Local adaptation to climate has facilitated the global invasion of cheatgrass

Diana Gamba; Megan L. Vahsen; Toby M. Maxwell; Nikki Pirtel; Seth Romero; Justin J. Van Ee; Amanda Penn; Aayudh Das; Rotem Ben-Zeev; Owen Baughman; C. Sean Blaney; Randy Bodkins; Shanta Budha-Magar; Stella M. Copeland; Shannon L. Davis-Foust; Alvin Diamond; Ryan C. Donnelly; Peter W. Dunwiddie; David J. Ensing; Thomas A. Everest; Holly Hoitink; Martin C. Holdrege; Ruth A. Hufbauer; Sigitas Juzėnas; Jesse M. Kalwij; Ekaterina Kashirina; Sangtae Kim; Marcin Klisz; Alina Klyueva; Michel Langeveld; Samuel Lutfy; Daniel Martin; Christopher L. Merkord; John W. Morgan; Dávid U. Nagy; Jacqueline P. Ott; Radoslaw Puchalka; Lysandra A. Pyle; Leonid Rasran; Brian G. Rector; Christoph Rosche; Marina Sadykova; Robert K. Shriver; Alexandr Stanislavschi; Brian M. Starzomski; Rachel L. Stone; Kathryn G. Turner; Alexandra K. Urza; Acer VanWallendael; Carl Adam Wegenschimmel; Justin Zweck; Cynthia S. Brown; Elizabeth A. Leger; Dana M. Blumenthal; Matthew J. Germino; Lauren M. Porensky; Mevin B. Hooten; Peter B. Adler; Jesse R. Lasky

doi:10.1038/s41467-025-64799-9

Local adaptation to climate has facilitated the global invasion of cheatgrass

Diana Gamba
, Megan L. Vahsen
, Toby M. Maxwell
, Nikki Pirtel
, Seth Romero
, Justin J. Van Ee
, Amanda Penn
, Aayudh Das
, Rotem Ben-Zeev
, Owen Baughman
, C. Sean Blaney
, Randy Bodkins
, Shanta Budha-Magar
, Stella M. Copeland
, Shannon L. Davis-Foust
, Alvin Diamond
, Ryan C. Donnelly
, Peter W. Dunwiddie
, David J. Ensing
, Thomas A. Everest

Holly Hoitink, Martin C. Holdrege, Ruth A. Hufbauer, Sigitas Juzėnas, Jesse M. Kalwij, Ekaterina Kashirina, Sangtae Kim, Marcin Klisz, Alina Klyueva, Michel Langeveld, Samuel Lutfy, Daniel Martin, Christopher L. Merkord, John W. Morgan, Dávid U. Nagy, Jacqueline P. Ott, Radoslaw Puchalka, Lysandra A. Pyle, Leonid Rasran, Brian G. Rector, Christoph Rosche, Marina Sadykova, Robert K. Shriver, Alexandr Stanislavschi, Brian M. Starzomski, Rachel L. Stone, Kathryn G. Turner, Alexandra K. Urza, Acer VanWallendael, Carl Adam Wegenschimmel, Justin Zweck, Cynthia S. Brown, Elizabeth A. Leger, Dana M. Blumenthal, Matthew J. Germino, Lauren M. Porensky, Mevin B. Hooten, Peter B. Adler, Jesse R. Lasky

Pennsylvania State University
Utah State University
Boise State University
United States Department of Agriculture
Colorado State University
The Nature Conservancy
Atlantic Canada Conservation Data Centre
University of Texas at Austin
NorthTec
Oregon State University
University of Wisconsin Oshkosh
Troy University
Kansas State University
University of Washington
Agriculture and Agri-Food Canada
New Mexico State University
Northern Arizona University
Vilnius University
University of Johannesburg
Karlsruhe Institute of Technology
A.O. Kovalevsky Institute of Biology of the Southern Seas of RAS
Sungshin Women's University
Forest Research Institute
Bryansk State University Academician I. G. Petrovsky
Texas A&M University-Kingsville
Minnesota State University Moorhead
La Trobe University
Goethe University Frankfurt
Nicolaus Copernicus University in Toruń
Alberta Biodiversity Monitoring Institute
University of Natural Resources and Life Sciences, Vienna
Martin Luther University Halle-Wittenberg
University of Nevada, Reno
Gh. Asachi Technical University
University of Victoria BC
Case Western Reserve University
Idaho State University
North Carolina State University
Terrastory Environmental Consulting Inc.
United States Geological Survey

