Taxonomic, functional, and phylogenetic dimensions of rodent biodiversity along an extensive tropical elevational gradient

Dreiss, Lindsay M.; Burgio, Kevin R.; Cisneros, Laura M.; Klingbeil, Brian T.; Patterson, Bruce D.; Presley, Steven J.; Willig, Michael R.

doi:10.1111/ecog.00971

Cited by 62 publications

(82 citation statements)

References 87 publications

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“…This could be due to current and historic isolation, and environmental filtering or local adaptation to different environmental conditions. These results are in line with previous work that highlighted a general congruence between dimensions but also a decoupling in some regions for both alpha and beta diversity [19,[46][47][48][49].…”

Section: Discussionsupporting

confidence: 93%

Global mammal beta diversity shows parallel assemblage structure in similar but isolated environments

et al. 2016

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The taxonomic, phylogenetic and trait dimensions of beta diversity each provide us unique insights into the importance of historical isolation and environmental conditions in shaping global diversity. These three dimensions should, in general, be positively correlated. However, if similar environmental conditions filter species with similar trait values, then assemblages located in similar environmental conditions, but separated by large dispersal barriers, may show high taxonomic, high phylogenetic, but low trait beta diversity. Conversely, we expect lower phylogenetic diversity, but higher trait biodiversity among assemblages that are connected but are in differing environmental conditions. We calculated all pairwise comparisons of approximately 110 Â 110 km grid cells across the globe for more than 5000 mammal species (approx. 70 million comparisons). We considered realms as units representing geographical distance and historical isolation and biomes as units with similar environmental conditions. While beta diversity dimensions were generally correlated, we highlight geographical regions of decoupling among beta diversity dimensions. Our analysis shows that assemblages from tropical forests in different realms had low trait dissimilarity while phylogenetic beta diversity was significantly higher than expected, suggesting potential convergent evolution. Low trait beta diversity was surprisingly not found between isolated deserts, despite harsh environmental conditions. Overall, our results provide evidence for parallel assemblage structure of mammal assemblages driven by environmental conditions at a global scale.

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Section: Discussionsupporting

confidence: 93%

Global mammal beta diversity shows parallel assemblage structure in similar but isolated environments

et al. 2016

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“…Because of their low dispersal capacity, understory birds, like many Tyranni, have a greater genetic divergence when compared to canopy birds (Burney & Brumfield, ; Hawkins, Diniz‐Filho, Jaramillo, & Soeller, ) and this may also have led to a high diversity of lineages within this suborder (Smith et al., ). In addition, forests with greater structural complexity and productivity, such as those existing in South America, allow greater diversification and persistence of species, through having a higher number and variety of available niches (Dreiss et al., ).…”

Section: Discussionmentioning

confidence: 99%

The influence of biogeographic history on the functional and phylogenetic diversity of passerine birds in savannas and forests of the Brazilian Amazon

Almeida

Juen

Sobral

et al. 2018

Ecology and Evolution

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Passeriformes is the largest and most diverse avian order in the world and comprises the Passeri and Tyranni suborders. These suborders constitute a monophyletic group, but differ in their ecology and history of occupation of South America. We investigated the influence of biogeographic history on functional and phylogenetic diversities of Passeri and Tyranni in forest and savanna habitats in the Brazilian Amazon. We compiled species composition data for 34 Passeriformes assemblages, 12 in savannas and 22 in forests. We calculated the functional (Rao's quadratic entropy, FDQ) and phylogenetic diversities (mean pairwise distance, MPD, and mean nearest taxon distance, MNTD), and the functional beta diversity to investigate the potential role of biogeographic history in shaping ecological traits and species lineages of both suborders. The functional diversity of Passeri was higher than for Tyranni in both habitats. The MPD for Tyranni was higher than for Passeri in forests; however, there was no difference between the suborders in savannas. In savannas, Passeri presented higher MNTD than Tyranni, while in forest areas, Tyranni assemblages showed higher MNTD than Passeri. We found a high functional turnover (~75%) between Passeri and Tyranni in both habitats. The high functional diversity of Passeri in both habitats is due to the high diversity of ecological traits exhibited by species of this group, which enables the exploitation of a wide variety of resources and foraging strategies. The higher Tyranni MPD and MNTD in forests is likely due to Tyranni being older settlers in this habitat, resulting in the emergence and persistence of more lineages. The higher Passeri MNTD in savannas can be explained by the existence of a larger number of different Passeri lineages adapted to this severe habitat. The high functional turnover between the suborders in both habitats suggests an ecological strategy to avoid niche overlap.

