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Functional diversity in relation to the longitudinal gradient of a species-rich Neotropical river

Published online by Cambridge University Press:  16 October 2024

Edwin O. López-Delgado
Affiliation:
Department of Ecology and Conservation Biology, Texas A&M University, College Station, TX, USA Grupo de Estudios en Biodiversidad (GEBIO), Universidad Industrial de Santander, Bucaramanga, Colombia
Francisco A. Villa-Navarro
Affiliation:
Grupo de Investigación en Zoología, Universidad del Tolima, Ibagué, Colombia
Kirk O. Winemiller*
Affiliation:
Department of Ecology and Conservation Biology, Texas A&M University, College Station, TX, USA
*
Corresponding author: Kirk O. Winemiller; Email: [email protected]
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Abstract

A functional traits approach was adopted to examine patterns of fish diversity in relation to environmental and spatial variables and for comparison with findings from earlier analyses of fish taxonomic diversity in a nearly pristine river in the Llanos region of Colombia. Fishes were surveyed during the low-water period at 34 sites along the longitudinal fluvial gradient of the Bita River, a clearwater tributary of the Orinoco River. We compiled a matrix of 37 traits associated with locomotion, feeding, and defense for 132 species to compute functional β diversity metrics among four reaches along the entire longitudinal fluvial gradient and also within reaches. Functional redundancy (trait under-dispersion) was found to be common throughout the fluvial gradient. Functional β diversity was high at both spatial scales, with widespread evidence of functional nestedness and functional turnover, especially in upper reaches. In the Bita River, environmental filtering and stochastic processes, such as random dispersal, appear to be the dominant mechanisms influencing fish functional diversity. Inferences derived from analysis of functional versus taxonomic diversity are largely congruent, although analysis of functional β diversity found more evidence of nestedness than turnover at both spatial scales. Both lines of evidence stress the importance of habitat heterogeneity and aquatic habitat connectivity for conservation of high species diversity in this system.

Type
Research Article
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution and reproduction, provided the original article is properly cited.
Copyright
© The Author(s), 2024. Published by Cambridge University Press

Introduction

A long-standing challenge for ecologists is to identify and understand mechanisms that create and maintain biodiversity at various scales of time and space. Whereas most research has focused on taxonomic diversity, trait-based approaches provide a stronger basis to infer how organisms and populations respond to environmental gradients, disturbances, and biotic interactions (Cadotte et al. Reference Cadotte, Carscadden and Mirotchnick2011, Villéger et al. Reference Villéger, Brosse, Mouchet, Mouillot and Vanni2017). The current study analyses functional diversity of fish assemblages in the Bita River, a nearly pristine river in the Llanos region of Colombia. The goal was to contrast patterns of functional diversity along the longitudinal fluvial gradient and to compare inferences about mechanisms structuring fish assemblages with those derived from prior analysis of taxonomic diversity (López-Delgado et al. Reference López-Delgado, Winemiller and Villa-Navarro2019, Reference López-Delgado, Winemiller and Villa-Navarro2020).

Communities can be influenced by both random factors, such as environmental and demographic stochasticity, and deterministic processes, such as environmental filtering and competitive exclusion. Environmental conditions may only allow establishment and persistence of species with certain traits, which can yield communities with high functional redundancy (i.e., trait under-dispersion within the community) (Mason et al. Reference Mason, Lanoiselée, Mouillot, Irz and Argillier2007, Rodrigues-Filho et al. Reference Rodrigues-Filho, Gurge-Lourenço, Queiroz Lima, Fontes de Oliveira and Sánchez-Botero2017). Conversely, biotic interactions may select for certain functional trait combinations that facilitate species coexistence, resulting in communities with high functional diversity (i.e., trait over-dispersion within the community) (Mouillot et al. Reference Mouillot, Dumay and Tomasini2007, Montaña et al. Reference Montaña, Winemiller and Sutton2014, Cadotte and Tucker Reference Cadotte and Tucker2017).

Two assemblages can differ in species composition (high taxonomic β diversity) but be very similar in terms of functional traits (low functional β diversity). Functional β diversity can be partitioned into functional turnover and functional nestedness (Villéger et al. Reference Villéger, Grenouillet and Brosse2013). Functional turnover is indicated by the degree of overlap within functional space between two species assemblages, whereas functional nestedness occurs when one assemblage encompasses only a subset of the functional space occupied by the other assemblage. High functional β diversity can result from either of these components or both simultaneously. If assemblages are strongly influenced by environmental filtering, then within-assemblage functional diversity should be low (a limited set of traits may be adaptive for local conditions) with high functional turnover among local assemblages along environmental gradients (as conditions shift along the gradient, different sets of adaptive traits may apply). However, responses to environmental gradients also can yield nested β diversity patterns, for example, if some species are highly sensitive or responsive to abiotic variation but others are tolerant of a wider range of conditions. In contrast, if competition is strong, coexisting species may have divergent traits that yield high assemblage functional diversity (trait-overdispersion), with levels of functional β diversity depending on species responses to conditions along environmental gradients (Mouchet et al. Reference Mouchet, Burns, Garcia, Vieira and Mouillot2013).

We analysed functional diversity of fish assemblages along the longitudinal fluvial gradient of the Bita River to infer potential influences from environmental filtering, interspecific competition, and dispersal in shaping assemblage structure. More specifically, we tested whether functional β diversity and its components are influenced by spatial scale and position within the river basin. We hypothesized that, at the basin scale, high functional β diversity is driven by functional turnover due to environmental filtering along the river’s longitudinal fluvial gradient (Carvalho and Tejerina-Garro Reference Carvalho and Tejerina-Garro2015a, Reference Carvalho and Tejerina-Garro2015b). In headwater reaches, dispersal limitation and the influence of abiotic environmental factors should result in environmental filtering, and β diversity should influenced by functional diversity turnover. In contrast, downstream segments where there is more extensive aquatic habitat with greater connectivity, biotic interactions should have a stronger influence on assemblage structure (limiting similarity), resulting in higher functional α diversity and relatively low functional β diversity due to high rates of dispersal. We compare findings for functional diversity in this system with those from earlier analyses of taxonomic diversity (López-Delgado et al. Reference López-Delgado, Winemiller and Villa-Navarro2019, Reference López-Delgado, Winemiller and Villa-Navarro2020) that found high species turnover and a strong association of abiotic environmental variables with assemblage structure.

