Convergent evolution of toxin resistance in animals

Jory van Thiel; Muzaffar A. Khan; Roel M. Wouters; Richard J. Harris; Nicholas R. Casewell; Bryan G. Fry; R. Manjunatha Kini; Stephen P. Mackessy; Freek J. Vonk; Wolfgang Wüster; Michael K. Richardson

doi:10.1111/brv.12865

Convergent evolution of toxin resistance in animals

Jory van Thiel^*
, Muzaffar A. Khan
, Roel M. Wouters
, Richard J. Harris
, Nicholas R. Casewell
, Bryan G. Fry
, R. Manjunatha Kini
, Stephen P. Mackessy
, Freek J. Vonk
, Wolfgang Wüster
, Michael K. Richardson

^*Corresponding author for this work

Research output: Contribution to Journal › Article › Academic › peer-review

Abstract

Convergence is the phenomenon whereby similar phenotypes evolve independently in different lineages. One example is resistance to toxins in animals. Toxins have evolved many times throughout the tree of life. They disrupt molecular and physiological pathways in target species, thereby incapacitating prey or deterring a predator. In response, molecular resistance has evolved in many species exposed to toxins to counteract their harmful effects. Here, we review current knowledge on the convergence of toxin resistance using examples from a wide range of toxin families. We explore the evolutionary processes and molecular adaptations driving toxin resistance. However, resistance adaptations may carry a fitness cost if they disrupt the normal physiology of the resistant animal. Therefore, there is a trade-off between maintaining a functional molecular target and reducing toxin susceptibility. There are relatively few solutions that satisfy this trade-off. As a result, we see a small set of molecular adaptations appearing repeatedly in diverse animal lineages, a phenomenon that is consistent with models of deterministic evolution. Convergence may also explain what has been called ‘autoresistance’. This is often thought to have evolved for self-protection, but we argue instead that it may be a consequence of poisonous animals feeding on toxic prey. Toxin resistance provides a unique and compelling model system for studying the interplay between trophic interactions, selection pressures and the molecular mechanisms underlying evolutionary novelties.

Original language	English
Pages (from-to)	1823-1843
Number of pages	21
Journal	Biological Reviews
Volume	97
Issue number	5
Early online date	17 May 2022
DOIs	https://doi.org/10.1111/brv.12865
Publication status	Published - Oct 2022

Bibliographical note

Funding Information:
M. A. K. and M. K. R. were supported by Elise Mathilde Fonds of Leids Universiteits Fonds (grant number 6113/21‐6‐16), Academy Ecology Funds of Royal Netherlands Academy of Arts and Sciences (grant number 713/18015), Higher Education Commission, Islamabad, Pakistan; R. J. H. was supported by the University of Queensland International PhD scholarship fund; and R. M. K. was supported by Ministry of Education, Singapore (grant number MOE2017‐T2‐1‐045). All line drawings of animals and plants were created by Sven Ballinger.

Publisher Copyright:
© 2022 The Authors. Biological Reviews published by John Wiley & Sons Ltd on behalf of Cambridge Philosophical Society.

Funding

M. A. K. and M. K. R. were supported by Elise Mathilde Fonds of Leids Universiteits Fonds (grant number 6113/21‐6‐16), Academy Ecology Funds of Royal Netherlands Academy of Arts and Sciences (grant number 713/18015), Higher Education Commission, Islamabad, Pakistan; R. J. H. was supported by the University of Queensland International PhD scholarship fund; and R. M. K. was supported by Ministry of Education, Singapore (grant number MOE2017‐T2‐1‐045). All line drawings of animals and plants were created by Sven Ballinger.

Keywords

co-evolutionary arms races
convergent evolution
deterministic evolution
functional constraint
molecular adaptation
toxin resistance

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10.1111/brv.12865

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Cite this

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title = "Convergent evolution of toxin resistance in animals",

abstract = "Convergence is the phenomenon whereby similar phenotypes evolve independently in different lineages. One example is resistance to toxins in animals. Toxins have evolved many times throughout the tree of life. They disrupt molecular and physiological pathways in target species, thereby incapacitating prey or deterring a predator. In response, molecular resistance has evolved in many species exposed to toxins to counteract their harmful effects. Here, we review current knowledge on the convergence of toxin resistance using examples from a wide range of toxin families. We explore the evolutionary processes and molecular adaptations driving toxin resistance. However, resistance adaptations may carry a fitness cost if they disrupt the normal physiology of the resistant animal. Therefore, there is a trade-off between maintaining a functional molecular target and reducing toxin susceptibility. There are relatively few solutions that satisfy this trade-off. As a result, we see a small set of molecular adaptations appearing repeatedly in diverse animal lineages, a phenomenon that is consistent with models of deterministic evolution. Convergence may also explain what has been called {\textquoteleft}autoresistance{\textquoteright}. This is often thought to have evolved for self-protection, but we argue instead that it may be a consequence of poisonous animals feeding on toxic prey. Toxin resistance provides a unique and compelling model system for studying the interplay between trophic interactions, selection pressures and the molecular mechanisms underlying evolutionary novelties.",

