Hawkmoth Pollination Facilitates Long-Distance Pollen Dispersal and Reduces Isolation Across a Gradient of Land-Use Change

Krissa A. Skogen; Rick P. Overson; Evan T. Hilpman; Jeremie B. Fant

doi:10.3417/2019475

Hawkmoth Pollination Facilitates Long-Distance Pollen Dispersal and Reduces Isolation Across a Gradient of Land-Use Change

Krissa A. Skogen, Rick P. Overson, Evan T. Hilpman, Jeremie B. Fant

Program in Biological Sciences

Research output: Contribution to journal › Article › peer-review

30 Scopus citations

Abstract

Land-use change is among the top drivers of global biodiversity loss, which impacts the arrangement and distribution of suitable habitat for species. Population-level effects include increased isolation, decreased population size, and changes to mutualistic and antagonistic interactions. However, the extent to which species are impacted is determined by life history characteristics including dispersal. In plants, mating dynamics can be changed in ways that can negatively impact population persistence if dispersal of pollen and/or seed is disrupted. Long-distance dispersal has the potential to buffer species from the negative impacts of land-use change. Biotic vectors of long-distance dispersal have been less frequently studied, though specific taxa are known to travel great distances. Here, we describe population genetic diversity and structure in a sphingophilous species that is experiencing habitat fragmentation through land-use change, Oenothera harringtonii W. L. Wagner, Stockh. & W. M. Klein (Onagraceae). We use 12 nuclear and four plastid microsatellite markers and show that pollen dispersal by hawkmoths drives high gene flow and low population differentiation despite a range-wide gradient of land-use change and habitat fragmentation. By separating the contributions of pollen and seed dispersal to gene flow, we show that most of the genetic parameters are driven by hawkmoth-facilitated long-distance pollen dispersal, but populations with small, effective population sizes experience higher levels of relatedness and inbreeding. We discuss considerations for conservation efforts for this and other species that are pollinated by long-distance dispersers.

Original language	English (US)
Pages (from-to)	495-511
Number of pages	17
Journal	Annals of the Missouri Botanical Garden
Volume	104
Issue number	3
DOIs	https://doi.org/10.3417/2019475
State	Published - Oct 1 2019

Funding

1 Funding was provided by the National Science Foundation (DEB 1342873 to K. A. S. and J. B. F.), Colorado Native Plant Society (to K. A. S.), and the Chicago Botanic Garden Division of Plant Science and Conservation. The authors thank N. Wickett and two anonymous reviewers for feedback on previous versions of this manuscript. S. (Tass) Kelso and S. Olson facilitated fieldwork and access to population localities. S. Todd, K. West, and Q. Roberts provided assistance in the field and lab. S. Olson (USDA Forest Service) provided permission to conduct studies at Comanche National Grasslands, U.S.A. 2 Plant Science and Conservation, Chicago Botanic Garden, Glencoe, Illinois 60022, U.S.A. [email protected]. 3 School of Sustainability, Arizona State University, Tempe, Arizona 85287, U.S.A. 4 School of Biological Sciences, Washington State University, Pullman, Washington 99164, U.S.A.

Keywords

Habitat fragmentation
Oenothera
Onagraceae
hawkmoth pollination
isolation
land-use change
long-distance dispersal
pollen dispersal
population genetics
seed dispersal

ASJC Scopus subject areas

Ecology, Evolution, Behavior and Systematics
Plant Science

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

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10.3417/2019475

Cite this

@article{20cfb4996fb34a32bf18a15ea9bda045,

title = "Hawkmoth Pollination Facilitates Long-Distance Pollen Dispersal and Reduces Isolation Across a Gradient of Land-Use Change",

abstract = "Land-use change is among the top drivers of global biodiversity loss, which impacts the arrangement and distribution of suitable habitat for species. Population-level effects include increased isolation, decreased population size, and changes to mutualistic and antagonistic interactions. However, the extent to which species are impacted is determined by life history characteristics including dispersal. In plants, mating dynamics can be changed in ways that can negatively impact population persistence if dispersal of pollen and/or seed is disrupted. Long-distance dispersal has the potential to buffer species from the negative impacts of land-use change. Biotic vectors of long-distance dispersal have been less frequently studied, though specific taxa are known to travel great distances. Here, we describe population genetic diversity and structure in a sphingophilous species that is experiencing habitat fragmentation through land-use change, Oenothera harringtonii W. L. Wagner, Stockh. & W. M. Klein (Onagraceae). We use 12 nuclear and four plastid microsatellite markers and show that pollen dispersal by hawkmoths drives high gene flow and low population differentiation despite a range-wide gradient of land-use change and habitat fragmentation. By separating the contributions of pollen and seed dispersal to gene flow, we show that most of the genetic parameters are driven by hawkmoth-facilitated long-distance pollen dispersal, but populations with small, effective population sizes experience higher levels of relatedness and inbreeding. We discuss considerations for conservation efforts for this and other species that are pollinated by long-distance dispersers.",

keywords = "Habitat fragmentation, Oenothera, Onagraceae, hawkmoth pollination, isolation, land-use change, long-distance dispersal, pollen dispersal, population genetics, seed dispersal",

author = "Skogen, {Krissa A.} and Overson, {Rick P.} and Hilpman, {Evan T.} and Fant, {Jeremie B.}",