Methods

Data collection

Fish surveys were performed across the longitudinal fluvial gradient (700 km) of the Bita River (basin = 812,312 ha), a free-flowing, clearwater tributary of the Orinoco River in the Llanos region of Colombia. The regional climate is tropical with a mean annual precipitation of 2,300 mm and mean temperature of 28°C. During the dry season, aquatic habitats are restricted to the river mainstem and lateral channels, creeks, and lakes in the floodplains. Substrates in the main channel are dominated by sand with small patches of wood, leaves and rocks, and substrates of aquatic habitats in floodplains generally are a mixture of sand, leaves and woody debris. During the wet season, flooding of forests and savannas greatly increases aquatic habitat volume and connectivity.

Fishes were surveyed in littoral habitats during the dry season (January–March 2016) when low-water conditions typically result in high fish densities and greater efficiency of fish sampling methods (López-Delgado et al. Reference López-Delgado, Winemiller and Villa-Navarro2019). The annual low-water period is when availability of aquatic habitat is lowest, lateral connectivity of aquatic habitats is lowest, fish densities are highest, and the intensity of competition should be greatest for most fish trophic guilds (Lowe-McConnell Reference Lowe-McConnell1964, Reference Lowe-McConnell1987). We conducted surveys within each of four sections of equal length along the longitudinal fluvial gradient of the river network (high, mid-high, mid-low, and low). A total of 34 sites were surveyed (Figure 1) using a seine (10 × 1.5 m, 3-mm mesh) and two gill nets (10 × 2 m, 100-mm mesh). At each survey site, nearshore habitat within a 200-m reach was sampled using seven 20-m seine hauls and two gillnets, each set for 2 h. Fishes were handled according to animal-use protocol IACUC 2015-0360 (Texas A&M University). Surveys yielded 201 fish species and a total of 25,928 specimens (López-Delgado et al. Reference López-Delgado, Winemiller and Villa-Navarro2019) that were formalin fixed, EtOH preserved, and deposited in the ichthyology collections of the Instituto Alexander von Humboldt (IAvH-P) and Universidad del Tolima in Colombia (CZUT-IC). The surveys effectively captured species common in littoral habitats (Table S1), but some rare species (e.g., or common large species that move in and out of littoral areas that are known from the regional ichthyofauna (ca. total 300 spp.) have been documented from clearwater rivers of the region, D.C. Taphorn, unpublished) eluded capture by the methods we employed (e.g., Cichla temensis, Crenicichla lugubris, Hydrolycus armatus, Pseudoplatystoma fasciatum, and Serrasalmus manueli).

Figure. 1. Locations of the 34 sites sampled within the Bita River Basin; rectangles group sites according to sections along the longitudinal fluvial gradient.

Functional traits data

Traits were classified into functional categories, reflecting three major niche dimensions (locomotion and habitat use, feeding, defense) sensu Winemiller et al. (Reference Winemiller, Fitzgerald, Bower and Pianka2015). Twenty traits were related to locomotion and habitat use, 13 traits to feeding, and four traits to defense (Table S2). Body dimensions were measured on 3–10 specimens of 132 common species that had more than three specimens collected during the study, yielding a total of 2,219 specimens measured. To eliminate allometric variation associated with ontogeny during analysis of interspecific patterns, only adult size classes were measured. Body dimensions were measured to the nearest 0.1 mm using calipers and following the methodology described by Winemiller (Reference Winemiller1991). As proposed by Su et al. (Reference Su, Villéger and Brosse2018), values were set to 0 for traits that were not applicable for a given species (e.g., dorsal fin is absent in gymnotiforms and synbranchiforms). Ten categorical traits and one ordinal trait (number of barbels) were recorded as ordinal numbers designating states along gradients from low to high values (Table S2).

Environmental and spatial variables

Environmental and spatial variables were recorded at each survey site. Environmental variables were divided into six categories that describe physical and chemical features of aquatic habitats (Table S3). Water quality parameters were measured using a multiparameter probe (YSI model 85), percent instream coverage of substrate categories was estimated visually along the littoral zone of each 200-m reach, and variables associated with the riparian area and landcover were estimated using georeferenced satellite images and ArcMap (Version 10.3.1). Spatial structure of survey locations was modelled using asymmetric eigenvector maps (AEM), a method formulated by Blanchet et al. (2008). This method considers the directional aspects of inter-site distances in systems like river networks, accounting for factors such as water flow and relative position within the network. We created AEM eigenfunctions by constructing a connection diagram that links the sites according to the river network’s flow, from upstream to downstream. While AEM eigenfunction variables are mathematical abstractions, in our case, they effectively model the connections among sites and the flow direction of the river at the basin scale (see López-Delgado et al. (Reference López-Delgado, Winemiller and Villa-Navarro2019) for a full description of methods for measuring environmental parameters and modelling spatial variables). When constructing AEMs, there are n−1 variables created, where n is the number of sites. In our case, with 34 sites, AEM derived 33 variables. These variables, denoted as Vi, are related to the position within the basin.

Data analysis

To determine if functional diversity patterns differed depending on the spatial scale and position within the river network, analyses were performed at the basin scale (34 sites) and local scale (survey sites within a given basin section). Body dimension measurements were converted to unitless ratios to serve as shape components of the body and head, as recommended by Winemiller (Reference Winemiller1991) for studies comparing assemblages. In total, 26 continuous and 10 categorical traits were obtained for analysis. To calculate functional diversity indices, we used the mean of standardized trait values for each species. A matrix of functional distances between all species pairs was calculated using Gower’s distance (Villéger et al. Reference Villéger, Grenouillet and Brosse2013). Principal coordinates analysis (PCoA) was performed on the functional distance matrix to obtain species coordinates in multidimensional trait space. We applied Maire et al.’s (Reference Maire, Grenouillet, Brosse and Villéger2015) method to estimate the trait space that best represented functional information content. Species coordinates from the first three PCoA axes were used to calculate functional α and β diversity indices. These analyses were performed using the function quality_funct_space in R (R Core Team, 2020) available in Appendix S1 from Maire et al. (Reference Maire, Grenouillet, Brosse and Villéger2015).

