Pre-dispersal seed predation and pollen limitation constrain population growth across the geographic distribution of Astragalus utahensis

1. A central focus of ecology is to understand the conditions under which biotic interactions affect species' abundance and distribution. Classic and recent studies have shown that biotic interactions can strongly impact local or regional patterns of species abundance, but two fundamental quest...

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Published inThe Journal of ecology Vol. 106; no. 4; pp. 1646 - 1659
Main Authors Baer, Kathryn C., Maron, John L.
Format Journal Article
LanguageEnglish
Published Oxford John Wiley & Sons Ltd 01.07.2018
Blackwell Publishing Ltd
Subjects
Abundance
Annual precipitation
Astragalus utahensis
Biogeography and macroecology
Constraining
context‐dependence
Dispersal
Dispersion
Environmental changes
Fecundity
Geographical distribution
Growth rate
Herbivores
Insects
integral projection model
Interactions
Interspecific relationships
landscape ecology
plant population and community dynamics
Pollen
pollen limitation
Population dynamics
Population growth
Population studies
Predation
Predators
pre‐dispersal seed predation
range limit
Seed dispersal
Seed predation
Seed production
Species
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Abstract 1. A central focus of ecology is to understand the conditions under which biotic interactions affect species' abundance and distribution. Classic and recent studies have shown that biotic interactions can strongly impact local or regional patterns of species abundance, but two fundamental questions remain largely unaddressed for non-competitive biotic interactions. First, do the effects of these interactions on population performance change predictably with environmental context? Second, to what extent do population-scale effects contribute to limiting species' geographic distributions? 2. To address these questions, we experimentally assessed the extent to which pollen limitation and insect seed predators affected the fecundity and projected population growth rate (λ) of the native forb Astragalus utahensis. We studied populations at the centre and northern edge of the latitudinal range of A. utahensis that occur across a gradient in abiotic harshness characterized primarily by declining mean annual precipitation. 3. Supplementing pollen and suppressing pre-dispersal seed predators increased seed production similarly within A. utahensis populations at the centre and northern edge of the range. Integral projection population models revealed that relaxing these checks on seed production tended to increase in most populations, regardless of their location within the range. 4. Synthesis. Our results suggest that pollen limitation and insect herbivores limit population growth in A. utahensis similarly across the centre-to-north portion of its latitudinal distribution. However, because A. utahensis population growth barely reaches the level of replacement at the northern range edge, the reduction in resulting from these interactions may contribute to limiting expansion at the northern edge of A. utahensis' latitudinal range.
AbstractList Abstract A central focus of ecology is to understand the conditions under which biotic interactions affect species’ abundance and distribution. Classic and recent studies have shown that biotic interactions can strongly impact local or regional patterns of species abundance, but two fundamental questions remain largely unaddressed for non‐competitive biotic interactions. First, do the effects of these interactions on population performance change predictably with environmental context? Second, to what extent do population‐scale effects contribute to limiting species’ geographic distributions? To address these questions, we experimentally assessed the extent to which pollen limitation and insect seed predators affected the fecundity and projected population growth rate (λ) of the native forb Astragalus utahensis . We studied populations at the centre and northern edge of the latitudinal range of A. utahensis that occur across a gradient in abiotic harshness characterized primarily by declining mean annual precipitation. Supplementing pollen and suppressing pre‐dispersal seed predators increased seed production similarly within A. utahensis populations at the centre and northern edge of the range. Integral projection population models revealed that relaxing these checks on seed production tended to increase λ in most populations, regardless of their location within the range. Synthesis . Our results suggest that pollen limitation and insect herbivores limit population growth in A. utahensis similarly across the centre‐to‐north portion of its latitudinal distribution. However, because A. utahensis population growth barely reaches the level of replacement at the northern range edge, the reduction in λ resulting from these interactions may contribute to limiting expansion at the northern edge of A. utahensis ’ latitudinal range.
1. A central focus of ecology is to understand the conditions under which biotic interactions affect species' abundance and distribution. Classic and recent studies have shown that biotic interactions can strongly impact local or regional patterns of species abundance, but two fundamental questions remain largely unaddressed for non-competitive biotic interactions. First, do the effects of these interactions on population performance change predictably with environmental context? Second, to what extent do population-scale effects contribute to limiting species' geographic distributions? 2. To address these questions, we experimentally assessed the extent to which pollen limitation and insect seed predators affected the fecundity and projected population growth rate (λ) of the native forb Astragalus utahensis. We studied populations at the centre and northern edge of the latitudinal range of A. utahensis that occur across a gradient in abiotic harshness characterized primarily by declining mean annual precipitation. 3. Supplementing pollen and suppressing pre-dispersal seed predators increased seed production similarly within A. utahensis populations at the centre and northern edge of the range. Integral projection population models revealed that relaxing these checks on seed production tended to increase in most populations, regardless of their location within the range. 4. Synthesis. Our results suggest that pollen limitation and insect herbivores limit population growth in A. utahensis similarly across the centre-to-north portion of its latitudinal distribution. However, because A. utahensis population growth barely reaches the level of replacement at the northern range edge, the reduction in resulting from these interactions may contribute to limiting expansion at the northern edge of A. utahensis' latitudinal range.
