast Shelf Sci. 2012; 115: 300–308.
- View Article
- Google Scholar
93. Ochoa-Izaguirre MJ, Soto-Jimenez MF. Variability in Nitrogen Stable Isotope Ratios of Macroalgae: Consequences for the Identification of Nitrogen Sources. J Phycol. 2015; 51: 46–65. pmid:26986258
- View Article
- PubMed/NCBI
- Google Scholar
94. Finlay JC, Khandwala S, Power ME. Spatial scales of carbon flow in a river food web. Ecology. 2002; 83: 1845–1859.
- View Article
- Google Scholar
95. MacLeod NA, Barton DR. Effects of light intensity, water velocity, and species composition on carbon and nitrogen stable isotope ratios in periphyton. Can J Fish Aquat Sci. 1998; 55: 1919–1925.
- View Article
- Google Scholar
96. Hill WR, Fanta SE, Roberts BJ. C-13 dynamics in benthic algae: Effects of light, phosphorous, and biomass development. Limnol Oceanogr. 2008; 53: 1217–1226.
- View Article
- Google Scholar
97. Cloern JE, Canuel EA, Harris D. Stable carbon and nitrogen isotope composition of aquatic and terrestrial plants of the San Francisco Bay estuarine system. Limnol Oceanogr. 2002; 47: 713–729.
- View Article
- Google Scholar
98. Thomaz SM, Lansac Tôha FA, Roberto MC, Esteves FA, Lima AF. Seasonal variation of some limnological factors of lagoa do Guaraná, a várzea lake of the High Rio Paraná, State of Mato Grosso do Sul, Brazil. Rev Hydrobiol Trop. 1992; 25:269–276.
- View Article
- Google Scholar
99. Carvalho P, Bini LM, Thomaz SM, Oliveira LG, Robertson B, Tavechio WLG, et al. Comparative limnology of South American floodplain lakes and lagoons. Acta Sci Biol Sci. 2001; 23:265–273.
- View Article
- Google Scholar
100. Gu B. Variations and controls of nitrogen stable isotopes in particulate organic matter of lakes. Oecologia. 2009; 160: 421–431. pmid:19352718
- View Article
- PubMed/NCBI
- Google Scholar
101. Hobson KA, Wassenaar LI, Taylor OR. Stable isotopes (δD and δ¹³C) are geographic indicators of natal origins of monarch butterflies in eastern North America. Oecologia. 1999; 120: 397–404. pmid:28308016
- View Article
- PubMed/NCBI
- Google Scholar
102. Rubenstein DR, Hobson KA. From birds to butterflies: Animal movement patterns and stable isotopes. Trends Ecol Evol. 2004; 19: 256–263. pmid:16701265
- View Article
- PubMed/NCBI
- Google Scholar
103. Hobson KA, Van Wilgenburg SL, Faaborg J, Toms JD, Rengifo C, Sosa AL, et al. Connecting breeding and wintering grounds of Neotropical migrant songbirds using stable hydrogen isotopes: a call for an isotopic atlas of migratory connectivity. J Field Ornithol. 2014; 85: 237–257.
- View Article
- Google Scholar
104. Hoeinghaus DJ, Winemiller KO, Layman CA, Arrington DA, Jepsen DB. Effects of seasonality and migratory prey on body condition of Cichla species in a tropical floodplain river. Ecol Freshw Fish. 2006; 15: 398–407
- View Article
- Google Scholar
105. Bowen GJ. Isoscapes: Spatial Pattern in Isotopic Biogeochemistry. Annu Rev Earth Planet Sci. 2010; 38: 161–187.
- View Article
- Google Scholar
106. Powell RL, Yoo EH, Still CJ. Vegetation and soil carbon-13 isoscapes for South America: integrating remote sensing and ecosystem isotope measurements. Ecosphere. 2012; 3: 1–25.
- View Article
- Google Scholar
107. Radabaugh K, Hollander D, Peebles E. Seasonal δ¹³C and δ¹⁵N isoscapes of fish populations along a continental shelf trophic gradient. Cont Shelf Res. 2013; 68: 112–122.
- View Article
- Google Scholar
108. Veuger B, Eyre BD, Maher D, Middelburg JJ. Nitrogen incorporation and retention by bacteria, algae, and fauna in a subtropical intertidal sediment: An situ ¹⁵N-labeling study. Limnol Oceanogr. 2007; 52: 1930–1942.
- View Article
- Google Scholar
109. Yu J, Li Y, Liu X, Li K, Chen F, Gulati R, et al. The fate of cyanobacterial detritus in the food web of Lake Taihu: a mesocosm study using ¹³C and ¹⁵N labeling. Hydrobiologia. 2013. 710: 39–46.
- View Article
- Google Scholar
110. Finlay JC, Doucett RR, Mcneely C. Tracing energy flow in stream food webs using stable isotopes of hydrogen. Freshw Biol. 2010; 55: 941–951.
- View Article
- Google Scholar
111. Hondula KL, Pace ML, Cole JJ, Batt RD. Hydrogen isotope discrimination in aquatic primary producers: Implications for aquatic food web studies. Aquat Sci. 2014; 76: 217–229.
- View Article
- Google Scholar
112. Connolly RM, Guest MA, Melville AJ, Oakes JM. Sulfur stable isotopes separate producers in marine food-web analysis. Oecologia. 2004; 138: 161–167. pmid:14593525
- View Article
- PubMed/NCBI
- Google Scholar
113. Fry B, Chumchal MM. Sulfur stable isotope indicators of residency in estuarine fish. Limnol Oceanogr. 2011; 56: 1563–1576.
- View Article
- Google Scholar
114. Sousa RGC, Humston R, Freitas CEC. Movement patterns of adult peacock bass Cichla temensis between tributaries of the middle Negro River basin (Amazonas—Brazil): an otolith geochemical analysis. Fish Manag Ecol. 2016; 23: 76–87.
- View Article
- Google Scholar
115. Post DM, Pace ML, Hairston NG. Ecosystem size determines food-chain length in lakes. Nature. 2000; 405: 1047–1049. pmid:10890443
- View Article
- PubMed/NCBI
- Google Scholar