We compared functional α diversity indices of local assemblages within and among the four river sections using six functional diversity metrics that have been proposed as predictors of assembly processes (Villéger et al. Reference Villéger, Mason and Mouillot2008, Mouchet et al. Reference Mouchet, Mason and Mouillot2010, Mouillot et al. Reference Mouillot, Graham, Villéger, Mason and Bellwood2013). Functional richness (FRic) is the proportion of the functional space occupied by species in an assemblage. Functional divergence (FDiv) is the deviation of species abundance to the center of the functional space occupied by the regional species pool. Functional evenness (FEve) is the evenness of species abundance within the functional space. Functional dispersion (FDis) is the mean distance of species to the centroid of the functional space of the local assemblage divided by half the maximum distance among all species in the regional assemblage. Functional specialization (FSpe) is the mean distance of species to the assemblage centroid. Functional originality (FOri) as the mean distance of species to their closest neighbour within the local assemblage divided by the maximum distance to a nearest neighbour recorded for that assemblage (Mouchet et al. Reference Mouchet, Burns, Garcia, Vieira and Mouillot2013, Córdova-Tapia et al. Reference Córdova-Tapia, Hernández-Marroquín and Zambrano2018). These indices were calculated using the function multidimFD in R. In addition, we estimated the diversity of species with similar functions in the ecosystem using the functional redundancy method proposed by Pillar et al. (Reference Pillar, Blanco, Müller, Sosinski, Joner and Duarte2013). The Kruskal–Wallis test was used to compare differences in functional α diversity metrics among river sections.

To test whether environmental filtering (should increase trait similarity) or competition (should limit similarity) best explained community assembly, we applied a null model to identify whether the observed values for functional diversity metrics differed from random expectations. For example, if species within a local assemblage are more similar to each other and/or unevenly dispersed (clumped) in trait space than expected at random (trait under-dispersion), then environmental filtering is inferred to be important during community assembly from the regional species pool. In contrast, if species are more dissimilar to each other and/or broadly and evenly dispersed than expected at random (trait overdispersion), then interspecific competition is inferred to be important during community assembly. Therefore, for all six of our functional diversity metrics, observed values lower than the random expectation yield an inference of environmental filtering, and observed values higher than the random expectation yield an inference of interspecific competition affecting community assembly. The model generated 999 random community matrices using an independent swap algorithm (unconstrained) and recalculated functional diversity metrics for each. Standardized effect sizes (SES) were calculated as a measure of departure from random expectation; values greater than 0 indicate that the observed value is greater than expected by chance (trait overdispersion suggesting limiting similarity in response to competition), and values smaller than 0 indicate that observed value is less than expected (trait under-dispersion suggesting environmental filtering) (Mouillot et al. Reference Mouillot, Dumay and Tomasini2007). Randomizations were conducted using the function randomizeMatrix in the R package picante (Kembel et al. Reference Kembel, Cowan, Helmus, Cornwell, Morlon, Ackerly, Blomberg and Webb2010), and SES and p-values were calculated according to Swenson (Reference Swenson2014). We applied a two-tailed test with p-values ≥0.975 indicating the observed value was greater than expected by chance, and an observed value ≤0.025 indicated a value lower than expected by chance.

To calculate pairwise functional β diversity, we used the convex hull volume of assemblages and measured the overlap in the functional space between two assemblages; a value of one indicates that there is no overlap between two assemblages, and a value of 0 indicates complete overlap. This method was proposed by Villéger et al. (Reference Villéger, Grenouillet and Brosse2013) as an analogy of taxonomic β diversity proposed by Baselga (Reference Baselga2012). Functional β diversity was then calculated based on the Jaccard dissimilarity index and partitioned into functional turnover and functional nestedness dissimilarity components using the function functional.beta.pair in the package betapart in R. To identify possible differences in mean functional β diversity and its components among river sections, we used a test of homogeneity of dispersion PERMDIST, and then Tukey’s HSD was applied to identify significant pair-wise differences among river sections. Analyses were conducted using the function betadisper from the vegan library in R.

Variation in functional β diversity along environmental and spatial gradients

To test whether variation in functional dissimilarity matrices (functional β diversity, functional turnover, and functional nestedness) between pairs of local assemblages was best explained by environmental or spatial factors, we performed a distance-based redundancy analysis (db-RDA) and variation partitioning analysis (Legendre, Reference Legendre2014). To select the environmental and spatial variables to include in the variation partitioning analysis, first, a db-RDA was performed using each of the functional dissimilarity matrices and the environmental and spatial variables, and then a forward selection procedure was applied on the set of principal coordinates produced by the db-RDA. Environmental variables were transformed and standardized (mean = 0; standard deviation = 1) prior to analysis; all variables expressed as proportions were transformed to the arcsine of their square root, and the remaining variables (except categorical) were log(x+1) transformed. Selected variables (environmental and spatial) by the forward selection procedure were used in the variation partitioning analysis. Statistical significance of each component from the variation partitioning was assessed based on an ANOVA-like permutation (999 permutations; α = 0.05). Analyses were performed in R using the functions forward.sel from the adespatial package, dbRDA.D from appendix S4 in Legendre (Reference Legendre2014), and varpart and anova from the vegan package.

Results

Functional richness per section ranged from 19 to 32% of the total functional space filled by the basin-wide species pool (132 species included in our analysis), with a mean of 27 ± 22. Highest values of the various diversity metrics were observed in the two middle sections; however, none of the differences between sections were significantly different (Table S4). Based on the null model analysis of standardized effect size (two-tailed test), trait under-dispersion was the predominant pattern among the 34 local assemblages (Figure 2, Table S5). However, most of the observed values were not significantly different from random expectations, with the exception of functional divergence (FDiv) in which 91% of the values were significantly different from random.

