The coevolution of fungus-ant agriculture

Ted R. Schultz; Jeffrey Sosa-Calvo; Matthew P. Kweskin; Michael W. Lloyd; Bryn Dentinger; Pepijn W. Kooij; Else C. Vellinga; Stephen A. Rehner; Andre Rodrigues; Quimi V. Montoya; Hermógenes Fernández-Marín; Ana Ješovnik; Tuula Niskanen; Kare Liimatainen; Caio A. Leal-Dutra; Scott E. Solomon; Nicole M. Gerardo; Cameron R. Currie; Mauricio Bacci; Heraldo L. Vasconcelos; Christian Rabeling; Brant C. Faircloth; Vinson P. Doyle

doi:10.1126/science.adn7179

The coevolution of fungus-ant agriculture

Ted R. Schultz, Jeffrey Sosa-Calvo, Matthew P. Kweskin, Michael W. Lloyd, Bryn Dentinger, Pepijn W. Kooij, Else C. Vellinga, Stephen A. Rehner, Andre Rodrigues, Quimi V. Montoya, Hermógenes Fernández-Marín, Ana Ješovnik, Tuula Niskanen, Kare Liimatainen, Caio A. Leal-Dutra, Scott E. Solomon, Nicole M. Gerardo, Cameron R. Currie, Mauricio Bacci, Heraldo L. VasconcelosChristian Rabeling, Brant C. Faircloth, Vinson P. Doyle

Ecology and Evolution

Publikation: Bidrag til tidsskrift › Tidsskriftartikel › Forskning › peer review

7 Citationer (Scopus)

Abstract

Fungus-farming ants cultivate multiple lineages of fungi for food, but, because fungal cultivar relationships are largely unresolved, the history of fungus-ant coevolution remains poorly known. We designed probes targeting >2000 gene regions to generate a dated evolutionary tree for 475 fungi and combined it with a similarly generated tree for 276 ants. We found that fungus-ant agriculture originated ~66 million years ago when the end-of-Cretaceous asteroid impact temporarily interrupted photosynthesis, causing global mass extinctions but favoring the proliferation of fungi. Subsequently, ~27 million years ago, one ancestral fungal cultivar population became domesticated, i.e., obligately mutualistic, when seasonally dry habitats expanded in South America, likely isolating the cultivar population from its free-living, wet forest–dwelling conspecifics. By revealing these and other major transitions in fungus-ant coevolution, our results clarify the historical processes that shaped a model system for nonhuman agriculture.

Originalsprog	Engelsk
Tidsskrift	Science (New York, N.Y.)
Vol/bind	386
Udgave nummer	6717
Sider (fra-til)	105-110
Antal sider	6
ISSN	0036-8075
DOI	https://doi.org/10.1126/science.adn7179
Status	Udgivet - 2024

Adgang til dokumentet

10.1126/science.adn7179

Citationsformater

Schultz, T. R., Sosa-Calvo, J., Kweskin, M. P., Lloyd, M. W., Dentinger, B., Kooij, P. W., Vellinga, E. C., Rehner, S. A., Rodrigues, A., Montoya, Q. V., Fernández-Marín, H., Ješovnik, A., Niskanen, T., Liimatainen, K., Leal-Dutra, C. A., Solomon, S. E., Gerardo, N. M., Currie, C. R., Bacci, M., ... Doyle, V. P. (2024). The coevolution of fungus-ant agriculture. Science (New York, N.Y.), 386(6717), 105-110. https://doi.org/10.1126/science.adn7179

Schultz, TR, Sosa-Calvo, J, Kweskin, MP, Lloyd, MW, Dentinger, B, Kooij, PW, Vellinga, EC, Rehner, SA, Rodrigues, A, Montoya, QV, Fernández-Marín, H, Ješovnik, A, Niskanen, T, Liimatainen, K, Leal-Dutra, CA, Solomon, SE, Gerardo, NM, Currie, CR, Bacci, M, Vasconcelos, HL, Rabeling, C, Faircloth, BC & Doyle, VP 2024, 'The coevolution of fungus-ant agriculture', Science (New York, N.Y.), bind 386, nr. 6717, s. 105-110. https://doi.org/10.1126/science.adn7179