[ref1] 1. Vannote RL, Minshall G, Cummins KW, Sedell JR, Cushing CE. The river continuum concept. Can J Fish Aquat Sci. 1980; 37: 130–137.
View Article
Google Scholar

[2] View Article

[3] Google Scholar

[ref2] 2. Junk WJ, Bayley PB, Sparks RE. The flood pulse concept in river-floodplain systems. In: Dodge DP, editor. Proceedings of the International Large River Symposium. Canadian Special Publications Fisheries and Aquatic Sciences; 1989. pp. 110–127.

[ref3] 3. Thorp JH, Delong MD. The riverine productivity model: an heuristic view of carbon sources and organic processing in large river ecosystems. Oikos. 1994; 70: 305–308.
View Article
Google Scholar

[6] View Article

[7] Google Scholar

[ref4] 4. Thorp JH, Thoms MC, Delong MD. The riverine ecosystem synthesis: Biocomplexity in river networks across space and time. River Res Appl. 2006; 22: 123–147.
View Article
Google Scholar

[9] View Article

[10] Google Scholar

[ref5] 5. Humphries P, Keckeis H, Finlayson B. The River Wave Concept: Integrating River Ecosystem Models. BioScience. 2014; 64: 870–882.
View Article
Google Scholar

[12] View Article

[13] Google Scholar

[ref6] 6. Bunn SE, Davies PM, Winning M. Sources of organic carbon supporting the food web of an arid zone floodplain river. Freshw Biol. 2003; 48: 619–635.
View Article
Google Scholar

[15] View Article

[16] Google Scholar

[ref7] 7. Doi AH, Takemon Y, Ohta T, Ishida Y, Kikuchi E. Effects of reach-scale canopy cover on trophic pathways of caddisfly larvae in a Japanese mountain stream. Mar Freshw Res. 2007; 58: 811–817.
View Article
Google Scholar

[18] View Article

[19] Google Scholar

[ref8] 8. Hoeinghaus DJ, Winemiller KO, Agostinho AA. Landscape-scale hydrologic characteristics differentiate patterns of carbon flow in large-river food webs. Ecosystems. 2007; 10: 1019–1033.
View Article
Google Scholar

[21] View Article

[22] Google Scholar

[ref9] 9. Medeiros ESF, Arthington AH. Allochthonous and autochthonous carbon sources for fish in floodplain lagoons of an Australian dryland river. Environ Biol Fishes. 2011; 90: 1–17.
View Article
Google Scholar

[24] View Article

[25] Google Scholar

[ref10] 10. Jardine TD, Pusey BJ, Hamilton SK, Pettit NE, Davies PM, Douglas MM, et al. Fish mediate high food web connectivity in the lower reaches of a tropical floodplain river. Oecologia. 2012; 168: 829–838. pmid:21983712
View Article
PubMed/NCBI
Google Scholar

[27] View Article

[28] PubMed/NCBI

[29] Google Scholar

[ref11] 11. Fellman JB, Pettit NE, Kalic J, Grierson PF. Influence of stream-floodplain biogeochemical linkages on aquatic food web structure along a gradient of stream size in a tropical catchment. Freshw Sci. 2013; 32: 217–229.
View Article
Google Scholar

[31] View Article

[32] Google Scholar

[ref12] 12. Jardine TD, Hunt RJ, Faggotter SJ, Valdez D, Burford MA, Bunn SE. Carbon from periphyton supports fish biomass in waterholes of a wet—dry tropical river. River Res Appl. 2013; 29: 560–573.
View Article
Google Scholar

[34] View Article

[35] Google Scholar

[ref13] 13. Roach K. A. Environmental factors affecting incorporation of terrestrial material into large river food webs. Freshw Sci. 2013; 32: 283–298.
View Article
Google Scholar

[37] View Article

[38] Google Scholar

[ref14] 14. Costas N, Pardo I. Isotopic variability in a stream longitudinal gradient: implications for trophic ecology. Aquat Sci. 2014; 77: 231–260.
View Article
Google Scholar

[40] View Article

[41] Google Scholar

[ref15] 15. Benedito-Cecilio E, CARM Araujo-Lima, Fosberg BR, Bittencourt MM, Martinelli LC. Carbon sources of Amazonian fisheries. Fish Manag Ecol. 2000; 7: 305–315.
View Article
Google Scholar