Figure. 2. Comparison of standard effect size (deviation of observed values from random expectations) of six functional diversity indices of fish assemblages in four sections of the Bita River Basin. A value of zero (dotted line) indicates the mean for randomly assembled communities. Observed values above the dotted line indicate overdispersion of species in functional trait space, and values below the line indicate under-dispersion of the metrics: functional richness (FRic), functional divergence (FDiv), functional evenness (FEve), functional dispersion (FDis), functional specialization (FSpe), functional originality (FOri), and functional redundancy (FRed).

Functional β diversity and its components

At the basin scale, functional β diversity ranged from 0.25 to 1, with a mean value of 0.74 ± 0.19. Functional turnover contributed 43%, whereas the functional nestedness component was 57%. At a finer spatial scale, functional β diversity generally was high within river sections (Table S6), with values greater than 0.64 and the nestedness component dominating functional β diversity within all four sections (Table 1). According to results from PERMDISP analysis, only functional turnover was significantly different among the river sections (p = 0.001). The Tukey HSD test revealed that the mid=low section was significantly different from both the mid=high section and the low section (Table S7).

Table 1. Mean values (± standard deviation) of functional beta diversity (FBeta), functional turnover (FTurn), and functional nestedness (FNes) calculated at the scale of the entire river basin and for each river section. Fpturn refers to the contribution of turnover to functional beta diversity (Fpturn = FTurn/FBeta)

Functional β diversity and environmental variables

The forward selection procedure selected four environmental and four spatial variables that modelled functional β diversity (Table S8). For functional turnover, six environmental and one spatial variable were selected; for functional nestedness, five environmental and four spatial variables were selected. Most of the selected environmental variables were associated with aquatic habitat structural features. The spatial variables were associated with the high and mid-high sections of the basin, suggesting a tendency towards dispersal limitation in these areas. Results from the variation partitioning analysis showed that both environmental and spatial components explained significant variation in functional β diversity, functional turnover, and functional nestedness (Table S6). The variation explained by the pure spatial fraction was higher than the pure environmental fraction for functional β diversity and functional nestedness (0.11 and 0.20, respectively) (Figure 3). Conversely, 43% of the variation in functional turnover was explained by the pure environmental fraction, and 11.6% was explained by the spatial fraction.

Figure 3. Variation partitioning analysis. (a) functional β diversity, (b) turnover, and (c) functional nestedness. Circles are not drawn to scale, values represent the adjusted R2, and negative fractions values are not shown.

Discussion

Results from both spatial scales of analysis revealed high functional β diversity driven mostly by functional nestedness, but also species turnover within upper reaches of the basin, suggesting a significant influence from environmental filtering. This result confirmed one of our initial predictions. At the basin scale, we expected high functional β diversity driven by functional turnover; however, results showed that functional nestedness was just as prevalent throughout the basin. Our general finding of trait under-dispersion is consistent with those from other studies that found high functional redundancy among stream fishes in Brazil (e.g., Casatti et al. Reference Casatti, Teresa, de Oliveira Zeni, Ribeiro, Brejao and Ceneviva-Bastos2015). At the finer spatial scale, we expected to find distinct patterns of functional diversity depending on position within the river network. Headwater assemblages should be more strongly influenced by environmental filtering and have low functional α diversity and high functional β diversity relative to those in downstream habitats (Vitorino Júnior et al. Reference Vitorino Júnior, Fernandes, Agostinho and Pelicice2016). Conversely, downstream assemblages should be influenced by biotic interactions to a greater degree owing to higher connectivity of aquatic habitats (facilitating high dispersal) resulting in higher functional α diversity. Overall, our results only support the hypothesis regarding headwater assemblages, and environmental filtering was the dominant inference no matter the position within the river network. Evidence was generally lacking to support a stronger influence of biotic interactions on downstream assemblages. Several studies have shown that factors influencing community structure vary according to spatial scale (Brown et al. Reference Brown, Fox and Kelt2000, Mason et al. Reference Mason, Irz, Lanoisele, Mouillot and Argillier2008, Vitorino Júnior et al. Reference Vitorino Júnior, Fernandes, Agostinho and Pelicice2016). Our results did not reveal major differences in patterns of functional diversity for analyses performed at basin-wide versus reach scales.

Our results from variance partitioning analysis using environmental and spatial variables differed depending on the dissimilarity matrix used. For functional β diversity, the percentage of unexplained variation was high (84%), which is fairly common in ecological studies (Erős, Reference Erős2017, Leibold and Chase, Reference Leibold and Chase2017). Low percentage of variation explained by the variation partitioning analysis might suggest that stochastic processes not linked to network connectivity play an important role in structuring fish assemblages in this system during the annual low-water season. However, environmental and spatial variables explained more variation in functional turnover and nestedness (albeit in different percentages) than in functional β diversity per se. Functional turnover seems to be driven more by environmental variables, and functional nestedness influenced relatively more by spatial factors. Functional turnover was associated with structural habitat features, especially the percentages of cobble, leaf packs, small woody debris, and large woody debris, whereas nestedness was most strongly associated with percentages of mud, grass and filamentous algae. These results were consistent with those of Santos et al. (Reference Santos, Benone, Soares, Barthem and Montag2019) who found a significant relation between environmental heterogeneity and functional structure of fish assemblages in tropical streams. In a recent study of taxonomic β diversity in streams of the Cerrado region (Araguaia River Basin, Brazil), Oliveira et al. (Reference Oliveira, Bini, Lima and Lima-Junior2023) reported minor but statistically significant fractions of β diversity was explained by environmental and spatial variables. Of course, these relationships are strongly dependent on the spatial scale of analysis. For example, at the river-basin scale in the Neotropics, water chemistry (i.e., black-, clear-, and white-water conditions) has been shown to have a major association with fish assemblage turnover (Winemiller et al. Reference Winemiller, López Fernández, Taphorn, Nico and Barbarino Duque2008, Borges et al. Reference Borges, D’Aquino, Victória da Cruz and Felipe de Souza2023).