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

1 Scopus citations

Abstract

Local adaptation may facilitate range expansion during invasions, but the mechanisms underlying successful invasions remain unclear. Cheatgrass (Bromus tectorum), native to Eurasia and Africa, has invaded globally, with severe impacts in western North America. We aim to identify mechanisms and consequences of local adaptation in the North American cheatgrass invasion. We sequence 307 range-wide genotypes and conduct controlled experiments. We find that diverse lineages invaded North America, where long-distance gene flow is common. Nearly half of North American cheatgrass comprises a mosaic of ~19 locally adapted, near-clonal genotypes, each seemingly very successful in a different part of North America. Additionally, ancestry, phenotype, and allele frequency-environment clines in the native range predict those in the invaded range, indicating pre-adapted genotypes colonized different regions. Common gardens show directional selection on flowering time that reverse between warm and cold sites, potentially maintaining clines. In the USA Great Basin, genomic predictions of strong local adaptation identify sites where cheatgrass is most dominant. Our results indicate that multiple introductions and migration within the invaded range fuel local adaptation and success of cheatgrass in western North America. Understanding how environment and gene flow shape adaptation and invasion is critical for managing ongoing invasions.

Original language	English
Article number	10203
Journal	Nature Communications
Volume	16
Issue number	1
DOIs	https://doi.org/10.1038/s41467-025-64799-9
State	Published - Dec 2025
Externally published	Yes

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Gamba, D., Vahsen, M. L., Maxwell, T. M., Pirtel, N., Romero, S., Van Ee, J. J., Penn, A., Das, A., Ben-Zeev, R., Baughman, O., Blaney, C. S., Bodkins, R., Budha-Magar, S., Copeland, S. M., Davis-Foust, S. L., Diamond, A., Donnelly, R. C., Dunwiddie, P. W., Ensing, D. J., ... Lasky, J. R. (2025). Local adaptation to climate has facilitated the global invasion of cheatgrass. Nature Communications, 16(1), Article 10203. https://doi.org/10.1038/s41467-025-64799-9

@article{6fdf824067d542a9a9436ed2da3bdcf7,

title = "Local adaptation to climate has facilitated the global invasion of cheatgrass",

abstract = "Local adaptation may facilitate range expansion during invasions, but the mechanisms underlying successful invasions remain unclear. Cheatgrass (Bromus tectorum), native to Eurasia and Africa, has invaded globally, with severe impacts in western North America. We aim to identify mechanisms and consequences of local adaptation in the North American cheatgrass invasion. We sequence 307 range-wide genotypes and conduct controlled experiments. We find that diverse lineages invaded North America, where long-distance gene flow is common. Nearly half of North American cheatgrass comprises a mosaic of \textasciitilde{}19 locally adapted, near-clonal genotypes, each seemingly very successful in a different part of North America. Additionally, ancestry, phenotype, and allele frequency-environment clines in the native range predict those in the invaded range, indicating pre-adapted genotypes colonized different regions. Common gardens show directional selection on flowering time that reverse between warm and cold sites, potentially maintaining clines. In the USA Great Basin, genomic predictions of strong local adaptation identify sites where cheatgrass is most dominant. Our results indicate that multiple introductions and migration within the invaded range fuel local adaptation and success of cheatgrass in western North America. Understanding how environment and gene flow shape adaptation and invasion is critical for managing ongoing invasions.",