[43] View Article

[44] Google Scholar

[ref16] 16. Hoeinghaus DJ, Winemiller KO, Agostinho AA. Hydrogeomorphology and river impoundment affect food-chain length of diverse Neotropical food webs. Oikos. 2008; 117: 984–995.
View Article
Google Scholar

[46] View Article

[47] Google Scholar

[ref17] 17. Hadwen WL, Spears M, Kennard MJ. Temporal variability of benthic algal δ¹³C signatures influences assessments of carbon flows in stream food webs. Hydrobiologia. 2010; 651: 239–251.
View Article
Google Scholar

[49] View Article

[50] Google Scholar

[ref18] 18. Jardine TD, Hadwen WL, Hamilton SK, Hladyz S, Mitrovic SM, Kidd KA, Tsoi WY, et al. Understanding and overcoming baseline isotopic variability in running waters. River Res Appl. 2014; 165: 155–165.
View Article
Google Scholar

[52] View Article

[53] Google Scholar

[ref19] 19. Stumm W, Morgan JJ. Aquatic chemistry: an introduction emphasizing chemical equilibria in natural waters. New York: Wiley Inter-science; 1981.

[ref20] 20. Gray DP, Harding JS, Elberling B, Horton T, Clough TJ, Winterbourn MJ. Carbon cycling in floodplain ecosystems: out-gassing and photosynthesis transmit soil δ¹³C gradient through stream food webs. Ecosystems. 2011; 14: 583–597.
View Article
Google Scholar

[56] View Article

[57] Google Scholar

[ref21] 21. Bade DL, Carpenter SR, Cole JJ, Hanson PC, Hesslein RH. Controls of δ¹³C-DIC in lakes: Geochemistry, lake metabolism, and morphometry. Limnol Oceanogr. 2004; 49: 1160–1172.
View Article
Google Scholar

[59] View Article

[60] Google Scholar

[ref22] 22. Lin G, Sternberg LDSL. Effect of growth form, salinity, nutrient and sulfide on photosynthesis, carbon isotope discrimination and growth of red mangrove (Rhizophora mangle L.). Aust J Plant Physiol. 1992; 19: 509–517.
View Article
Google Scholar

[62] View Article

[63] Google Scholar

[ref23] 23. McKee KL, Feller IC, Popp M, Wanek W. Mangrove isotopic (δ¹³C and δ¹⁵N) fractionation across a nitrogen vs. phosphorus limitation gradient. Ecology. 2002; 83: 1065–1075.
View Article
Google Scholar

[65] View Article

[66] Google Scholar

[ref24] 24. Striegl RG, Kortelainen P, Chanton JP, Wickland KP. Carbon dioxide partial pressure and ¹³C content of north temperate and boreal lakes at spring ice melt. Limnol Oceanogr. 2001; 46: 941–945.
View Article
Google Scholar

[68] View Article

[69] Google Scholar

[ref25] 25. Finlay J. Controls of streamwater dissolved inorganic carbon dynamics in a forested watershed. Biogeochemistry. 2003; 62: 231–252.
View Article
Google Scholar

[71] View Article

[72] Google Scholar

[ref26] 26. Bullen TD, Kendall C. Tracing of weathering reactions and water flowpaths: a multi-isotope approach. In: Kendall C, McDonnell JJ, editors. Isotope Tracers in Catchment Hydrology. Amsterdan: Elsevier; 1998. pp. 611–646.

[ref27] 27. Jepsen DB, Winemiller KO. Basin geochemistry and isotopic ratios of fishes and basal production sources in four Neotropical rivers. Ecol Freshw Fish. 2007; 16: 267–281.
View Article
Google Scholar

[75] View Article

[76] Google Scholar

[ref28] 28. Casey MM, Post DM. The problem of isotopic baseline: Reconstructing the diet and trophic position of fossil animals. Earth Sci Rev. 2011; 106: 131–148.
View Article
Google Scholar

[78] View Article

[79] Google Scholar

[ref29] 29. Marshall JD, Brooks JR, Lajtha K. Sources of variation in the stable isotopic composition of plants. In: Michener R, Lajtha K, editors. Stable Isotopes in Ecology and Environmental Science. Oxford: Blackwell publishing; 2007. pp. 22–60.

[ref30] 30. Fry B. Stable isotope ecology. New York: Springer Science; 2006.

[ref31] 31. Iglett PW, Reddy KR. Investigating the use of macrophyte stable C and N isotopic ratios as indicators of wetland eutrophication: Patterns in the P-affected Everglades. Limnol Oceanogr. 2006; 51:2380–2387.
View Article
Google Scholar

[83] View Article

[84] Google Scholar

[ref32] 32. Cabana G, Rasmussen JB. Comparison of aquatic food chains using nitrogen isotopes. Proc Natl Acad Sci U S A. 1996; 93: 10844–10847. pmid:8855268
View Article
PubMed/NCBI
Google Scholar

[86] View Article

[87] PubMed/NCBI

[88] Google Scholar

[ref33] 33. Finlay JC, Kendall C. 2007. Stable isotope tracing of temporal and spatial variability in organic matter sources to freshwater ecosystems. In: Michener R, Lajtha K, editors. Stable isotopes in ecology and environmental science. London: Blackwell Publishing; 2007. pp. 283–333.