Overall, our results for functional β diversity are similar to those obtained from a prior analysis of taxonomic β diversity (López-Delgado et al. Reference López-Delgado, Winemiller and Villa-Navarro2020), but there are a few differences. Taxonomic β diversity of fishes in the Bita River was high at both basin-wide and within-region scales, and the dominant pattern was species turnover. In addition, variance partitioning revealed that environmental factors were more influential than spatial variables. Those results led to an inference of species sorting as a strong influence on fish assemblage structure. Our results for functional β diversity also showed high β diversity, but there tended to be greater support for functional nestedness than functional turnover, and local assemblages, for the most part, tended to be significantly under-dispersed in functional trait space according to multiple functional diversity metrics. Moreover, variance partitioning indicated a greater association of environmental variables compared to spatial variables on assemblage functional diversity. Our conclusion based on functional diversity is, nonetheless, the same as that for taxonomic diversity, which is that environmental filtering (species sorting) is an influential process structuring fish assemblages in the Bita River during the low-water season. Nonsignificant results and unexplained variance for many tests also indicate the potential for random processes, such as dispersal dynamics, to influence assemblage functional structure. Null model analysis showed that many of the observed values of functional β diversity were not different from random expectations based on the regional species pool. Stochastic factors associated with dispersal and survival undoubtedly play a role in structuring local assemblages (Chase Reference Chase2007, Spasojevic and Suding Reference Spasojevic and Suding2012).

Results from our study are consistent with the environmental control model proposed by Heino et al. (Reference Heino, Melo and Bini2015) that predicts a strong influence of environmental filtering at multiple spatial scales when communities are dominated by species with low dispersal. Most of the fishes that we captured from shallow littoral habitats in the Bita River were small (<10 cm standard length) and most probably have relatively low capability for rapid dispersal over long distances. Cadotte and Tucker (Reference Cadotte and Tucker2017) proposed that abundant and widespread species should have similar trait combinations that convey fitness under diverse environmental conditions. This idea was supported by our results for the Bita River; for example, small characids were the most abundant and diverse fishes, and had similar traits associated with habitat use, defense, and feeding.

It is important to note that several factors could bias our results. Our surveys of littoral habitats did not capture large, vagile fishes that may be important interactors in local assemblages, either as predators or competitors. Inclusion of these species could change estimates of functional α and β diversity. Additionally, there are potential sources of error that could influence the ability of community metrics to detect community assembly rules (Botta-Dukát and Czúcz Reference Botta-Dukát and Czúcz2016), such as choice of the null model (Swenson, Reference Swenson2014) and the kinds of traits analyzed (Maire et al. Reference Maire, Grenouillet, Brosse and Villéger2015, Fitzgerald et al. Reference Fitzgerald, Winemiller, Sabaj Pérez and Sousa2017, Vitule et al. Reference Vitule, Agostinho, Azevedo-Santos, Daga, Darwall, Fitzgerald, Frehse, Hoeinghaus, Lima, Magalhães, Orsi, Padial, Pelicice, Petrere, Pompeu and Winemiller2017). The selection of additional functional traits or exclusion of certain traits from our dataset could change results.

Future research might adopt the methodology proposed by Winemiller et al. (Reference Winemiller, Fitzgerald, Bower and Pianka2015) that uses multivariate methods to combine trait datasets for five niche dimensions (habitat, trophic, metabolic, defense, and life history) to produce an ordination of species according to their niche as a composite described by the functional traits relevant for each dimension. This requires compiling diverse traits data that, for most Neotropical fishes, are currently lacking. Finally, our field study was conducted during the annual low-water season, and dispersal and other ecological dynamics during the preceding high-water season could have yielded legacy effects on our survey data. Future research could repeat surveys during other periods of the year, although capture efficiencies would be lower and much greater survey effort would be required.

Many studies have inferred environmental filtering as the mechanism responsible for patterns of trait under-dispersion and low functional richness (Cadotte and Tucker, Reference Cadotte and Tucker2017, Thakur and Wright, Reference Thakur and Wright2017). In the Bita River, low functional richness and high functional redundancy were consistent patterns throughout the longitudinal fluvial gradient, suggesting that despite being a species-rich system, locally co-occurring species have relatively consistent sets of functional traits. For example, small fusiform fishes with banded or spotted pigmentation, such as Dicrossus filamentosus, Elachocharax pulcher, Crenicichla wallacii, and Nannostomus unifasciatus, were almost always captured from habitats with abundant leaf packs and woody debris. High functional redundancy in fish assemblages has been found in other Neotropical systems (Casatti et al. Reference Casatti, Teresa, de Oliveira Zeni, Ribeiro, Brejao and Ceneviva-Bastos2015) and inferred to enhance community and ecosystem stability and resilience (Cadotte et al. Reference Cadotte, Carscadden and Mirotchnick2011). High functional redundancy reduces the probability that loss of a given species affects ecosystem functions (Fonseca and Ganade, Reference Fonseca and Ganade2001). Based on a global biodiversity assessment, Toussaint et al. (Reference Toussaint, Charpin, Brosse and Villéger2016) concluded that functional redundancy of freshwater fishes was greatest in the Neotropics, and, therefore, loss of threatened species might not erode overall functional diversity to the same extent as similar losses in temperate regions with less functional redundancy. However, Vitule et al. (Reference Vitule, Agostinho, Azevedo-Santos, Daga, Darwall, Fitzgerald, Frehse, Hoeinghaus, Lima, Magalhães, Orsi, Padial, Pelicice, Petrere, Pompeu and Winemiller2017) argued that Toussaint et al.’s estimate of functional diversity was based solely on ecomorphological variables (body shape variables) and therefore lacked consideration of trait diversity with respect to other niche dimensions that may show high functional diversity with less functional redundancy. For example, Neotropical freshwater fishes reveal great variation in life history traits (Winemiller Reference Winemiller1989) and traits associated with other niche dimensions (Winemiller et al. Reference Winemiller, Fitzgerald, Bower and Pianka2015). Here we attempted to expand analysis of functional traits by including not only body shape variables associated with swimming performance, habitat use, and feeding but also variables associated with defense from predators. Nonetheless, our traits dataset was limited in scope and heavily influenced by traditional body shape variables, leaving the possibility that inclusion of more traits associated with more dimensions could change results.

