Identifying the paths leading to variation in geographical range size in western North American monkeyflowers

Sheth, Seema N.; Jiménez, Iván; Angert, Amy L.

doi:10.1111/jbi.12378

Cited by 30 publications

(65 citation statements)

References 53 publications

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“…Though experiments can only quantify niche breadth for a relatively small number of species and niche axes, they are a potentially powerful complement to verify tests of the niche breadth hypothesis based on correlative methods for a large number of species. For example, a study of western North American monkeyflowers found strong support for the climatic niche breadth hypothesis when using herbarium records to quantify both niche breadth and range size for 72 species (Sheth et al , ), and weaker support (possibly due to small sample sizes) when quantifying niche breadth experimentally with thermal performance curves for 10 of those species (Sheth & Angert, ).…”

Section: Equilibrial Limits: Variation In Ranges That Are Static Thromentioning

confidence: 99%

“…Colors in the map correspond to the mean range size of species recorded in each grid cell. (b) Frequency distribution of range size for species of western North American monkeyflowers (redrawn from Sheth et al , ). As observed in many species assemblages, most species have small geographic ranges, and only a small number of species have large geographic ranges, but range size can vary dramatically even among closely related species.…”

Section: Introductionmentioning

confidence: 99%

“…Range filling is often estimated as the proportion of suitable habitat (shaded blue grid cells) in which a species is known to occur (blue dots). For (b–d), see Sheth et al () for more information.…”

Section: Introductionmentioning

confidence: 99%

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Determinants of geographic range size in plants

2020

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Summary Geographic range size has long fascinated ecologists and evolutionary biologists, yet our understanding of the factors that cause variation in range size among species and across space remains limited. Not only does geographic range size inform decisions about the conservation and management of rare and nonindigenous species due to its relationship with extinction risk, rarity, and invasiveness, but it also provides insights into fundamental processes such as dispersal and adaptation. There are several features unique to plants (e.g. polyploidy, mating system, sessile habit) that may lead to distinct mechanisms explaining variation in range size. Here, we highlight key studies testing intrinsic and extrinsic hypotheses about geographic range size under contrasting scenarios where species' ranges are static or change over time. We then present results from a meta‐analysis of the relative importance of commonly hypothesized determinants of range size in plants. We show that our ability to infer the relative importance of these determinants is limited, particularly for dispersal ability, mating system, ploidy, and environmental heterogeneity. We highlight avenues for future research that merge approaches from macroecology and evolutionary ecology to better understand how adaptation and dispersal interact to facilitate niche evolution and range expansion.

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Section: Equilibrial Limits: Variation In Ranges That Are Static Thromentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Determinants of geographic range size in plants

2020

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“…Understanding how fitness and reproductive success vary across climate niche space could be an important avenue for future investigation, as it has been with density-dependent habitat selection (Morris, 1989;Sillett et al, 2004). While others have defined ecological niche as the set of conditions under which the intrinsic rate of increase is non-negative (Sheth et al, 2014), we make no statements here about fitness or growth rate and instead use the range of conditions occupied to define realized niche, as is consistent with ecological niche modelling (Pearson & Dawson, 2003;Sober on & Peterson, 2005) and niche theory (Pulliam, 2000). While others have defined ecological niche as the set of conditions under which the intrinsic rate of increase is non-negative (Sheth et al, 2014), we make no statements here about fitness or growth rate and instead use the range of conditions occupied to define realized niche, as is consistent with ecological niche modelling (Pearson & Dawson, 2003;Sober on & Peterson, 2005) and niche theory (Pulliam, 2000).…”