@article{5499411dd55441e2b05e98a9f868ecbf,

title = "The coevolution of fungus-ant agriculture",

abstract = "Fungus-farming ants cultivate multiple lineages of fungi for food, but, because fungal cultivar relationships are largely unresolved, the history of fungus-ant coevolution remains poorly known. We designed probes targeting >2000 gene regions to generate a dated evolutionary tree for 475 fungi and combined it with a similarly generated tree for 276 ants. We found that fungus-ant agriculture originated ~66 million years ago when the end-of-Cretaceous asteroid impact temporarily interrupted photosynthesis, causing global mass extinctions but favoring the proliferation of fungi. Subsequently, ~27 million years ago, one ancestral fungal cultivar population became domesticated, i.e., obligately mutualistic, when seasonally dry habitats expanded in South America, likely isolating the cultivar population from its free-living, wet forest-dwelling conspecifics. By revealing these and other major transitions in fungus-ant coevolution, our results clarify the historical processes that shaped a model system for nonhuman agriculture.",

author = "Schultz, {Ted R.} and Jeffrey Sosa-Calvo and Kweskin, {Matthew P.} and Lloyd, {Michael W.} and Bryn Dentinger and Kooij, {Pepijn W.} and Vellinga, {Else C.} and Rehner, {Stephen A.} and Andre Rodrigues and Montoya, {Quimi V.} and Herm{\'o}genes Fern{\'a}ndez-Mar{\'i}n and Ana Je{\v s}ovnik and Tuula Niskanen and Kare Liimatainen and Leal-Dutra, {Caio A.} and Solomon, {Scott E.} and Gerardo, {Nicole M.} and Currie, {Cameron R.} and Mauricio Bacci and Vasconcelos, {Heraldo L.} and Christian Rabeling and Faircloth, {Brant C.} and Doyle, {Vinson P.}",

year = "2024",

doi = "10.1126/science.adn7179",

language = "English",

volume = "386",

pages = "105--110",

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T1 - The coevolution of fungus-ant agriculture

AU - Schultz, Ted R.

AU - Sosa-Calvo, Jeffrey

AU - Kweskin, Matthew P.

AU - Lloyd, Michael W.

AU - Dentinger, Bryn

AU - Kooij, Pepijn W.

AU - Vellinga, Else C.

AU - Rehner, Stephen A.

AU - Rodrigues, Andre

AU - Montoya, Quimi V.

AU - Fernández-Marín, Hermógenes

AU - Ješovnik, Ana

AU - Niskanen, Tuula

AU - Liimatainen, Kare

AU - Leal-Dutra, Caio A.

AU - Solomon, Scott E.

AU - Gerardo, Nicole M.

AU - Currie, Cameron R.

AU - Bacci, Mauricio

AU - Vasconcelos, Heraldo L.

AU - Rabeling, Christian

AU - Faircloth, Brant C.

AU - Doyle, Vinson P.

PY - 2024

Y1 - 2024

N2 - Fungus-farming ants cultivate multiple lineages of fungi for food, but, because fungal cultivar relationships are largely unresolved, the history of fungus-ant coevolution remains poorly known. We designed probes targeting >2000 gene regions to generate a dated evolutionary tree for 475 fungi and combined it with a similarly generated tree for 276 ants. We found that fungus-ant agriculture originated ~66 million years ago when the end-of-Cretaceous asteroid impact temporarily interrupted photosynthesis, causing global mass extinctions but favoring the proliferation of fungi. Subsequently, ~27 million years ago, one ancestral fungal cultivar population became domesticated, i.e., obligately mutualistic, when seasonally dry habitats expanded in South America, likely isolating the cultivar population from its free-living, wet forest-dwelling conspecifics. By revealing these and other major transitions in fungus-ant coevolution, our results clarify the historical processes that shaped a model system for nonhuman agriculture.

AB - Fungus-farming ants cultivate multiple lineages of fungi for food, but, because fungal cultivar relationships are largely unresolved, the history of fungus-ant coevolution remains poorly known. We designed probes targeting >2000 gene regions to generate a dated evolutionary tree for 475 fungi and combined it with a similarly generated tree for 276 ants. We found that fungus-ant agriculture originated ~66 million years ago when the end-of-Cretaceous asteroid impact temporarily interrupted photosynthesis, causing global mass extinctions but favoring the proliferation of fungi. Subsequently, ~27 million years ago, one ancestral fungal cultivar population became domesticated, i.e., obligately mutualistic, when seasonally dry habitats expanded in South America, likely isolating the cultivar population from its free-living, wet forest-dwelling conspecifics. By revealing these and other major transitions in fungus-ant coevolution, our results clarify the historical processes that shaped a model system for nonhuman agriculture.

U2 - 10.1126/science.adn7179

DO - 10.1126/science.adn7179

M3 - Journal article

C2 - 39361762

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