High functional β diversity across and within river sections probably reflects the fact that the low-gradient, meandering Bita River is a mosaic of in-channel and floodplain habitats. This habitat heterogeneity apparently produces high functional turnover in fish assemblages in response to spatial variation in environmental conditions (Teresa and Casatti, Reference Teresa and Casatti2012, Weinstein et al. Reference Weinstein, Tinoco, Parra, Brown, McGuire, Stiles and Graham2014) with varying degrees of nestedness. Despite that certain habitat types are present throughout the basin (e.g., sandbanks, patches with leaf packs or submerged woody debris), we found both taxonomic (López-Delgado et al. Reference López-Delgado, Winemiller and Villa-Navarro2020) and functional β diversity to be significant within and among regions along the longitudinal fluvial gradient.

Evidence of deterministic and stochastic processes acting simultaneously has been found in studies of assemblage structure in other Neotropical rivers (Arrington et al. Reference Arrington, Winemiller and Layman2005, Fitzgerald et al. Reference Fitzgerald, Winemiller, Sabaj Pérez and Sousa2017, Córdova-Tapia et al. Reference Córdova-Tapia, Hernández-Marroquín and Zambrano2018). Stochastic factors can increase β diversity even in relatively homogenous habitats with little dispersal limitation, especially when the regional species pool is diverse, and there is a high functional redundancy (Leibold and Chase Reference Leibold and Chase2017). Our study was conducted during the annual low-water period when fish functional groups are expected to be strongly influenced by environmental filtering due to reduced availability of habitat, high fish densities, and, in some cases, harsh abiotic environmental conditions (Winemiller Reference Winemiller1990, Córdova-Tapia and Zambrano Reference Córdova-Tapia and Zambrano2016). Local fish assemblage structure has been shown to be non-random in other Llanos rivers during the period of flood recession (Arrington and Winemiller Reference Arrington and Winemiller2006, Montaña et al. Reference Montaña, Winemiller and Sutton2014, Winemiller et al. Reference Winemiller, Taphorn, Kelso-Winemiller, López-Delgado, Keppeler and Montaña2018).

To conclude, findings from analyses of both taxonomic and functional diversity indicate that environmental filtering is an important mechanism that structures fish assemblages of the Bita River at both basin and reach scales, with a particular influence of habitat features related to substrate composition and structural complexity. This implies that to preserve fish biodiversity in the Bita River, sufficient habitat heterogeneity and connectivity need to be maintained. Degradation of the fluvial habitat mosaic during the dry season would reduce fish functional diversity, possibly affecting occurrence frequencies of traits that are redundant within and among local species assemblages, with consequences for community resilience.

Supplementary material

The supplementary material for this article can be found at https://doi.org/10.1017/S026646742400021X

Acknowledgements

The authors thank Carlos DoNacimento, Donald C. Taphorn, Juan Gabriel Albornoz, and Diana Montoya for help during the field and laboratory work.

Authors’ contributions

EOL and KOW participated in the study design, field work, laboratory work, analysed data, wrote, edited, and revised the manuscript. FAVN participated in the study design, field work, and manuscript editing.

Financial support

The work was supported by grants from the World Wildlife Fund (WWF) Colombia, Fundación Omacha, Instituto de Investigación de Recursos Biológicos Alexander von Humboldt (IAvH), and Grupo de Investigación en Zoología at the Universidad el Tolima.

Competing interests

The author(s) declare none.

Publishing ethics

This manuscript and data are our own original work without previous duplication.

Ethical statement

None.

