Functional and Taxonomic Beta Diversity of Saproxylic Beetles in Mediterranean Forests: On What Factors Do They Depend?

Abstract Understanding how biodiversity is distributed across geographical and environmental gradients is a main goal of diversity sciences. However, since ecosystem processes are linked to variation in functional traits of the biota, examining functional beta diversity is particularly important. Our objective was to analyze the taxonomic and functional beta diversity patterns of saproxylic beetle assemblages in evergreen Quercus forest of Spain. We tested whether environmental or geographical distance had a greater influence on taxonomic and functional beta diversity, and if both measures of beta diversity were affected by the same environmental variables. We used 45 flight interception traps distributed in three protected areas over a 12-mo period to sample saproxylic beetles. We measured 13 environmental variables around each trap and the geographical distance between traps. For functional composition, we used 12 functional traits from four functional groups (morphological, phenological, trophic, and a surrogate of physiological). Our results showed that environmental differences between areas influenced the taxonomic and functional beta diversity components (replacement and loss/gain) but in different ways. While replacement components (higher for taxonomic composition) increased with environmental distance, the loss or gain components (higher for functional composition) remained constant, indicating that species replacement mostly involved functionally redundant species. Besides, environmental variables influencing both taxonomic and functional composition were strongly dependent on each area. In conclusion, in well-preserved Mediterranean forests, environmental filtering determines the taxonomic and functional composition of saproxylic beetle assemblages, by favoring species replacement but filtering species traits.

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Influence of Traditional Management and Environmental Variables on Mediterranean Saproxylic Beetle Assemblages

Environmental Entomology ◽

10.1093/ee/nvx140 ◽

2017 ◽

Vol 46 (6) ◽

pp. 1235-1242 ◽

Cited By ~ 4

Author(s):

P Ramilo ◽

A P Martínez-Falcón ◽

A García-López ◽

H Brustel ◽

E Galante ◽

...

Keyword(s):

Environmental Variables ◽

Traditional Management ◽

Beetle Assemblages ◽

Saproxylic Beetle

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Factors that influence the beta-diversity of spider communities in northwestern Argentinean Grasslands

PeerJ ◽

10.7717/peerj.1946 ◽

2016 ◽

Vol 4 ◽

pp. e1946 ◽

Cited By ~ 14

Author(s):

Sandra M. Rodriguez-Artigas ◽

Rodrigo Ballester ◽

Jose A. Corronca

Keyword(s):

Beta Diversity ◽

Environmental Variables ◽

Regional Scale ◽

Geographic Distance ◽

Species Replacement ◽

Community Similarity ◽

Dispersal Capacity ◽

Assembly Structure ◽

Dispersion Capacity ◽

Spider Communities

Beta-diversity, defined as spatial replacement in species composition, is crucial to the understanding of how local communities assemble. These changes can be driven by environmental or geographic factors (such as geographic distance), or a combination of the two. Spiders have been shown to be good indicators of environmental quality. Accordingly, spiders are used in this work as model taxa to establish whether there is a decrease in community similarity that corresponds to geographic distance in the grasslands of the Campos & Malezales ecoregion (Corrientes). Furthermore, the influence of climactic factors and local vegetation heterogeneity (environmental factors) on assemblage composition was evaluated. Finally, this study evaluated whether the differential dispersal capacity of spider families is a factor that influences their community structure at a regional scale. Spiders were collected with a G-Vac from vegetation in six grassland sites in the Campos & Malezales ecoregion that were separated by a minimum of 13 km. With this data, the impact of alpha-diversity and different environmental variables on the beta-diversity of spider communities was analysed. Likewise, the importance of species replacement and nesting on beta-diversity and their contribution to the regional diversity of spider families with different dispersion capacities was evaluated. The regional and site-specific inventories obtained were complete. The similarity between spider communities declined as the geographic distance between sites increased. Environmental variables also influenced community composition; stochastic events and abiotic forces were the principal intervening factors in assembly structure. The differential dispersal capacity of spider groups also influenced community structure at a regional scale. The regional beta-diversity, as well as species replacement, was greater in high and intermediate vagility spiders; while nesting was greater in spiders with low dispersion capacity. Geographic distance, among other factors (climate, and active and passive dispersion capacity), explains assembly structure and the decrease spider community similarity between geographically distant sites. Spiders with the highest dispersal capacity showed greater species replacement. This may be due to the discontinuity (both natural and anthropic) of the grasslands in this ecoregion, which limits the dispersal capacity of these spiders, and their close dependence on microhabitats. The dispersal capacity of the least vagile spiders is limited by geographic distance and biotic factors, such as competition, which could explain the nesting observed between their communities.