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author = "\{van Thiel\}, Jory and Khan, \{Muzaffar A.\} and Wouters, \{Roel M.\} and Harris, \{Richard J.\} and Casewell, \{Nicholas R.\} and Fry, \{Bryan G.\} and Kini, \{R. Manjunatha\} and Mackessy, \{Stephen P.\} and Vonk, \{Freek J.\} and Wolfgang W{\"u}ster and Richardson, \{Michael K.\}",

note = "Funding Information: M. A. K. and M. K. R. were supported by Elise Mathilde Fonds of Leids Universiteits Fonds (grant number 6113/21‐6‐16), Academy Ecology Funds of Royal Netherlands Academy of Arts and Sciences (grant number 713/18015), Higher Education Commission, Islamabad, Pakistan; R. J. H. was supported by the University of Queensland International PhD scholarship fund; and R. M. K. was supported by Ministry of Education, Singapore (grant number MOE2017‐T2‐1‐045). All line drawings of animals and plants were created by Sven Ballinger. Publisher Copyright: {\textcopyright} 2022 The Authors. Biological Reviews published by John Wiley \& Sons Ltd on behalf of Cambridge Philosophical Society.",

year = "2022",

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language = "English",

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AU - van Thiel, Jory

AU - Khan, Muzaffar A.

AU - Wouters, Roel M.

AU - Harris, Richard J.

AU - Casewell, Nicholas R.

AU - Fry, Bryan G.

AU - Kini, R. Manjunatha

AU - Mackessy, Stephen P.

AU - Vonk, Freek J.

AU - Wüster, Wolfgang

AU - Richardson, Michael K.

N1 - Funding Information: M. A. K. and M. K. R. were supported by Elise Mathilde Fonds of Leids Universiteits Fonds (grant number 6113/21‐6‐16), Academy Ecology Funds of Royal Netherlands Academy of Arts and Sciences (grant number 713/18015), Higher Education Commission, Islamabad, Pakistan; R. J. H. was supported by the University of Queensland International PhD scholarship fund; and R. M. K. was supported by Ministry of Education, Singapore (grant number MOE2017‐T2‐1‐045). All line drawings of animals and plants were created by Sven Ballinger. Publisher Copyright: © 2022 The Authors. Biological Reviews published by John Wiley & Sons Ltd on behalf of Cambridge Philosophical Society.

PY - 2022/10

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N2 - Convergence is the phenomenon whereby similar phenotypes evolve independently in different lineages. One example is resistance to toxins in animals. Toxins have evolved many times throughout the tree of life. They disrupt molecular and physiological pathways in target species, thereby incapacitating prey or deterring a predator. In response, molecular resistance has evolved in many species exposed to toxins to counteract their harmful effects. Here, we review current knowledge on the convergence of toxin resistance using examples from a wide range of toxin families. We explore the evolutionary processes and molecular adaptations driving toxin resistance. However, resistance adaptations may carry a fitness cost if they disrupt the normal physiology of the resistant animal. Therefore, there is a trade-off between maintaining a functional molecular target and reducing toxin susceptibility. There are relatively few solutions that satisfy this trade-off. As a result, we see a small set of molecular adaptations appearing repeatedly in diverse animal lineages, a phenomenon that is consistent with models of deterministic evolution. Convergence may also explain what has been called ‘autoresistance’. This is often thought to have evolved for self-protection, but we argue instead that it may be a consequence of poisonous animals feeding on toxic prey. Toxin resistance provides a unique and compelling model system for studying the interplay between trophic interactions, selection pressures and the molecular mechanisms underlying evolutionary novelties.

AB - Convergence is the phenomenon whereby similar phenotypes evolve independently in different lineages. One example is resistance to toxins in animals. Toxins have evolved many times throughout the tree of life. They disrupt molecular and physiological pathways in target species, thereby incapacitating prey or deterring a predator. In response, molecular resistance has evolved in many species exposed to toxins to counteract their harmful effects. Here, we review current knowledge on the convergence of toxin resistance using examples from a wide range of toxin families. We explore the evolutionary processes and molecular adaptations driving toxin resistance. However, resistance adaptations may carry a fitness cost if they disrupt the normal physiology of the resistant animal. Therefore, there is a trade-off between maintaining a functional molecular target and reducing toxin susceptibility. There are relatively few solutions that satisfy this trade-off. As a result, we see a small set of molecular adaptations appearing repeatedly in diverse animal lineages, a phenomenon that is consistent with models of deterministic evolution. Convergence may also explain what has been called ‘autoresistance’. This is often thought to have evolved for self-protection, but we argue instead that it may be a consequence of poisonous animals feeding on toxic prey. Toxin resistance provides a unique and compelling model system for studying the interplay between trophic interactions, selection pressures and the molecular mechanisms underlying evolutionary novelties.

KW - co-evolutionary arms races

KW - convergent evolution

KW - deterministic evolution

KW - functional constraint

KW - molecular adaptation

KW - toxin resistance

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JO - Biological Reviews

JF - Biological Reviews

IS - 5

ER -

Convergent evolution of toxin resistance in animals

Abstract

Bibliographical note

Funding

Keywords

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