note = "Funding Information: 1 Funding was provided by the National Science Foundation (DEB 1342873 to K. A. S. and J. B. F.), Colorado Native Plant Society (to K. A. S.), and the Chicago Botanic Garden Division of Plant Science and Conservation. The authors thank N. Wickett and two anonymous reviewers for feedback on previous versions of this manuscript. S. (Tass) Kelso and S. Olson facilitated fieldwork and access to population localities. S. Todd, K. West, and Q. Roberts provided assistance in the field and lab. S. Olson (USDA Forest Service) provided permission to conduct studies at Comanche National Grasslands, U.S.A. 2 Plant Science and Conservation, Chicago Botanic Garden, Glencoe, Illinois 60022, U.S.A. [email protected]. 3 School of Sustainability, Arizona State University, Tempe, Arizona 85287, U.S.A. 4 School of Biological Sciences, Washington State University, Pullman, Washington 99164, U.S.A. Publisher Copyright: {\textcopyright} 2019 Missouri Botanical Garden. All rights reserved.",

year = "2019",

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doi = "10.3417/2019475",

language = "English (US)",

volume = "104",

pages = "495--511",

journal = "Annals of the Missouri Botanical Garden",

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T1 - Hawkmoth Pollination Facilitates Long-Distance Pollen Dispersal and Reduces Isolation Across a Gradient of Land-Use Change

AU - Skogen, Krissa A.

AU - Overson, Rick P.

AU - Hilpman, Evan T.

AU - Fant, Jeremie B.

N1 - Funding Information: 1 Funding was provided by the National Science Foundation (DEB 1342873 to K. A. S. and J. B. F.), Colorado Native Plant Society (to K. A. S.), and the Chicago Botanic Garden Division of Plant Science and Conservation. The authors thank N. Wickett and two anonymous reviewers for feedback on previous versions of this manuscript. S. (Tass) Kelso and S. Olson facilitated fieldwork and access to population localities. S. Todd, K. West, and Q. Roberts provided assistance in the field and lab. S. Olson (USDA Forest Service) provided permission to conduct studies at Comanche National Grasslands, U.S.A. 2 Plant Science and Conservation, Chicago Botanic Garden, Glencoe, Illinois 60022, U.S.A. [email protected]. 3 School of Sustainability, Arizona State University, Tempe, Arizona 85287, U.S.A. 4 School of Biological Sciences, Washington State University, Pullman, Washington 99164, U.S.A. Publisher Copyright: © 2019 Missouri Botanical Garden. All rights reserved.

PY - 2019/10/1

Y1 - 2019/10/1

N2 - Land-use change is among the top drivers of global biodiversity loss, which impacts the arrangement and distribution of suitable habitat for species. Population-level effects include increased isolation, decreased population size, and changes to mutualistic and antagonistic interactions. However, the extent to which species are impacted is determined by life history characteristics including dispersal. In plants, mating dynamics can be changed in ways that can negatively impact population persistence if dispersal of pollen and/or seed is disrupted. Long-distance dispersal has the potential to buffer species from the negative impacts of land-use change. Biotic vectors of long-distance dispersal have been less frequently studied, though specific taxa are known to travel great distances. Here, we describe population genetic diversity and structure in a sphingophilous species that is experiencing habitat fragmentation through land-use change, Oenothera harringtonii W. L. Wagner, Stockh. & W. M. Klein (Onagraceae). We use 12 nuclear and four plastid microsatellite markers and show that pollen dispersal by hawkmoths drives high gene flow and low population differentiation despite a range-wide gradient of land-use change and habitat fragmentation. By separating the contributions of pollen and seed dispersal to gene flow, we show that most of the genetic parameters are driven by hawkmoth-facilitated long-distance pollen dispersal, but populations with small, effective population sizes experience higher levels of relatedness and inbreeding. We discuss considerations for conservation efforts for this and other species that are pollinated by long-distance dispersers.

AB - Land-use change is among the top drivers of global biodiversity loss, which impacts the arrangement and distribution of suitable habitat for species. Population-level effects include increased isolation, decreased population size, and changes to mutualistic and antagonistic interactions. However, the extent to which species are impacted is determined by life history characteristics including dispersal. In plants, mating dynamics can be changed in ways that can negatively impact population persistence if dispersal of pollen and/or seed is disrupted. Long-distance dispersal has the potential to buffer species from the negative impacts of land-use change. Biotic vectors of long-distance dispersal have been less frequently studied, though specific taxa are known to travel great distances. Here, we describe population genetic diversity and structure in a sphingophilous species that is experiencing habitat fragmentation through land-use change, Oenothera harringtonii W. L. Wagner, Stockh. & W. M. Klein (Onagraceae). We use 12 nuclear and four plastid microsatellite markers and show that pollen dispersal by hawkmoths drives high gene flow and low population differentiation despite a range-wide gradient of land-use change and habitat fragmentation. By separating the contributions of pollen and seed dispersal to gene flow, we show that most of the genetic parameters are driven by hawkmoth-facilitated long-distance pollen dispersal, but populations with small, effective population sizes experience higher levels of relatedness and inbreeding. We discuss considerations for conservation efforts for this and other species that are pollinated by long-distance dispersers.

KW - Habitat fragmentation

KW - Oenothera

KW - Onagraceae

KW - hawkmoth pollination

KW - isolation

KW - land-use change

KW - long-distance dispersal

KW - pollen dispersal

KW - population genetics

KW - seed dispersal

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JO - Annals of the Missouri Botanical Garden

JF - Annals of the Missouri Botanical Garden

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ER -

Hawkmoth Pollination Facilitates Long-Distance Pollen Dispersal and Reduces Isolation Across a Gradient of Land-Use Change

Abstract

Funding

Keywords

ASJC Scopus subject areas

UN SDGs

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