Section: Discussionmentioning

confidence: 88%

“…This expands long-standing ecological niche theory that occupied niche breadth increases with population growth (Vandermeer, 1972). Niche breadth has been used as a static, explanatory variable of population trends (Green et al, 2008;Jiguet et al, 2013) or geographical distribution (Sheth et al, 2014), or as a latent variable in the distribution-abundance relationship (Brown, 1984;Heino et al, 2008;Borregaard & Rahbek, 2010). Niche breadth has been used as a static, explanatory variable of population trends (Green et al, 2008;Jiguet et al, 2013) or geographical distribution (Sheth et al, 2014), or as a latent variable in the distribution-abundance relationship (Brown, 1984;Heino et al, 2008;Borregaard & Rahbek, 2010).…”

Section: Discussionmentioning

confidence: 99%

Realized climate niche breadth varies with population trend and distribution in North American birds

Ralston

DeLuca

Feldman

et al. 2016

Global Ecol. Biogeogr.

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Aim Ecological niche theory states that realized niche breadth should increase with population growth. This relationship has been studied extensively in the context of density‐dependent habitat selection, and there is evidence that animal populations at higher density occupy a wider range of vegetation types. To our knowledge, no previous studies have investigated the relationship between population growth and climate niche breadth (i.e. the range of climatic conditions occupied). Here we aim to estimate the influence of population trend, as well as changes in distribution, on realized climate niche breadth. Location North America. Methods We estimated changes in realized climate niche breadth and distribution between 1980 and 2012 for 46 bird species using data from the North American Breeding Bird Survey (BBS) and standard ecological niche modelling techniques. We analysed changes in niche breadth in relation to population trends and distributional changes from the BBS for these same species. Results Changes in realized climate niche breadth were significantly and positively associated with population growth, as reflected by BBS population trends, and with changes in distributional extent. Using variance partitioning, we showed that 44.2% of the variation in change in niche breadth can be explained by population trend, and that roughly half of this was independent of changes in distribution. Conclusions Realized climate niche breadth is variable on an ecological time‐scale as a function of population trend. Mechanisms associated with changes in distribution and those acting within current species range limits appear to be equally important in driving this relationship. Observed changes in niche breadth may violate distribution modelling assumptions of niche conservatism. Studying how population growth influences realized climate niche breadth is therefore important for understanding dynamic species distributions, responses to climate change and our ability to model future species distributions.

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Trait dimensionality and population choice alter estimates of phenotypic dissimilarity

Carscadden

Cadotte

Gilbert

2017

Ecology and Evolution

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The ecological niche is a multi‐dimensional concept including aspects of resource use, environmental tolerance, and interspecific interactions, and the degree to which niches overlap is central to many ecological questions. Plant phenotypic traits are increasingly used as surrogates of species niches, but we lack an understanding of how key sampling decisions affect our ability to capture phenotypic differences among species. Using trait data of ecologically distinct monkeyflower (Mimulus) congeners, we employed linear discriminant analysis to determine how (1) dimensionality (the number and type of traits) and (2) variation within species influence how well measured traits reflect phenotypic differences among species. We conducted analyses using vegetative and floral traits in different combinations of up to 13 traits and compared the performance of commonly used functional traits such as specific leaf area against other morphological traits. We tested the importance of intraspecific variation by assessing how population choice changed our ability to discriminate species. Neither using key functional traits nor sampling across plant functions and organs maximized species discrimination. When using few traits, vegetative traits performed better than combinations of vegetative and floral traits or floral traits alone. Overall, including more traits increased our ability to detect phenotypic differences among species. Population choice and the number of traits used had comparable impacts on discriminating species. We addressed methodological challenges that have undermined cross‐study comparability of trait‐based approaches. Our results emphasize the importance of sampling among‐population trait variation and suggest that a high‐dimensional approach may best capture phenotypic variation among species with distinct niches.

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Identifying the paths leading to variation in geographical range size in western North American monkeyflowers

Cited by 30 publications

References 53 publications

Determinants of geographic range size in plants

Determinants of geographic range size in plants

Realized climate niche breadth varies with population trend and distribution in North American birds

Trait dimensionality and population choice alter estimates of phenotypic dissimilarity

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