author = "Diana Gamba and Vahsen, \{Megan L.\} and Maxwell, \{Toby M.\} and Nikki Pirtel and Seth Romero and \{Van Ee\}, \{Justin J.\} and Amanda Penn and Aayudh Das and Rotem Ben-Zeev and Owen Baughman and Blaney, \{C. Sean\} and Randy Bodkins and Shanta Budha-Magar and Copeland, \{Stella M.\} and Davis-Foust, \{Shannon L.\} and Alvin Diamond and Donnelly, \{Ryan C.\} and Dunwiddie, \{Peter W.\} and Ensing, \{David J.\} and Everest, \{Thomas A.\} and Holly Hoitink and Holdrege, \{Martin C.\} and Hufbauer, \{Ruth A.\} and Sigitas Juzėnas and Kalwij, \{Jesse M.\} and Ekaterina Kashirina and Sangtae Kim and Marcin Klisz and Alina Klyueva and Michel Langeveld and Samuel Lutfy and Daniel Martin and Merkord, \{Christopher L.\} and Morgan, \{John W.\} and Nagy, \{D{\'a}vid U.\} and Ott, \{Jacqueline P.\} and Radoslaw Puchalka and Pyle, \{Lysandra A.\} and Leonid Rasran and Rector, \{Brian G.\} and Christoph Rosche and Marina Sadykova and Shriver, \{Robert K.\} and Alexandr Stanislavschi and Starzomski, \{Brian M.\} and Stone, \{Rachel L.\} and Turner, \{Kathryn G.\} and Urza, \{Alexandra K.\} and Acer VanWallendael and Wegenschimmel, \{Carl Adam\} and Justin Zweck and Brown, \{Cynthia S.\} and Leger, \{Elizabeth A.\} and Blumenthal, \{Dana M.\} and Germino, \{Matthew J.\} and Porensky, \{Lauren M.\} and Hooten, \{Mevin B.\} and Adler, \{Peter B.\} and Lasky, \{Jesse R.\}",

note = "{\textcopyright} 2025. The Author(s).",

year = "2025",

month = dec,

doi = "10.1038/s41467-025-64799-9",

language = "English",

volume = "16",

number = "1",

}

Gamba, D, Vahsen, ML, Maxwell, TM, Pirtel, N, Romero, S, Van Ee, JJ, Penn, A, Das, A, Ben-Zeev, R, Baughman, O, Blaney, CS, Bodkins, R, Budha-Magar, S, Copeland, SM, Davis-Foust, SL, Diamond, A, Donnelly, RC, Dunwiddie, PW, Ensing, DJ, Everest, TA, Hoitink, H, Holdrege, MC, Hufbauer, RA, Juzėnas, S, Kalwij, JM, Kashirina, E, Kim, S, Klisz, M, Klyueva, A, Langeveld, M, Lutfy, S, Martin, D, Merkord, CL, Morgan, JW, Nagy, DU, Ott, JP, Puchalka, R, Pyle, LA, Rasran, L, Rector, BG, Rosche, C, Sadykova, M, Shriver, RK, Stanislavschi, A, Starzomski, BM, Stone, RL, Turner, KG, Urza, AK, VanWallendael, A, Wegenschimmel, CA, Zweck, J, Brown, CS, Leger, EA, Blumenthal, DM, Germino, MJ, Porensky, LM, Hooten, MB, Adler, PB & Lasky, JR 2025, 'Local adaptation to climate has facilitated the global invasion of cheatgrass', Nature Communications, vol. 16, no. 1, 10203. https://doi.org/10.1038/s41467-025-64799-9

TY - JOUR

T1 - Local adaptation to climate has facilitated the global invasion of cheatgrass

AU - Gamba, Diana

AU - Vahsen, Megan L.

AU - Maxwell, Toby M.

AU - Pirtel, Nikki

AU - Romero, Seth

AU - Van Ee, Justin J.

AU - Penn, Amanda

AU - Das, Aayudh

AU - Ben-Zeev, Rotem

AU - Baughman, Owen

AU - Blaney, C. Sean

AU - Bodkins, Randy

AU - Budha-Magar, Shanta

AU - Copeland, Stella M.

AU - Davis-Foust, Shannon L.

AU - Diamond, Alvin

AU - Donnelly, Ryan C.

AU - Dunwiddie, Peter W.

AU - Ensing, David J.

AU - Everest, Thomas A.

AU - Hoitink, Holly

AU - Holdrege, Martin C.

AU - Hufbauer, Ruth A.

