Habitat connectivity is determined by the scale of habitat loss and dispersal strategy

Edelsparre, Allan H.; Shahid, Ashif; Fitzpatrick, Mark

doi:10.1002/ece3.4072

Cited by 21 publications

(18 citation statements)

References 39 publications

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“…For example, at the habitat scale, if we know that wild bees of a certain feeding guild rely on certain habitat features such as perennial vegetation, we can inform city policies on vegetation management within city parks and roadsides (Aronson et al 2016;Turo and Gardiner 2019). At the landscape scale, if we understand that certain landscape features such as high habitat connectivity promote species of short flight distances that are critical to pollination services (Edelsparre et al 2018), we can guide city planning to prioritize habitats that connect to other habitats across a city. Aside from biological traits, functional diversity comprises components of biodiversity that are linked to ecosystem processes and therefore adds additional ecological information to typical measures of taxonomic diversity (Magurran and McGill 2011).…”

Section: Introductionmentioning

confidence: 99%

Functional ecology of wild bees in cities: towards a better understanding of trait-urbanization relationships

Buchholz

Egerer

2020

Biodivers Conserv

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A functional ecological understanding of urban wild bee communities is of growing importance especially in regard to biodiversity conservation, ecosystem service maintenance and effective conservation programmes. In this paper, we review and summarize the published literature aiming to inform future research investigations in the growing field of wild bee functional ecology. Specifically, we: (1) review which functional trait-based analyses have been carried out on wild bees in cities thus far; (2) summarize which wild bee species traits have been considered; (3) evaluate any consistent wild bee trait-environment relationships (i.e. urbanization) across studies; and (4) synthesize findings and limitations to inform future research recommendations. We reviewed 48 studies based on a systematic Web of Knowledge search. We found consistent trait characteristics for 'nesting type', 'diet', 'body size', 'sociality' and 'phenology' across studies. More than one third of the studies were descriptive and the majority of studies were located in urban gardens in temperate Europe and North America, calling for more research from underrepresented geographic regions and from the entire spectrum of urban habitat types. Of these studies, only five analyzed functional diversity indices and three studies applied statistics to relate urban wild bee traits to urbanization factors. Future studies should consider trait-based statistics, and could incorporate functional trait-based ecological networks to examine network shifts across urbanization gradients. Our review suggests that we lack generalizable information about wild bee trait and urbanization relationships yet, making conservation recommendations challenging. Therefore, we propose more research that considers methodological recommendations to develop a comparable and comprehensive understanding of how urbanization affects the functional ecology of urban wild bees to link with specific urban conservation measures.

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Section: Introductionmentioning

confidence: 99%

Functional ecology of wild bees in cities: towards a better understanding of trait-urbanization relationships

Buchholz

Egerer

2020

Biodivers Conserv

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“…Dispersal is a central issue for the understanding of evolutionary processes and population dynamics 1 , 2 , with profound implications for current spatial distributions, local population densities, demographic dynamics, and the genetics of spatially-structured populations 3 – 5 . Moreover, dispersal processes are important because of their implications for forecasting animal distributions and for robust decision-making in the areas of resource management and conservation of biodiversity 6 .…”

Section: Introductionmentioning

confidence: 99%

Individual differences in dominance-related traits drive dispersal and settlement in hatchery-reared juvenile brown trout

Sánchez-González

Nicieza

2021

Sci Rep

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Effective management of exploited populations is based on an understanding of population dynamics and evolutionary processes. In spatially structured populations, dispersal is a central process that ultimately can affect population growth and viability. It can be influenced by environmental conditions, individual phenotypes, and stochastic factors. However, we have a limited knowledge of the relative contribution of these components and its interactions, and which traits can be used as reliable predictors of the dispersal ability. Here, we conducted a longitudinal field experiment aimed to identify traits which can be used as proxy for dispersal in juvenile brown trout (Salmo trutta L.). We measured body size and standard metabolic rates, and estimated body shapes for 212 hatchery-reared juvenile fish that were marked with individual codes and released in a small coastal stream in northwest Spain. We registered fish positions and distances to the releasing point after 19, 41, 60 and 158 days in the stream. We detected a high autocorrelation of dispersal distances, demonstrating that most individuals settle down relatively soon and then hold stable positions over the study period. Body size and fish shape were reliable predictors of dispersal, with bigger and more robust-set individuals being more likely to settle closer to the release site than smaller and more elongated fish. In addition, the analysis of spacing and spatial patterns indicated that the dispersal of introduced fish could affect the distribution of resident conspecifics. All together, these results suggest that stocking programs aimed to the enhancement of overexploited populations at fine spatial scales can be optimized by adjusting the size and shape of the introduced fish to specific management targets and environmental conditions.