References

Arrington, DA and Winemiller, KO (2006) Habitat affinity, the seasonal flood pulse, and community assembly in the littoral zone of a Neotropical floodplain river. Journal of the North American Benthological Society 25, 126141.CrossRefGoogle Scholar
Arrington, DA, Winemiller, KO and Layman, CA (2005) Community assembly at the patch scale in a species rich tropical river. Oecologia 144, 157167.CrossRefGoogle Scholar
Baselga, A (2012) The relationship between species replacement, dissimilarity derived from nestedness, and nestedness. Global Ecology and Biogeography 21, 12231232.CrossRefGoogle Scholar
Borges, SH, D’Aquino, DD, Victória da Cruz, M and Felipe de Souza, R (2023) Turnover in fish species composition is related to water colour of Amazonian rivers. Journal of Tropical Ecology 39, 18.CrossRefGoogle Scholar
Botta-Dukát, Z and Czúcz, B (2016) Testing the ability of functional diversity indices to detect trait convergence and divergence using individual-based simulation. Methods in Ecology and Evolution 7, 114126.CrossRefGoogle Scholar
Brown, JH, Fox, BJ and Kelt, DA (2000) Assembly rules: desert rodent communities are structured at scales from local to continental. The American Naturalist 156, 314321.CrossRefGoogle ScholarPubMed
Cadotte, MW, Carscadden, K and Mirotchnick, N (2011) Beyond species: functional diversity and the maintenance of ecological processes and services. Journal of Applied Ecology 48, 10791087.CrossRefGoogle Scholar
Cadotte, MW and Tucker, CM (2017) Should environmental filtering be abandoned? Trends in Ecology & Evolution 32, 429437.CrossRefGoogle ScholarPubMed
Carvalho, RA and Tejerina-Garro, FL (2015a) The influence of environmental variables on the functional structure of headwater stream fish assemblages: a study of two tropical basins in Central Brazil. Neotropical Ichthyology 13, 349360.CrossRefGoogle Scholar
Carvalho, RA and Tejerina-Garro, FL (2015b) Environmental and spatial processes: what controls the functional structure of fish assemblages in tropical rivers and headwater streams? Ecology of Freshwater Fish 24, 317328.CrossRefGoogle Scholar
Casatti, L, Teresa, FB, de Oliveira Zeni, J, Ribeiro, MD, Brejao, GL and Ceneviva-Bastos, M (2015) More of the same: high functional redundancy in stream fish assemblages from tropical agroecosystems. Environmental Management 55, 13001314.CrossRefGoogle ScholarPubMed
Chase, JM (2007) Drought mediates the importance of stochastic community assembly. Proceedings of the National Academy of Sciences 104, 1743017434.CrossRefGoogle ScholarPubMed
Córdova-Tapia, F and Zambrano, L (2016) Fish functional groups in a tropical wetland of the Yucatan Peninsula, Mexico. Neotropical Ichthyology 14, e150162.CrossRefGoogle Scholar
Córdova-Tapia, F, Hernández-Marroquín, V and Zambrano, L (2018) The role of environmental filtering in the functional structure of fish communities in tropical wetlands. Ecology of Freshwater Fish 27, 522532.CrossRefGoogle Scholar
Erős, T (2017) Scaling fish metacommunities in stream networks: synthesis and future research avenues. Community Ecology 18, 7286.CrossRefGoogle Scholar
Fitzgerald, DB, Winemiller, KO, Sabaj Pérez, MH and Sousa, LM (2017) Seasonal changes in the assembly mechanisms structuring tropical fish communities. Ecology 98, 2131.CrossRefGoogle ScholarPubMed
Fonseca, CR and Ganade, G (2001) Species functional redundancy, random extinctions and the stability of ecosystems. Journal of Ecology 89, 118125.CrossRefGoogle Scholar
Heino, J, Melo, AS and Bini, LM (2015) Reconceptualising the beta diversity-environmental heterogeneity relationship in running water systems. Freshwater Biology 60, 223235.CrossRefGoogle Scholar
Kembel, SW, Cowan, PD, Helmus, MR, Cornwell, WK, Morlon, H, Ackerly, DD, Blomberg, SP and Webb, CO (2010) Picante: R tools for integrating phylogenies and ecology. Bioinformatics 26, 14631464.CrossRefGoogle ScholarPubMed
Legendre, P (2014) Interpreting the replacement and richness difference components of beta diversity. Global Ecology and Biogeography 23, 13241334.CrossRefGoogle Scholar
Leibold, MA and Chase, JM (2017) Metacommunity Ecology. Princeton, NJ: Princeton University Press.CrossRefGoogle Scholar
López-Delgado, EO, Winemiller, KO and Villa-Navarro, FA (2019) Do metacommunity theories explain spatial variation in fish assemblage structure in a pristine tropical river? Freshwater Biology 64, 367379.CrossRefGoogle Scholar
López-Delgado, EO, Winemiller, KO and Villa-Navarro, FA (2020) Local environmental factors influence beta-diversity patterns of tropical fish assemblages more than spatial factors. Ecology 101, e02940.CrossRefGoogle ScholarPubMed
Lowe-McConnell, RH (1964) The fishes of the Rupununi savanna district of British Guiana. Pt. 1. Groupings of fish species and effects of the seasonal cycles on the fish. Journal of the Linnean Society of London, Zoology 45, 103144.CrossRefGoogle Scholar
Lowe-McConnell, RH (1987) Ecological Studies in Tropical Fish Communities. Cambridge, England: Cambridge University Press.CrossRefGoogle Scholar
Maire, E, Grenouillet, G, Brosse, S and Villéger, S (2015) How many dimensions are needed to accurately assess functional diversity? A pragmatic approach for assessing the quality of functional spaces. Global Ecology and Biogeography 24, 728740.CrossRefGoogle Scholar
Mason, NWH, Lanoiselée, C, Mouillot, D, Irz, P and Argillier, C (2007) Functional characters combined with null models reveal inconsistency in mechanisms of species turnover in lacustrine fish communities. Oecologia 153, 441452.CrossRefGoogle ScholarPubMed
Mason, NWH, Irz, P, Lanoisele, C, Mouillot, D and Argillier, C (2008) Evidence that niche specialization explains species-energy relationships in lake fish communities. Journal of Animal Ecology 77, 285296.CrossRefGoogle ScholarPubMed
Montaña, CG, Winemiller, KO and Sutton, A (2014) Intercontinental comparison of fish ecomorphology: null model tests of community assembly at the patch scale in rivers. Ecological Monographs 84, 91107.CrossRefGoogle Scholar
Mouchet, MA, Mason, WH and Mouillot, D (2010) Functional diversity measures: an overview of their redundancy and their ability to discriminate community assembly rules. Functional Ecology 24, 867876.CrossRefGoogle Scholar
Mouchet, MA, Burns, MD, Garcia, AM, Vieira, JP and Mouillot, D (2013) Invariant scaling relationship between functional dissimilarity and co-occurrence in fish assemblages of the Patos Lagoon estuary (Brazil): Environmental filtering consistently overshadows competitive exclusion. Oikos 122, 247257.CrossRefGoogle Scholar
Mouillot, D, Dumay, O and Tomasini, JA (2007) Limiting similarity, niche filtering and functional diversity in coastal lagoon fish communities. Estuarine, Coastal and Shelf Science 71, 443456.CrossRefGoogle Scholar