A central focus of ecology is to understand the conditions under which biotic interactions affect species’ abundance and distribution. Classic and recent studies have shown that biotic interactions can strongly impact local or regional patterns of species abundance, but two fundamental questions remain largely unaddressed for non‐competitive biotic interactions. First, do the effects of these interactions on population performance change predictably with environmental context? Second, to what extent do population‐scale effects contribute to limiting species’ geographic distributions?To address these questions, we experimentally assessed the extent to which pollen limitation and insect seed predators affected the fecundity and projected population growth rate (λ) of the native forb Astragalus utahensis. We studied populations at the centre and northern edge of the latitudinal range of A. utahensis that occur across a gradient in abiotic harshness characterized primarily by declining mean annual precipitation.Supplementing pollen and suppressing pre‐dispersal seed predators increased seed production similarly within A. utahensis populations at the centre and northern edge of the range. Integral projection population models revealed that relaxing these checks on seed production tended to increase λ in most populations, regardless of their location within the range.Synthesis. Our results suggest that pollen limitation and insect herbivores limit population growth in A. utahensis similarly across the centre‐to‐north portion of its latitudinal distribution. However, because A. utahensis population growth barely reaches the level of replacement at the northern range edge, the reduction in λ resulting from these interactions may contribute to limiting expansion at the northern edge of A. utahensis’ latitudinal range.
A central focus of ecology is to understand the conditions under which biotic interactions affect species’ abundance and distribution. Classic and recent studies have shown that biotic interactions can strongly impact local or regional patterns of species abundance, but two fundamental questions remain largely unaddressed for non‐competitive biotic interactions. First, do the effects of these interactions on population performance change predictably with environmental context? Second, to what extent do population‐scale effects contribute to limiting species’ geographic distributions? To address these questions, we experimentally assessed the extent to which pollen limitation and insect seed predators affected the fecundity and projected population growth rate (λ) of the native forb Astragalus utahensis. We studied populations at the centre and northern edge of the latitudinal range of A. utahensis that occur across a gradient in abiotic harshness characterized primarily by declining mean annual precipitation. Supplementing pollen and suppressing pre‐dispersal seed predators increased seed production similarly within A. utahensis populations at the centre and northern edge of the range. Integral projection population models revealed that relaxing these checks on seed production tended to increase λ in most populations, regardless of their location within the range. Synthesis. Our results suggest that pollen limitation and insect herbivores limit population growth in A. utahensis similarly across the centre‐to‐north portion of its latitudinal distribution. However, because A. utahensis population growth barely reaches the level of replacement at the northern range edge, the reduction in λ resulting from these interactions may contribute to limiting expansion at the northern edge of A. utahensis’ latitudinal range. This study addresses fundamental but rarely studied questions in plant–pollinator and plant–herbivore interactions and biogeography. We found that pollen limitation and pre‐dispersal seed predation limited both the fecundity and population growth of Astragalus utahensis similarly across the centre‐to‐north portion of its latitudinal distribution, and likely contribute to the maintenance of this species’ northern distributional limit.
Author Maron, John L.
Baer, Kathryn C.
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e_1_2_8_79_1
Baer K. C. (e_1_2_8_12_1) 2018
e_1_2_8_90_1
Wolfe R. (e_1_2_8_91_1) 2002; 166
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Snippet 1. A central focus of ecology is to understand the conditions under which biotic interactions affect species' abundance and distribution. Classic and recent...
A central focus of ecology is to understand the conditions under which biotic interactions affect species’ abundance and distribution. Classic and recent...
Abstract A central focus of ecology is to understand the conditions under which biotic interactions affect species’ abundance and distribution. Classic and...
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SubjectTerms Abundance
Annual precipitation
Astragalus utahensis
Biogeography and macroecology
Constraining
context‐dependence
Dispersal
Dispersion
Environmental changes
Fecundity
Geographical distribution
Growth rate
Herbivores
Insects
integral projection model
Interactions
Interspecific relationships
landscape ecology
plant population and community dynamics
Pollen
pollen limitation
Population dynamics
Population growth
Population studies
Predation
Predators
pre‐dispersal seed predation
range limit
Seed dispersal
Seed predation
Seed production
Species
Title Pre-dispersal seed predation and pollen limitation constrain population growth across the geographic distribution of Astragalus utahensis
URI https://www.jstor.org/stable/45028999
https://onlinelibrary.wiley.com/doi/abs/10.1111%2F1365-2745.12932
https://www.proquest.com/docview/2056433966
Volume 106
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