How to Become a Generalist Species? Individual Niche Variation Across Habitat Transformation Gradients

Liang, Dan; Yang, Shengnan; Pagani‐Núñez, Emilio; He, Chao; Liu, Yang; Goodale, Eben; Liao, Wen Bo; Hu, Junhua

doi:10.3389/fevo.2020.597450

Cited by 16 publications

(6 citation statements)

References 66 publications

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“…Notably, amphibians are particularly vulnerable to environmental stresses and changes due to their highly permeable skin, unshelled eggs, and low dispersal abilities [ 10 ]. Previous studies have explained how amphibians respond to environmental changes through different strategies, such as niche shift [ 11 , 12 , 13 ], phenological changes [ 2 , 14 ], and variations in morphological traits [ 7 , 15 , 16 ]. Morphological variations that, in particular, reflect a strong link between an organism’s fitness and processes in the community and ecosystem, can help us understand how amphibians respond adaptively to environmental stresses and changes [ 4 ].…”

Section: Introductionmentioning

confidence: 99%

Morphological Variation and Its Environmental Correlates in the Taihangshan Swelled-Vented Frog across the Qinling Mountains

Wang

Yang

et al. 2022

Animals

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The Taihangshan swelled-vented frog (Feirana taihangnica), an endemic species to the Qinling Mountains, central China, has experienced a dramatic population decline over the last few decades. The aim of this work was to quantify morphological variation in F. taihangnica across the Qinling Mountains and examine environmental correlates of this variation of morphological traits. We implemented a hierarchical partitioning to estimate the independent contribution of each environmental variable on morphological variations. Temperature seasonality was the greatest contributor in variations of snout-vent length (SVL) and head width, and ultraviolet-B (UV-B) radiation of the lowest month was the most influential on both thigh length and tibia width. Then, we used generalized additive models to analyze the relationship between each environmental factor and morphological trait variations. Along the increasing of annual mean temperature, SVL decreased firstly and then increased, indicating no support for Bergmann’s rule. Furthermore, SVL was negatively correlated with annual precipitation, while positively with temperature seasonality. The mean UV-B of the highest and lowest months was positively and negatively correlated with head width, thigh length and tibia width, respectively. The results of this study help us to understand adaptive potential of this mountain frog species via morphological variations in the light of environmental changes.

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Section: Introductionmentioning

confidence: 99%

Morphological Variation and Its Environmental Correlates in the Taihangshan Swelled-Vented Frog across the Qinling Mountains

Wang

Yang

et al. 2022

Animals

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“…This, combined with our findings that urban foraging is linearly linked to isotope values, suggests that both within‐ and between‐individual differences in urban foraging resulted in trophic niche expansion at the peri‐urban colonies. Liang et al (2020) reported similar findings in multiple passerine and frog species, where a combination of between‐ and within‐individual differences drove changes in trophic niche size across urban and natural populations. Several studies have found that urban diet items show distinctly different isotope values than natural diet items (Lato et al, 2021; Moreno et al, 2010; Shlepr et al, 2021), and thus likely further drives differences in isotopic values and niche sizes in urban populations.…”

Section: Discussionmentioning

confidence: 73%

Peri‐urban systems alter trophic niche size and overlap in sympatric coastal bird species

