Untested assumptions about within-species sample size and missing data in interspecific studies

Garamszegi, László Zsolt; Møller, Anders Pape

doi:10.1007/s00265-012-1370-z

Cited by 25 publications

(16 citation statements)

References 75 publications

(63 reference statements)

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“…These results support the notion that while large ranges are bound to overlap with more sampling locations (compare Garamszegi & Møller, 2012), large, irregularly shaped ranges are severely constrained in the detail with which a given number of records could cover them. Range size was the single most important predictor, with a strong positive effect on record count and a strong negative effect on range coverage.…”

Section: Range Geometrymentioning

confidence: 99%

Range geometry and socio‐economics dominate species‐level biases in occurrence information

Meyer

Jetz

Guralnick

et al. 2016

Global Ecol. Biogeogr.

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Aim Despite the central role of species distributions in ecology and conservation, occurrence information remains geographically and taxonomically incomplete and biased. Efforts to address this problem, such as targeted data mobilization and advanced distribution modelling, all crucially rely on a solid understanding of the patterns and determinants of occurrence information. Numerous socio‐economic and ecological drivers of uneven record collection and mobilization among species have been suggested, but the generality of their effects remains untested. Here, we provide the first global analysis of patterns and drivers of species‐level variation in different metrics of occurrence information. Location Global, including separate analyses for six zoogeographical realms. Methods We evaluated three alternative metrics of occurrence information: (1) the record count per species, (2) the coverage of a range with records and (3) the geographical bias in how the records represent different range parts. To this end, we developed scale‐independent metrics of range coverage and geographical record bias. We applied the three metrics to 2.8 million point‐occurrence records and extent‐of‐occurrence range maps of 3625 mammalian species. We used multi‐model inference to evaluate 13 putative drivers of species‐level variation in data availability. Results All three metrics of occurrence information revealed severe species‐level biases. These data limitations were mainly linked to range size and shape, and the within‐range geography of socio‐economic conditions. Species attributes related to detection and collection probabilities, such as body size or diurnality, were remarkably weak predictors of record count and range coverage. Main conclusions Species‐level biases in mobilized occurrence information hamper its broader application in basic and applied biodiversity research. To successfully account for these limitations, the site‐specific socio‐economic constraints to record collection and mobilization, rather than species‐specific constraints to detection, should be explicitly incorporated into ecological models. Furthermore, our results strongly suggest that range‐restricted species should be prioritized in future data mobilization efforts.

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Section: Range Geometrymentioning

confidence: 99%

Range geometry and socio‐economics dominate species‐level biases in occurrence information

Meyer

Jetz

Guralnick

et al. 2016

Global Ecol. Biogeogr.

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“…An index of specialization is only as reliable as the underlying data. The quality of information about traits varies from species to species, might be incomplete or inaccurate in some cases, depending on the quality and number of studies conducted on each species (Ducatez & Lefebvre, ; Garamszegi & Møller, ; McKenzie & Robertson, ). Furthermore, the type of variable used to fill out the trait‐features can also influence the index.…”

Section: Discussionmentioning

confidence: 99%

Measuring avian specialization

Morelli

Benedetti

Møller

et al. 2019

Ecology and Evolution

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Measuring the extent to which a species is specialized is a major challenge in ecology, with important repercussions for fundamental research as well as for applied ecology and conservation. Here, we develop a multidimensional index of specialization based on five sets of ecological characteristics of breeding bird species. We used two recent databases of species traits of European birds based on foraging ecology, habitat, and breeding characteristics. The indices of specialization were calculated by applying the Gini coefficient, an index of inequality. The Gini coefficient is a measure of statistical dispersion on a scale between 0 and 1, reflecting a gradient from low to high specialization, respectively. Finally, we tested the strength of the phylogenetic signal of each specialization index to understand how the variance of such indices is shared throughout the phylogeny. The methods for constructing and evaluating a multidimensional index of bird specialization could also be applied to other taxa and regions, offering a simple but useful tool, particularly suited for global or biogeographic studies, as a contribution to comparative estimates of the degree of specialization of species.

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“…Most statistical analyses assume that single observations provide equally precise information about the deterministic part of total process variation; that is, the standard deviation of the error term is constant over all values of the predictor variable (Sokal & Rohlf, ). Garamszegi & Møller (, , ) have shown that bias due to variation in sample size among observations is a major problem in comparative analyses and equally significant as the biases caused by treating species‐specific estimates as statistically independent. If this assumption of similarity in sampling effort is violated, weighting each observation by sampling effort allows the use of all data, giving each datum a weight that reflects its degree of precision due to sampling effort (Draper & Smith, ; Sokal & Rohlf, ).…”

Section: Methodsmentioning

confidence: 99%

“…If this assumption of similarity in sampling effort is violated, weighting each observation by sampling effort allows the use of all data, giving each datum a weight that reflects its degree of precision due to sampling effort (Draper & Smith, ; Sokal & Rohlf, ). This procedure also allows both rare and common species to be included and hence avoids any bias in sampling due to rarity (Garamszegi & Møller, ). Therefore, we weighted statistical models by sample size.…”

Section: Methodsmentioning

confidence: 99%

Escape from predators and genetic variance in birds

Jiang

Møller

2017

J of Evolutionary Biology

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Predation is a common cause of death in numerous organisms, and a host of antipredator defences have evolved. Such defences often have a genetic background as shown by significant heritability and microevolutionary responses towards weaker defences in the absence of predators. Flight initiation distance (FID) is the distance at which an individual animal takes flight when approached by a human, and hence, it reflects the life-history compromise between risk of predation and the benefits of foraging. Here, we analysed FID in 128 species of birds in relation to three measures of genetic variation, band sharing coefficient for minisatellites, observed heterozygosity and inbreeding coefficient for microsatellites in order to test whether FID was positively correlated with genetic variation. We found consistently shorter FID for a given body size in the presence of high band sharing coefficients, low heterozygosity and high inbreeding coefficients in phylogenetic analyses after controlling statistically for potentially confounding variables. These findings imply that antipredator behaviour is related to genetic variance. We predict that many threatened species with low genetic variability will show reduced antipredator behaviour and that subsequent predator-induced reductions in abundance may contribute to unfavourable population trends for such species.

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Untested assumptions about within-species sample size and missing data in interspecific studies

Cited by 25 publications

References 75 publications

Range geometry and socio‐economics dominate species‐level biases in occurrence information

Range geometry and socio‐economics dominate species‐level biases in occurrence information

Measuring avian specialization

Escape from predators and genetic variance in birds

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