Mouillot, D, Graham, NA, Villéger, S, Mason, NW and Bellwood, DR (2013) A functional approach reveals community responses to disturbances. Trends in Ecology & Evolution 28, 167177.CrossRefGoogle ScholarPubMed
Oliveira, FJM, Bini, LM, Lima, LB and Lima-Junior, DP (2023) Environmental and spatial factors are poor predictors of fish beta diversity in Cerrado streams. Oecologia Australis 27, 389402.CrossRefGoogle Scholar
Pillar, VD, Blanco, CC, Müller, SC, Sosinski, EE, Joner, F and Duarte, LD (2013) Functional redundancy and stability in plant communities. Journal of Vegetation Science 24, 963974.CrossRefGoogle Scholar
R Core Team (2020) R: A Language and Environment for Statistical Computing. Vienna, Austria: R Foundation for Statistical Computing.Google Scholar
Rodrigues-Filho, CAS, Gurge-Lourenço, RC, Queiroz Lima, SM, Fontes de Oliveira, E and Sánchez-Botero, JI (2017) What governs the functional diversity patterns of fishes in the headwater streams of the humid forest enclaves: environmental conditions, taxonomic diversity or biotic interactions? Environmental Biology of Fishes 100, 10231032.CrossRefGoogle Scholar
Santos, LL, Benone, NL, Soares, BE, Barthem, RB and Montag, LF (2019) Trait–environment relationships in Amazon stream fish assemblages. Ecology of Freshwater Fish 28, 424433.CrossRefGoogle Scholar
Spasojevic, MJ and Suding, KN (2012) Inferring community assembly mechanisms from functional diversity patterns: the importance of multiple assembly processes. Journal of Ecology 100, 652661.CrossRefGoogle Scholar
Su, G, Villéger, S and Brosse, S (2018) Morphological diversity of freshwater fishes differs between realms, but morphologically extreme species are widespread. Global Ecology and Biogeography 28, 211221.CrossRefGoogle Scholar
Swenson, NG (2014) Functional and Phylogenetic Ecology in R. New York: Springer.CrossRefGoogle Scholar
Teresa, FB and Casatti, L (2012) Influence of forest cover and mesohabitat types on functional and taxonomic diversity of fish communities in Neotropical lowland streams. Ecology of Freshwater Fish 21, 433442.CrossRefGoogle Scholar
Thakur, MP and Wright, AJ (2017) Environmental filtering, Niche construction, and trait variability: the missing discussion. Trends in Ecology & Evolution 32, 884886.CrossRefGoogle ScholarPubMed
Toussaint, A, Charpin, N, Brosse, S and Villéger, S (2016) Global functional diversity of freshwater fish is concentrated in the Neotropics while functional vulnerability is widespread. Scientific Reports 6, 22125.CrossRefGoogle ScholarPubMed
Villéger, S, Brosse, S, Mouchet, M, Mouillot, D and Vanni, MJ (2017) Functional ecology of fish: current approaches and future challenges. Aquatic Sciences 79, 783801.CrossRefGoogle Scholar
Villéger, S, Grenouillet, G and Brosse, S (2013) Decomposing functional β-diversity reveals that low functional β-diversity is driven by low functional turnover in European fish assemblages. Global Ecology and Biogeography 22, 671681.CrossRefGoogle Scholar
Villéger, S, Mason, NW and Mouillot, D (2008) New multidimensional functional diversity indices for a multifaceted framework in functional ecology. Ecology 89, 22902301.CrossRefGoogle ScholarPubMed
Vitorino Júnior, OB, Fernandes, R, Agostinho, CS and Pelicice, FM (2016) Riverine networks constrain β-diversity patterns among fish assemblages in a large Neotropical river. Freshwater Biology 61, 17331745.CrossRefGoogle Scholar
Vitule, JRS, Agostinho, AA, Azevedo-Santos, VM, Daga, VS, Darwall, WRT, Fitzgerald, DB, Frehse, FA, Hoeinghaus, DJ, Lima, DP Jr, Magalhães, ALB, Orsi, ML, Padial, AA, Pelicice, FM, Petrere, M Jr, Pompeu, PS and Winemiller, KO (2017) We need better understanding about functional diversity and vulnerability of tropical freshwater fishes. Biodiversity and Conservation 26, 757762.CrossRefGoogle Scholar
Weinstein, BG, Tinoco, B, Parra, JL, Brown, LM, McGuire, JA, Stiles, FG and Graham, CH (2014) Taxonomic, phylogenetic, and trait beta diversity in South American hummingbirds. The American Naturalist 184, 211224.CrossRefGoogle ScholarPubMed
Winemiller, KO (1989) Patterns of variation in life history among South American fishes in seasonal environments. Oecologia 81, 225241.CrossRefGoogle ScholarPubMed
Winemiller, KO (1990) Spatial and temporal variation in tropical fish trophic networks. Ecological Monographs 60, 331367.CrossRefGoogle Scholar
Winemiller, KO (1991) Ecomorphological diversification in lowland freshwater fish assemblages from five biotic regions. Ecological Monographs 61, 343365.CrossRefGoogle Scholar
Winemiller, KO, Fitzgerald, DB, Bower, LM and Pianka, ER (2015) Functional traits, convergent evolution, and periodic tables of niches. Ecology Letters 18, 737751.CrossRefGoogle ScholarPubMed
Winemiller, KO, López Fernández, H, Taphorn, DC, Nico, LG and Barbarino Duque, A (2008) Fish assemblages of the Casiquiare River, a corridor and zoogeographic filter for dispersal between the Orinoco and Amazon basins. Journal of Biogeography 35, 15511563.CrossRefGoogle Scholar
Winemiller, KO, Taphorn, DC, Kelso-Winemiller, LC, López-Delgado, EO, Keppeler, FW and Montaña, CG (2018) Fish metacommunity structure in Caño Maraca, an important nursery habitat in the Western Llanos of Venezuela. Neotropical Ichthyology 16, e180074.CrossRefGoogle Scholar
Figure 0

Figure. 1. Locations of the 34 sites sampled within the Bita River Basin; rectangles group sites according to sections along the longitudinal fluvial gradient.

Figure 1

Figure. 2. Comparison of standard effect size (deviation of observed values from random expectations) of six functional diversity indices of fish assemblages in four sections of the Bita River Basin. A value of zero (dotted line) indicates the mean for randomly assembled communities. Observed values above the dotted line indicate overdispersion of species in functional trait space, and values below the line indicate under-dispersion of the metrics: functional richness (FRic), functional divergence (FDiv), functional evenness (FEve), functional dispersion (FDis), functional specialization (FSpe), functional originality (FOri), and functional redundancy (FRed).

Figure 2

Table 1. Mean values (± standard deviation) of functional beta diversity (FBeta), functional turnover (FTurn), and functional nestedness (FNes) calculated at the scale of the entire river basin and for each river section. Fpturn refers to the contribution of turnover to functional beta diversity (Fpturn = FTurn/FBeta)

Figure 3

Figure 3. Variation partitioning analysis. (a) functional β diversity, (b) turnover, and (c) functional nestedness. Circles are not drawn to scale, values represent the adjusted R2, and negative fractions values are not shown.

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