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Contrasting beta diversity and functional composition of aquatic insect communities across local to regional scales in Amazonian streams

10.1101/2020.09.14.297077 ◽

2020 ◽

Author(s):

Gilberto Nicacio ◽

Erlane José Cunha ◽

Neusa Hamada ◽

Leandro Juen

Keyword(s):

Beta Diversity ◽

Geographic Distance ◽

Aquatic Insect ◽

Procrustes Analysis ◽

Functional Composition ◽

Species Replacement ◽

Environmental Predictors ◽

Insect Communities ◽

Trait Convergence ◽

Community Dissimilarity

AbstractWe investigated how components of beta diversity (i.e., the turnover and nestedness and functional compositional) aquatic insect assemblages change among sites and are influenced by environmental and spatial drivers. For this, we analyzed beta-diversity and functional composition of Ephemeroptera, Plecoptera, and Trichoptera in 16 streams in two Amazonian basins with distinct environmental conditions (the Carajás and Tapajós regions). We performed Multiple regression on dissimilarity matrices (MRM) and Procrustes analysis to test spatial and environmental influences on the taxonomic and functional composition of communities. Community dissimilarity was most related to variations in geographic distance and topography, which highlighted the environmental distances shaping the communities. Variation in functional composition could be mostly attributed to the replacement of species by those with similar traits, indicating trait convergence among communities. Environmental predictors best-explained species replacement and trait congruence within and between the regions evaluated. In summary, among communities with different taxonomic compositions, the high species replacement observed appears to be leading them to have similar community structure, with species having the same functional composition, even in communities separated by both small and large geographic distances.

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Fish Functional Traits Correlated with Environmental Variables in a Temperate Biodiversity Hotspot

PLoS ONE ◽

10.1371/journal.pone.0093237 ◽

2014 ◽

Vol 9 (3) ◽

pp. e93237 ◽

Cited By ~ 20

Author(s):

Benjamin P. Keck ◽

Zachary H. Marion ◽

Derek J. Martin ◽

Jason C. Kaufman ◽

Carol P. Harden ◽

...

Keyword(s):

Functional Traits ◽

Environmental Variables ◽

Biodiversity Hotspot

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Canopy Leaf Traits, Basal Area, and Age Predict Functional Patterns of Regenerating Communities in Secondary Subtropical Forests

Frontiers in Forests and Global Change ◽

10.3389/ffgc.2021.572864 ◽

2021 ◽

Vol 4 ◽

Author(s):

Sandra Cristina Müller ◽

Rodrigo Scarton Bergamin ◽

Kauane Maiara Bordin ◽

Joice Klipel ◽

Milena Fermina Rosenfield

Keyword(s):

Functional Diversity ◽

Functional Traits ◽

Natural Regeneration ◽

Basal Area ◽

Leaf Traits ◽

Leaf Nitrogen ◽

Ecosystem Functions ◽

Secondary Forests ◽

Functional Composition ◽

Forest Age

Secondary forests originate from natural regeneration after fallow (succession) or restoration. Species assembly in these communities, which can affect ecosystem functions and successional trajectories, is very unpredictable. Trait-based trajectories can shed light on the recovery of ecosystem functions and enable predictions of how the regenerating communities will change with forest age. Regeneration communities are affected by initial conditions and also by canopy structure and functional traits that alter dispersers' attractiveness and coexistence mechanisms. Here we evaluated how community functional traits change over time and tested if functional diversity and composition of the established canopy, as well as the structure of the canopy and forest age, influence the functional structure of regenerating tree communities when compared to their reference forests. For this, we calculated dissimilarity in trait composition (community-weighted means) and in functional diversity of regenerating communities of each succession/restoration stand, using the tree stratum of nearby mature forests as baseline values. Functional trait information comprises leaf, wood density, and reproductive traits from tree species. Our community data contain information from natural successional forests and restoration sites, in the South-Brazilian Atlantic Forest. Predictor variables of functional dissimilarities were forest age, canopy structural variables, canopy functional composition, and functional diversity. Results showed leaf traits (leaf dry matter content, leaf nitrogen content, leaf nitrogen-phosphorus ratio) and seed mass varying with forest age. Canopy functional composition based on leaf traits and total basal area significantly predicted multiple trait functional dissimilarity between the regeneration component of secondary forests and their reference community values. Dissimilarity increased when the canopy was composed of species with more acquisitive traits. Difference in functional diversity was only influenced by forest age. Mid-stage secondary forests showed lower functional diversity than early-stage forests. Our results indicated the importance of canopy traits on the natural regeneration of secondary subtropical forests. If functional similarity with reference forests is a desired objective in order to recover ecosystem functions through natural regeneration, leaf functional traits of canopy trees that establish or are planted in degraded areas must be considered in the successional processes.

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