AU - Juzėnas, Sigitas

AU - Kalwij, Jesse M.

AU - Kashirina, Ekaterina

AU - Kim, Sangtae

AU - Klisz, Marcin

AU - Klyueva, Alina

AU - Langeveld, Michel

AU - Lutfy, Samuel

AU - Martin, Daniel

AU - Merkord, Christopher L.

AU - Morgan, John W.

AU - Nagy, Dávid U.

AU - Ott, Jacqueline P.

AU - Puchalka, Radoslaw

AU - Pyle, Lysandra A.

AU - Rasran, Leonid

AU - Rector, Brian G.

AU - Rosche, Christoph

AU - Sadykova, Marina

AU - Shriver, Robert K.

AU - Stanislavschi, Alexandr

AU - Starzomski, Brian M.

AU - Stone, Rachel L.

AU - Turner, Kathryn G.

AU - Urza, Alexandra K.

AU - VanWallendael, Acer

AU - Wegenschimmel, Carl Adam

AU - Zweck, Justin

AU - Brown, Cynthia S.

AU - Leger, Elizabeth A.

AU - Blumenthal, Dana M.

AU - Germino, Matthew J.

AU - Porensky, Lauren M.

AU - Hooten, Mevin B.

AU - Adler, Peter B.

AU - Lasky, Jesse R.

PY - 2025/12

Y1 - 2025/12

N2 - Local adaptation may facilitate range expansion during invasions, but the mechanisms underlying successful invasions remain unclear. Cheatgrass (Bromus tectorum), native to Eurasia and Africa, has invaded globally, with severe impacts in western North America. We aim to identify mechanisms and consequences of local adaptation in the North American cheatgrass invasion. We sequence 307 range-wide genotypes and conduct controlled experiments. We find that diverse lineages invaded North America, where long-distance gene flow is common. Nearly half of North American cheatgrass comprises a mosaic of ~19 locally adapted, near-clonal genotypes, each seemingly very successful in a different part of North America. Additionally, ancestry, phenotype, and allele frequency-environment clines in the native range predict those in the invaded range, indicating pre-adapted genotypes colonized different regions. Common gardens show directional selection on flowering time that reverse between warm and cold sites, potentially maintaining clines. In the USA Great Basin, genomic predictions of strong local adaptation identify sites where cheatgrass is most dominant. Our results indicate that multiple introductions and migration within the invaded range fuel local adaptation and success of cheatgrass in western North America. Understanding how environment and gene flow shape adaptation and invasion is critical for managing ongoing invasions.

AB - Local adaptation may facilitate range expansion during invasions, but the mechanisms underlying successful invasions remain unclear. Cheatgrass (Bromus tectorum), native to Eurasia and Africa, has invaded globally, with severe impacts in western North America. We aim to identify mechanisms and consequences of local adaptation in the North American cheatgrass invasion. We sequence 307 range-wide genotypes and conduct controlled experiments. We find that diverse lineages invaded North America, where long-distance gene flow is common. Nearly half of North American cheatgrass comprises a mosaic of ~19 locally adapted, near-clonal genotypes, each seemingly very successful in a different part of North America. Additionally, ancestry, phenotype, and allele frequency-environment clines in the native range predict those in the invaded range, indicating pre-adapted genotypes colonized different regions. Common gardens show directional selection on flowering time that reverse between warm and cold sites, potentially maintaining clines. In the USA Great Basin, genomic predictions of strong local adaptation identify sites where cheatgrass is most dominant. Our results indicate that multiple introductions and migration within the invaded range fuel local adaptation and success of cheatgrass in western North America. Understanding how environment and gene flow shape adaptation and invasion is critical for managing ongoing invasions.

UR - https://www.scopus.com/pages/publications/105022522938

U2 - 10.1038/s41467-025-64799-9

DO - 10.1038/s41467-025-64799-9

M3 - Article

C2 - 41266323

AN - SCOPUS:105022522938

VL - 16

JO - Nature Communications

JF - Nature Communications

IS - 1

M1 - 10203

ER -

Local adaptation to climate has facilitated the global invasion of cheatgrass

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