[ref34] 34. Yu J, He H, Liu Z, Li K, Hu Y, Zhong P, et al. Cyanobacteria-derived nitrogen uptake by benthic invertebrates in Lake Taihu: a mesocosm study using ¹⁵N labeling. Knowl Manag Aquat Ecosyst. 2014; 415: 1–7.
View Article
Google Scholar

[91] View Article

[92] Google Scholar

[ref35] 35. Viana IG, Bode A. Variability in δ¹⁵N of intertidal brown algae along a salinity gradient: Differential impact of nitrogen sources. Sci Total Environ. 2015; 513: 167–176.
View Article
Google Scholar

[94] View Article

[95] Google Scholar

[ref36] 36. deBruyn AMH, Rasmussen JB. Quantifying assimilation of sewage-derived organic matter by riverine benthos. Ecol Appl. 2002; 12: 511–520.
View Article
Google Scholar

[97] View Article

[98] Google Scholar

[ref37] 37. Bouillon S, Connolly RM, Lee SY. Organic matter exchange and cycling in mangrove ecosystems: Recent insights from stable isotope studies. J Sea Res. 2008; 59: 44–58.
View Article
Google Scholar

[100] View Article

[101] Google Scholar

[ref38] 38. Winemiller KO, Hoeinghaus DJ, Pease AA, Esselman PC, Honeycutt RL, Gbanaador D, et al. Stable isotope analysis reveals food web structure and watershed impacts along the fluvial gradient of a Mesoamerican coastal river. River Res Appl. 2011; 27: 791–803.
View Article
Google Scholar

[103] View Article

[104] Google Scholar

[ref39] 39. Schubert PR, Karez R, Reusch TBH, Dierking J. Isotopic signatures of eelgrass (Zostera marina L.) as bioindicator of anthropogenic nutrient input in the western Baltic Sea. Mar Pollut Bull. 2013; 72: 64–70. pmid:23711843
View Article
PubMed/NCBI
Google Scholar

[106] View Article

[107] PubMed/NCBI

[108] Google Scholar

[ref40] 40. Rožič RP, Dolenec T, Lojen S, Kniewald G, Dolenec M. Use of stable isotope composition variability of particulate organic matter to assess the anthropogenic organic matter in coastal environment (Istra Peninsula, Northern Adriatic). Environ Earth Sci. 2014; 73: 3109–3118.
View Article
Google Scholar

[110] View Article

[111] Google Scholar

[ref41] 41. Lake JL, McKinney RA, Osterman FA, Pruell RJ, Kiddon J, Ryba SA, et al. Stable nitrogen isotopes as indicators of anthropogenic activities in small freshwater systems. Can J Fish Aquat Sci. 2001; 58: 870–878.
View Article
Google Scholar

[113] View Article

[114] Google Scholar

[ref42] 42. Sigleo AC, Macko SA. 2002. Carbon and nitrogen isotopes in suspended particles and colloids, Chesapeake and San Francisco Estuaries. Estuar Coast Shelf Sci. 2002; 54: 701–711.
View Article
Google Scholar

[116] View Article

[117] Google Scholar

[ref43] 43. Sarà G, Scilipoti D, Mazzola A, Modica A. Effects of fish farming waste to sedimentary and particulate organic matter in a southern Mediterranean area (Gulf of Castellammare, Sicily): a multiple stable isotope study δ¹³C and δ¹⁵N. Aquaculture. 2004; 234: 199–213.
View Article
Google Scholar

[119] View Article

[120] Google Scholar

[ref44] 44. Chen ZX, Yu L, Liu WG, Lam MHW, Liu GJ, Yin XB. Nitrogen and oxygen isotopic composition of water-soluble nitrate in Taihu Lake water system, China: implication for nitrate sources and biogeochemical process. Environ Earth Sci. 2014; 71: 217–223.
View Article
Google Scholar

[122] View Article

[123] Google Scholar

[ref45] 45. Kumar BSK, Sarma VVSS, Krishna MS. Distribution of biochemical constituents in the surface sediments of western coastal Bay of Bengal: influence of river discharge and water column properties. Environ Earth Sci. 2014; 69: 1033–1043.
View Article
Google Scholar

[125] View Article

[126] Google Scholar

[ref46] 46. Lewis WM, Hamilton SK, Rodriguez MA, Saunders JF, Lasi MA. Food web analysis of the Orinoco floodplain based on production estimates and stable isotope data. J North Am Benthol Soc. 2001; 20: 241–254.
View Article
Google Scholar

[128] View Article

[129] Google Scholar

[ref47] 47. Fellerhoff C, Voss M, Wantzen KM. Stable carbon and nitrogen isotope signatures of decomposing tropical macrophytes. Aquat Ecol. 2003; 37: 361–375.
View Article
Google Scholar

[131] View Article

[132] Google Scholar

[ref48] 48. Benedito-Cecilio E, Araujo-Lima CARM. Variation in the carbon isotope composition of Semaprochilodus insignis, a detritivorous fish associated with oligotrophic and eutrophic Amazonian rivers. J Fish Biol. 2002; 60: 1603–1607.
View Article
Google Scholar

[134] View Article

[135] Google Scholar

[ref49] 49. Winemiller KO, Jepsen DB. Migratory Neotropical fish subsidize food webs of oligotrophic blackwater rivers. In: Polis GA, Power ME, Huxel GR, editors. Food webs at the landscape level. Chicago: University of Chicago Press; 2004. pp. 115–132.