et al. 2023

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Urban habitats can create empty trophic niche space by providing abundant alternative dietary resources, allowing some generalist species to either shift or expand their trophic niches. Resulting changes to trophic niche size may consequently affect interspecific interactions and competition, although trophic impacts are less clear in peri‐urban systems, where both natural and urban resources are readily accessible to highly mobile species. We combined stable isotope (δ13C, δ15N, δ34S) data with GPS tracking of two sympatric coastal bird species (Larus argentatus, L. marinus) across four study sites on the east coast of the United States, ranging from a study site in New York City (the most populous city in the United States) to less‐urban sites off Massachusetts. We quantified the trophic niche size and trophic niche overlap in three‐dimensional isotopic space and assessed spatial overlap in foraging habitat between species at both peri‐urban and less‐urban study sites. We found that for both species, birds at peri‐urban study sites had significantly larger trophic niches than birds from the less‐urban sites. Furthermore, for study sites where both species occurred, we found that overlap in trophic niche space and foraging habitats between species was lower at the peri‐urban study site than at the less‐urban site. These results suggest that peri‐urban environments may facilitate trophic niche expansion and decrease niche overlap in mobile generalist species, contrasting with previous studies showing increased trophic niche overlap in more isolated urban populations. Following further analysis, we found that trophic niche expansion was facilitated by both within‐ and between‐individual differences in foraging strategies. We posit that peri‐urban environments, particularly along coastal areas, can reduce interspecific competition between sympatric species by providing access to a variety of natural and anthropogenic diet items, especially for highly mobile generalist consumers that can access both natural and urban foraging areas. Research assessing how and at what scale peri‐urban systems influence wildlife is key to understanding how further global urbanization will shape ecosystem structures.

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“…Traits that generally promote positive responses to urbanisation include high fecundity, strong dispersal ability, behavioural flexibility, and increased tolerance and/or habituation to human presence 4 – 10 , but it is usually species dependent as to which traits are the most favourable 11 , 12 . Recently published literature shows that diet generalists tend to exhibit a positive response more often than diet specialist species in urban ecosystems 13 , 14 , as generalist species occupy broader niches that allow them to tolerate a wider array of landscapes 15 – 17 and to explore a variety of different food resources 8 , 18 . As the world continues to urbanise 19 , 20 , understanding the species-specific traits that allow wildlife to survive within urban habitat is vital to maintain wildlife biodiversity.…”

Section: Introductionmentioning

confidence: 99%

Smaller Australian raptors have greater urban tolerance

Headland

Colombelli‐Négrel

Callaghan

et al. 2023

Sci Rep

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Urbanisation is occurring around the world at a rapid rate and is generally associated with negative impacts on biodiversity at local, regional, and global scales. Examining the behavioural response profiles of wildlife to urbanisation helps differentiate between species that do or do not show adaptive responses to changing landscapes and hence are more or less likely to persist in such environments. Species-specific responses to urbanisation are poorly understood in the Southern Hemisphere compared to the Northern Hemisphere, where most of the published literature is focussed. This is also true for raptors, despite their high diversity and comparably high conservation concern in the Southern Hemisphere, and their critical role within ecosystems as bioindicators of environmental health. Here, we explore this knowledge gap using community science data sourced from eBird to investigate the urban tolerance of 24 Australian raptor species at a continental scale. We integrated eBird data with a global continuous measure of urbanisation, artificial light at night (ALAN), to derive an urban tolerance index, ranking species from positive to negative responses according to their tolerance of urban environments. We then gathered trait data from the published literature to assess whether certain traits (body mass, nest substrate, habitat type, feeding guild, and migratory status) were associated with urban tolerance. Body size was negatively associated with urban tolerance, as smaller raptors had greater urban tolerance than larger raptors. Out of the 24 species analysed, 13 species showed tolerance profiles for urban environments (positive response), and 11 species showed avoidance profiles for urban environments (negative response). The results of this study provide impetus to conserve native habitat and improve urban conditions for larger-bodied raptor species to conserve Australian raptor diversity in an increasingly urbanised world.

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How to Become a Generalist Species? Individual Niche Variation Across Habitat Transformation Gradients

Cited by 16 publications

References 66 publications

Morphological Variation and Its Environmental Correlates in the Taihangshan Swelled-Vented Frog across the Qinling Mountains

Morphological Variation and Its Environmental Correlates in the Taihangshan Swelled-Vented Frog across the Qinling Mountains

Peri‐urban systems alter trophic niche size and overlap in sympatric coastal bird species

Smaller Australian raptors have greater urban tolerance

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