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“…To evaluate how strain-differences in behaviour influence dispersal of flies in the field we used two inbred strains (rover-for R and sitter-for s ) and one outbred strain of flies. The effect of for on the dispersal strategy of the rover and sitter inbred strains was documented in Edelsparre et al (2014) and Edelsparre et al (2018). The outbred population was established from 92 iso-female lines originally collected in Sudbury, Ontario, Canada (501484.97 E, 5143198.65 N UTM) on August 12, 2012 by Thomas Merritt.…”

Section: Fly Linesmentioning

confidence: 99%

“…To accomplish this we first produced a large outbred study population from field collected flies. Secondly, we incorporated individual-level predictors of dispersal by using Drosophila melanogaster that carry variants of a gene known to influence differences in the propensity of the adult fly to disperse (Edelsparre et al 2014;Edelsparre et al 2018). This particular Drosophila system consists of two strains of flies that differ in several movement related behaviours both as larvae and adults and these differences are mediated by natural variation in the foraging (for) gene (Osborne et al 1987;de Belle et al 1993;Pereira and Sokolowski 1993;Edelsparre et al 2014).…”

Section: Introductionmentioning

confidence: 99%

Scaling up: understanding movement from individual differences to population-level dispersal

Edelsparre

Hefley

Rodríguez

et al. 2021

Preprint

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Dispersal is fundamental to life on our planet. Dispersal facilitates colonization of continents and islands. Dispersal mediates gene flow among populations, and influences the rate of spread of invasive species. Theory suggests that individuals consistently differ in dispersal propensity, however determining the relative contributions of environmental factors to individual and population-level dispersal, represent a major challenge to understand the spread of organisms. To address this, we conducted a field experiment using Drosophila melanogaster. As proxies for individuals with different dispersal propensities, we used wildtype strains of flies with natural variants of the foraging gene, known to influence dispersal in laboratory and field experiments. These included flies with fors alleles known to be less dispersive, flies with the forR alleles which are more dispersive flies as well as an outbred population established from field collected flies. We released approximately 6000 flies of each strain in an experimental arena (100 m × 100 m) in the field and our recaptures were used to determine dispersal of flies over time. To estimate environmental effects on dispersal, we measured temperature, wind direction and wind speed. Using partial-differential equations we combined ecological diffusion with advection to estimate dispersal rates and responses to wind. We found that temperature effects elicited a similar response in high and low dispersal lab strains with dispersal rate increasing with temperature most rapidly at temperatures above 18°C. This was in contrast to outbred flies which remained unresponsive to temperature changes. We also detected a response to wind with advection rates increasing linearly with wind speed for all flies in general. Our results suggest that response to temperature and wind can minimize known differences in behavioural predispositions to disperse. Our results also suggest that the direction and magnitude of wind may play a key role in the colonization and distribution of fly populations. Our findings therefore have implications for forecasting the spread of pests and invasive species as well as pathogens and vectors of disease. Our findings further contribute to the understanding of how the environment can modify behavioural predispositions and to influence population-level dispersal in fly populations in particular and insect species in general.

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Habitat connectivity is determined by the scale of habitat loss and dispersal strategy

Cited by 21 publications

References 39 publications

Functional ecology of wild bees in cities: towards a better understanding of trait-urbanization relationships

Functional ecology of wild bees in cities: towards a better understanding of trait-urbanization relationships

Individual differences in dominance-related traits drive dispersal and settlement in hatchery-reared juvenile brown trout

Scaling up: understanding movement from individual differences to population-level dispersal

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