[ref50] 50. Brosi BJ, Daily GC, Chamberlain CP, Mills M. Detecting changes in habitat-scale bee foraging in a tropical fragmented landscape using stable isotopes. For Ecol Manage. 2009; 258: 1846–1855.
View Article
Google Scholar

[138] View Article

[139] Google Scholar

[ref51] 51. Fry B, Mumford PL, Tam F, Fox DD, Warren GL, Havens KE, et al. Trophic position and individual feeding histories of fish from Lake Okeechobee, Florida. Can J Fish Aquat Sci. 1999; 56: 590–600.
View Article
Google Scholar

[141] View Article

[142] Google Scholar

[ref52] 52. Post DM, Layman CA, Arrington DA, Takimoto G, Quattrochi J, Montana CG. Getting to the fat of the matter: models, methods and assumptions for dealing with lipids in stable isotope analyses. Oecologia. 2007; 152: 179–189. pmid:17225157
View Article
PubMed/NCBI
Google Scholar

[144] View Article

[145] PubMed/NCBI

[146] Google Scholar

[ref53] 53. Logan JM, Jardine TD, Miller TJ, Bunn SE, Cunjak RA, Lutcavage ME. Lipid corrections in carbon and nitrogen stable isotope analyses: comparison of chemical extraction and modelling methods. J Anim Ecol. 2008; 77: 838–846. pmid:18489570
View Article
PubMed/NCBI
Google Scholar

[148] View Article

[149] PubMed/NCBI

[150] Google Scholar

[ref54] 54. Sioli H. The Amazon and its main affluents: hydrography, morphology of the rivers courses, and river types. In: Sioli H, editor. The Amazon: limnology and landscape ecology of a mighty tropical river and its basin. Dordrecht: Dr. Junk Publishers; 1984. pp. 127–165.

[ref55] 55. Sioli H. Tropical rivers as an expression of their terrestrial environment. In: Golly FB, editor. Tropical Ecological Systems. Berlin: Springer-Verlag, Stallard; 1975. pp. 275–288.

[ref56] 56. Arrieira RL, Schwind LTF, Bonecker CC, Lansac-Tôha . Temporal dynamics and environmental predictors on the structure of planktonic testate amoebae community in four Neotropical floodplains. J Freshw Ecol. 2016;
View Article
Google Scholar

[154] View Article

[155] Google Scholar

[ref57] 57. Agostinho AA, Thomaz SM, Minte-Vera CV, Winemiller KO. Biodiversity in the high Paraná River floodplain. In: Gopal B, Junk WJ, Davis JA, editors. Biodiversity in wetlands: assessment, function and conservation. Leiden: Backhuys Publishers; 2000. pp. 89–118.

[ref58] 58. Gomes LC, Miranda LE. Riverine characteristics dictate composition of fish assemblages and limit fisheries in reservoirs of the upper Paraná River basin. River Res Appl. 2001; 17: 67–76.
View Article
Google Scholar

[158] View Article

[159] Google Scholar

[ref59] 59. Souza-Filho EE. Evaluation of the Upper Paraná River discharge controlled by reservoirs. Braz J Biol. 2009; 69: 707–716. pmid:19738976
View Article
PubMed/NCBI
Google Scholar

[161] View Article

[162] PubMed/NCBI

[163] Google Scholar

[ref60] 60. Souza-Filho EE, Stevaux JC. Geology of the Paraná River valley in the vicinity of Porto Rico. In: Agostinho AA, Gomes LC, Rodrigues L, editors. Structure and functioning of the Paraná River and its floodplain, LTER-site 6. Maringá: EDUEM; 2004. pp. 101–106.

[ref61] 61. Hamilton SK. Hydrological controls of ecological structure and function in the Pantanal wetland (Brazil). In: McClain M, editor. The Ecohydrology of South American Rivers and Wetlands. Oxfordshire: International Association of Hydrological Science, Special publications; 2002. pp. 133–158.

[ref62] 62. Junk WJ, Cunha CN, Wantzen KM, Petermann P, Strüssmann C, Marques MI, et al. Biodiversity and its conservation in the Pantanal of Mato Grosso, Brazil. Aquat Sci. 2006; 68: 278–309.
View Article
Google Scholar

[167] View Article

[168] Google Scholar

[ref63] 63. Alvarenga SM, Brasil AE, Pinheiro R, Kux HJH. Estudo geomorfológico aplicado à Bacia do alto Rio Paraguai e Pantanais Matogrossenses. Boletim Técnico Projeto RADAM/ BRASIL. Série Geomorfologia. 1984; 187: 89–183.
View Article
Google Scholar

[170] View Article

[171] Google Scholar

[ref64] 64. Lacerda Filho JW, Brito RSC, Silva MG, Oliveira CC, Moreton LC, Martins EG, et al. Geologia e Recursos Minerais do Estado de Mato Grosso do Sul. Programa Integração, Atualização e Difusão de Dados de Geologia do Brasil. Convênio: CPRM/SICME—MS, Ministério do Meio Ambiente, Brasil; 2006.