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“…As easily obtained measurements of functional characters, morphological and behavioral traits are widely used in functional analysis of animal communities (Cisneros et al., ; Dreiss et al., ; Stevens & Gavilanez, ). For morphological dimensions of the rodent community structure, we chose the head–body length (HL) and tail/body ratio (TR) as ecologically relevant traits, which in mammalian organisms are known to determine thermoregulation, interspecific exclusion, and resource use capacities (Bowers & Brown, ; Ge et al., ; Hayssen, ; Hume, Morgan, & Kenagy, ; Kotler, Brown, Smith, & Wirtz, ; Persson, ; see Table ).…”

Section: Methodsmentioning

confidence: 99%

“…These unique historical events should have left distinct evolutionary imprints on the elevational patterns of trait diversity. Rodentia, the most diverse lineage of mammals (Fabre, Hautier, Dimitrov, & Douzery, ; Wilson & Reeder, ), offers an ideal model for understanding assembly processes in small mammal communities (Dreiss et al., ; Stevens & Gavilanez, ; Stevens, Gavilanez, Tello, & Ray, ; Stevens & Tello, ). Taking rodents in the HMs as our study model, we aim to (1) quantify the elevational pattern of functional dispersion in rodent communities.…”

Section: Introductionmentioning

confidence: 99%

The roles of environment, space, and phylogeny in determining functional dispersion of rodents (Rodentia) in the Hengduan Mountains, China

Wen

Zhang³

et al. 2017

Ecology and Evolution

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The recently described trait‐based approach is becoming widely popular for a mechanistic understanding of species coexistence. However, the greatest challenge in functional analyses is decomposing the contributions of different ecological and evolutionary processes (e.g., niche‐based process, neutral process, and evolutionary process) in determining trait structure. Taking rodents (Rodentia) in the Hengduan Mountains as our study model, we aim to (1) quantify the vertical patterns of functional structure for head–body length (HL), tail/body ratio (TR), animal component in diet (ACD), and all traits; (2) disentangle the relative importance of different assembly processes (environment, space, and phylogeny) in structuring trait dispersion; and (3) assess the feasibility of Bergmann's rule and Allen's rule along elevational gradient. Our results have suggested that the vertical functional structure pattern varied across these three traits, indicating distinct functional roles in the community assembly process. These nonrandom vertical patterns of HL, TR, and terminal ACD have demonstrated these traits were dominated by different ecological process along environmental gradient. In variance partitioning, high proportion of the spatial variations in trait dispersion was explained by environmental and spatial models, which have provided supporting strong evidence for niche‐based and neutral processes in leading species coexistence. Although the three traits all exhibited apparent phylogenetic signals, phylogenetic relationship within community failed to predict the spatial variations of functional dispersion, confirming the enormous inference of phylogenetic signals in predicting trait structure. By assessing the vertical patterns of HL and TR at order and family levels, we argued that functional adaptation along an environmental gradient is a surrogate of series of complex processes (e.g., environmental filtering, interspecific interaction, and neutral dispersal) acting on multiple functional axes, which results in inconsistence with the empirical rules along elevational gradient.

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Taxonomic, functional, and phylogenetic dimensions of rodent biodiversity along an extensive tropical elevational gradient

Cited by 62 publications

References 87 publications

Global mammal beta diversity shows parallel assemblage structure in similar but isolated environments

Global mammal beta diversity shows parallel assemblage structure in similar but isolated environments

The influence of biogeographic history on the functional and phylogenetic diversity of passerine birds in savannas and forests of the Brazilian Amazon

The roles of environment, space, and phylogeny in determining functional dispersion of rodents (Rodentia) in the Hengduan Mountains, China

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