[ref65] 65. Figueiredo AJA, Olivatti A. Projeto Alto Guaporé. Final report. Goiânia: DNPM/CPRM. 1974; pp. 173.

[ref66] 66. Latrubesse EM, Stevaux JC. Geomorphology and Environmental Aspects of Araguaia Fluvial Basin, Brazil. Z Geomorphol. 2002; 129: 109–127.
View Article
Google Scholar

[175] View Article

[176] Google Scholar

[ref67] 67. Aquino S, Latrubesse EM, Souza-Filho EE. Caracterização hidrológica dos afluentes da bacia do rio Araguaia. Rev Bras Geomorf. 2009; 10: 43–54.
View Article
Google Scholar

[178] View Article

[179] Google Scholar

[ref68] 68. Myers N, Mittermeier RA, Mittermeier CG, Fonseca GAB, Kent J. Biodiversity hotspots for conservation priorities. Nature. 2000; 403: 853–858 pmid:10706275
View Article
PubMed/NCBI
Google Scholar

[181] View Article

[182] PubMed/NCBI

[183] Google Scholar

[ref69] 69. Klinge H, Junk WJ, Revilla CJ. Status and distribution of forested wetlands in tropical South America. For Ecol Manage. 1990; 33/34: 81–101.
View Article
Google Scholar

[185] View Article

[186] Google Scholar

[ref70] 70. Souza EL, Galvão PHF, Pinheiro CSS, Baessa MPM, Demétrio JGA, Brito WRR. Síntese da hidrogeologia nas bacias sedimentares do Amazonas e do Solimões: Sistemas Aquíferos Içá-Solimões e Alter do Chão. Geol USP Sér Cient. 2013; 13: 107–117.
View Article
Google Scholar

[188] View Article

[189] Google Scholar

[ref71] 71. Furch K, Junk WJ. Physicochemical conditions in the floodplains. In: Junk WJ, editor. The central Amazon floodplain: ecology of a pulsing system. Berlin: Springer Ecological Studies; 1997. pp. 69–108.

[ref72] 72. Thomaz SM, Bini LM, Bozelli RL. Floods increase similarity among aquatic habitats in river-floodplain system. Hydrobiologia. 2007; 579: 1–13.
View Article
Google Scholar

[192] View Article

[193] Google Scholar

[ref73] 73. Bergamin H, Reis BF, Zagatto EAG. A new device for improving sensitivity and stabilization in flow injection analysis. Anal Chim Acta. 1978; 97: 427–431.
View Article
Google Scholar

[195] View Article

[196] Google Scholar

[ref74] 74. Giné MF, Bergamin FH, Zagatto EAG, Reis BF. Simultaneous determination of nitrate and nitrite by flow injection analysis. Anal Chim Acta. 1980; 114: 191–197.
View Article
Google Scholar

[198] View Article

[199] Google Scholar

[ref75] 75. MacKereth FYH, Heron J, Talling JJ. Water analysis: some revised methods for Limnologists. Freshw Rev. 1978; 36: 1–120.
View Article
Google Scholar

[201] View Article

[202] Google Scholar

[ref76] 76. Golterman HL, Clymo RS, Ohmstad MAM. Methods for physical and chemical analysis of fresh water. Oxford: Blackwell Scientific; 1978.

[ref77] 77. Peres-Neto PR, Jackson DA, Somers KM. How many principal components? Stopping rules for determining the number of non-trivial axes revisited. Comput Stat Data Anal. 2005; 49: 974–997.
View Article
Google Scholar

[205] View Article

[206] Google Scholar

[ref78] 78. De'ath G, Fabricius KE. Classification and regression trees: a powerful yet simple technique for the analysis of complex ecological data. Ecology. 2000; 81: 3178–3192.
View Article
Google Scholar

[208] View Article

[209] Google Scholar

[ref79] 79. Joel M, David SS, Mark FA, Frank DW, Ralph DC. Regression Tree Analysis of satellite and terrain data to guide vegetation sampling and surveys. J Veg Sci. 1994; 5: 673–686.
View Article
Google Scholar

[211] View Article

[212] Google Scholar

[ref80] 80. R Core Team. R: A language and environment for statistical computing. R Foundation for Statistical Computing, Vienna, Austria. 2014. http://www.R-project.org/.

[ref81] 81. Therneau T, Atkinson B, Ripley B. rpart: Recursive Partitioning and Regression Trees. R package version 4.1–10. 2015. http://CRAN.R-project.org/package=rpart.

[ref82] 82. Oksanen JF, Blanchet B, Kindt R, Legendre P, Minchin PR, O'Hara RB, et al. vegan: Community Ecology Package. R package version 2.3–0. 2015. http://CRAN.R-project.org/package=vegan.

[ref83] 83. Hill JM, McQuaid CD. δ¹³C and δ¹⁵N biogeographic trends in rocky intertidal communities along the coast of South Africa: Evidence of strong environmental signatures. Estuar Coast Shelf Sci. 2008; 80: 261–268.
View Article
Google Scholar

[217] View Article

[218] Google Scholar

[ref84] 84. Hobson KA, Ofukany A, Soto DX, Wassenaar LI. An isotopic baseline (δ¹³C, δ¹⁵N) for fishes of Lake Winnipeg: Implications for investigating impacts of eutrophication and invasive species. J Great Lakes Res. 2012; 38: 58–65.
View Article
Google Scholar

[220] View Article

[221] Google Scholar

[ref85] 85. Wantzen KM, Machado FA, Voss M, Boriss H, Junk WJ. Seasonal isotopic shifts in fish of the Pantanal wetland, Brazil. Aquat Sci. 2002; 64: 239–251.
View Article
Google Scholar

[223] View Article

[224] Google Scholar

[ref86] 86. Hamilton SK, Lewis WM. Stable carbon and nitrogen isotopes in algae and detritus from the Orinoco river floodplain, Venezuela. Geochim Cosmochim Acta. 1992; 56: 4237–4246.
View Article
Google Scholar

[226] View Article

[227] Google Scholar

[ref87] 87. Oana S, Deevey ES. Carbon 13 in lake waters and its possible bearing on paleolimnology. Am J Sci. 1960; 258: 253–272.
View Article
Google Scholar

[229] View Article

[230] Google Scholar

[ref88] 88. Wang X, Veizer J. Respiration-photosynthesis balance of terrestrial aquatic ecosystems, Ottawa area, Canada. Geochim Cosmochim Acta. 2000; 64: 3775–3786.
View Article
Google Scholar

[232] View Article

[233] Google Scholar

[ref89] 89. Miyajima T, Yamada Y, Wada E, Nakajkima T, Koitabashi T, Hanba YT, et al. Distribution of greenhouse gases, nitrite, and ¹³C of dissolved inorganic carbon in Lake Biwa: Implications for hypolimnetic metabolism. Biogeochemistry. 1997; 36: 205–221.
View Article
Google Scholar

[235] View Article

[236] Google Scholar

[ref90] 90. Tan FC, Edmond JM. Carbon isotope geochemistry of the Orinoco Basin. Estuar Coast Shelf Sci. 1993; 36: 541–547.
View Article
Google Scholar

[238] View Article

[239] Google Scholar

[ref91] 91. Inglett PW, Reddy KR, Newman S, Lorenzen B. Increased soil stable nitrogen isotopic ratio following phosphorus enrichment: Historical patterns and tests of two hypotheses in a phosphorus-limited wetland. Oecologia. 2007; 153: 99–109. pmid:17375325
View Article
PubMed/NCBI
Google Scholar

[241] View Article

[242] PubMed/NCBI

[243] Google Scholar

[ref92] 92. Como S, Magni P, Van Der Velde G, Blok FS, Van De Steeg MFM. Spatial variations in δ¹³C and δ¹⁵N values of primary consumers in a coastal lagoon. Estuar Coast Shelf Sci. 2012; 115: 300–308.
View Article
Google Scholar

[245] View Article

[246] Google Scholar

[ref93] 93. Ochoa-Izaguirre MJ, Soto-Jimenez MF. Variability in Nitrogen Stable Isotope Ratios of Macroalgae: Consequences for the Identification of Nitrogen Sources. J Phycol. 2015; 51: 46–65. pmid:26986258
View Article
PubMed/NCBI
Google Scholar

[248] View Article

[249] PubMed/NCBI

[250] Google Scholar

[ref94] 94. Finlay JC, Khandwala S, Power ME. Spatial scales of carbon flow in a river food web. Ecology. 2002; 83: 1845–1859.
View Article
Google Scholar

[252] View Article

[253] Google Scholar

[ref95] 95. MacLeod NA, Barton DR. Effects of light intensity, water velocity, and species composition on carbon and nitrogen stable isotope ratios in periphyton. Can J Fish Aquat Sci. 1998; 55: 1919–1925.
View Article
Google Scholar

[255] View Article

[256] Google Scholar

[ref96] 96. Hill WR, Fanta SE, Roberts BJ. C-13 dynamics in benthic algae: Effects of light, phosphorous, and biomass development. Limnol Oceanogr. 2008; 53: 1217–1226.
View Article
Google Scholar

[258] View Article

[259] Google Scholar

[ref97] 97. Cloern JE, Canuel EA, Harris D. Stable carbon and nitrogen isotope composition of aquatic and terrestrial plants of the San Francisco Bay estuarine system. Limnol Oceanogr. 2002; 47: 713–729.
View Article
Google Scholar

[261] View Article

[262] Google Scholar

[ref98] 98. Thomaz SM, Lansac Tôha FA, Roberto MC, Esteves FA, Lima AF. Seasonal variation of some limnological factors of lagoa do Guaraná, a várzea lake of the High Rio Paraná, State of Mato Grosso do Sul, Brazil. Rev Hydrobiol Trop. 1992; 25:269–276.
View Article
Google Scholar

[264] View Article

[265] Google Scholar

[ref99] 99. Carvalho P, Bini LM, Thomaz SM, Oliveira LG, Robertson B, Tavechio WLG, et al. Comparative limnology of South American floodplain lakes and lagoons. Acta Sci Biol Sci. 2001; 23:265–273.
View Article
Google Scholar

[267] View Article

[268] Google Scholar

[ref100] 100. Gu B. Variations and controls of nitrogen stable isotopes in particulate organic matter of lakes. Oecologia. 2009; 160: 421–431. pmid:19352718
View Article
PubMed/NCBI
Google Scholar

[270] View Article

[271] PubMed/NCBI

[272] Google Scholar

[ref101] 101. Hobson KA, Wassenaar LI, Taylor OR. Stable isotopes (δD and δ¹³C) are geographic indicators of natal origins of monarch butterflies in eastern North America. Oecologia. 1999; 120: 397–404. pmid:28308016
View Article
PubMed/NCBI
Google Scholar

[274] View Article

[275] PubMed/NCBI

[276] Google Scholar

[ref102] 102. Rubenstein DR, Hobson KA. From birds to butterflies: Animal movement patterns and stable isotopes. Trends Ecol Evol. 2004; 19: 256–263. pmid:16701265
View Article
PubMed/NCBI
Google Scholar

[278] View Article

[279] PubMed/NCBI

[280] Google Scholar

[ref103] 103. Hobson KA, Van Wilgenburg SL, Faaborg J, Toms JD, Rengifo C, Sosa AL, et al. Connecting breeding and wintering grounds of Neotropical migrant songbirds using stable hydrogen isotopes: a call for an isotopic atlas of migratory connectivity. J Field Ornithol. 2014; 85: 237–257.
View Article
Google Scholar

[282] View Article

[283] Google Scholar

[ref104] 104. Hoeinghaus DJ, Winemiller KO, Layman CA, Arrington DA, Jepsen DB. Effects of seasonality and migratory prey on body condition of Cichla species in a tropical floodplain river. Ecol Freshw Fish. 2006; 15: 398–407
View Article
Google Scholar

[285] View Article

[286] Google Scholar

[ref105] 105. Bowen GJ. Isoscapes: Spatial Pattern in Isotopic Biogeochemistry. Annu Rev Earth Planet Sci. 2010; 38: 161–187.
View Article
Google Scholar

[288] View Article

[289] Google Scholar

[ref106] 106. Powell RL, Yoo EH, Still CJ. Vegetation and soil carbon-13 isoscapes for South America: integrating remote sensing and ecosystem isotope measurements. Ecosphere. 2012; 3: 1–25.
View Article
Google Scholar

[291] View Article

[292] Google Scholar

[ref107] 107. Radabaugh K, Hollander D, Peebles E. Seasonal δ¹³C and δ¹⁵N isoscapes of fish populations along a continental shelf trophic gradient. Cont Shelf Res. 2013; 68: 112–122.
View Article
Google Scholar

[294] View Article

[295] Google Scholar

[ref108] 108. Veuger B, Eyre BD, Maher D, Middelburg JJ. Nitrogen incorporation and retention by bacteria, algae, and fauna in a subtropical intertidal sediment: An situ ¹⁵N-labeling study. Limnol Oceanogr. 2007; 52: 1930–1942.
View Article
Google Scholar

[297] View Article

[298] Google Scholar

[ref109] 109. Yu J, Li Y, Liu X, Li K, Chen F, Gulati R, et al. The fate of cyanobacterial detritus in the food web of Lake Taihu: a mesocosm study using ¹³C and ¹⁵N labeling. Hydrobiologia. 2013. 710: 39–46.
View Article
Google Scholar

[300] View Article

[301] Google Scholar

[ref110] 110. Finlay JC, Doucett RR, Mcneely C. Tracing energy flow in stream food webs using stable isotopes of hydrogen. Freshw Biol. 2010; 55: 941–951.
View Article
Google Scholar

[303] View Article

[304] Google Scholar

[ref111] 111. Hondula KL, Pace ML, Cole JJ, Batt RD. Hydrogen isotope discrimination in aquatic primary producers: Implications for aquatic food web studies. Aquat Sci. 2014; 76: 217–229.
View Article
Google Scholar

[306] View Article

[307] Google Scholar

[ref112] 112. Connolly RM, Guest MA, Melville AJ, Oakes JM. Sulfur stable isotopes separate producers in marine food-web analysis. Oecologia. 2004; 138: 161–167. pmid:14593525
View Article
PubMed/NCBI
Google Scholar

[309] View Article

[310] PubMed/NCBI

[311] Google Scholar

[ref113] 113. Fry B, Chumchal MM. Sulfur stable isotope indicators of residency in estuarine fish. Limnol Oceanogr. 2011; 56: 1563–1576.
View Article
Google Scholar

[313] View Article

[314] Google Scholar

[ref114] 114. Sousa RGC, Humston R, Freitas CEC. Movement patterns of adult peacock bass Cichla temensis between tributaries of the middle Negro River basin (Amazonas—Brazil): an otolith geochemical analysis. Fish Manag Ecol. 2016; 23: 76–87.
View Article
Google Scholar

[316] View Article

[317] Google Scholar

[ref115] 115. Post DM, Pace ML, Hairston NG. Ecosystem size determines food-chain length in lakes. Nature. 2000; 405: 1047–1049. pmid:10890443
View Article
PubMed/NCBI
Google Scholar

[319] View Article

[320] PubMed/NCBI

[321] Google Scholar

Figures

Abstract

Introduction

Material and methods

Ethics statement

Study systems and river classifications

Sampling

Data analysis

Results

Discussion

Supporting information

S1 Fig. Pearson correlation matrix of limnological parameters.

S1 Spreadsheet. Raw carbon and nitrogen stable isotopes data.

Acknowledgments

Author Contributions

References