Ten (mostly) simple rules to future-proof trait data in ecological and evolutionary sciences

Alexander Keller; Markus J. Ankenbrand; Helge Bruelheide; Stefanie Dekeyzer; Brian J. Enquist; Mohammad Bagher Erfanian; Daniel S. Falster; Rachael V. Gallagher; Jennifer Hammock; Jens Kattge; Sara D. Leonhardt; Joshua S. Madin; Brian Maitner; Margot Neyret; Renske E. Onstein; William D. Pearse; Jorrit H. Poelen; Roberto Salguero-Gomez; Florian D. Schneider; Anikó B. Tóth; Caterina Penone

doi:10.1111/2041-210X.14033

Ten (mostly) simple rules to future-proof trait data in ecological and evolutionary sciences

Alexander Keller, Markus J. Ankenbrand, Helge Bruelheide, Stefanie Dekeyzer, Brian J. Enquist, Mohammad Bagher Erfanian, Daniel S. Falster, Rachael V. Gallagher, Jennifer Hammock, Jens Kattge, Sara D. Leonhardt, Joshua S. Madin, Brian Maitner, Margot Neyret, Renske E. Onstein, William D. Pearse, Jorrit H. Poelen, Roberto Salguero-Gomez, Florian D. Schneider, Anikó B. TóthCaterina Penone

Hawkesbury Institute for the Environment

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

29 Citations (Scopus)

Abstract

Traits have become a crucial part of ecological and evolutionary sciences, helping researchers understand the function of an organism's morphology, physiology, growth and life history, with effects on fitness, behaviour, interactions with the environment and ecosystem processes. However, measuring, compiling and analysing trait data comes with data-scientific challenges. We offer 10 (mostly) simple rules, with some detailed extensions, as a guide in making critical decisions that consider the entire life cycle of trait data. This article is particularly motivated by its last rule, that is, to propagate good practice. It has the intention of bringing awareness of how data on the traits of organisms can be collected and managed for reuse by the research community. Trait observations are relevant to a broad interdisciplinary community of field biologists, synthesis ecologists, evolutionary biologists, computer scientists and database managers. We hope these basic guidelines can be useful as a starter for active communication in disseminating such integrative knowledge and in how to make trait data future-proof. We invite the scientific community to participate in this effort at http://opentraits.org/best-practices.html.

Original language	English
Pages (from-to)	444-458
Number of pages	15
Journal	Methods in Ecology and Evolution
Volume	14
Issue number	2
DOIs	https://doi.org/10.1111/2041-210X.14033
Publication status	Published - Feb 2023

Bibliographical note

Publisher Copyright:
© 2022 The Authors. Methods in Ecology and Evolution published by John Wiley & Sons Ltd on behalf of British Ecological Society.

Keywords

data life cycle
data science
FAIR principles
good practices
metadata
open science
phenotype
trait data

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10.1111/2041-210X.14033

Cite this

Keller, A., Ankenbrand, M. J., Bruelheide, H., Dekeyzer, S., Enquist, B. J., Erfanian, M. B., Falster, D. S., Gallagher, R. V., Hammock, J., Kattge, J., Leonhardt, S. D., Madin, J. S., Maitner, B., Neyret, M., Onstein, R. E., Pearse, W. D., Poelen, J. H., Salguero-Gomez, R., Schneider, F. D., ... Penone, C. (2023). Ten (mostly) simple rules to future-proof trait data in ecological and evolutionary sciences. Methods in Ecology and Evolution, 14(2), 444-458. https://doi.org/10.1111/2041-210X.14033

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title = "Ten (mostly) simple rules to future-proof trait data in ecological and evolutionary sciences",

abstract = "Traits have become a crucial part of ecological and evolutionary sciences, helping researchers understand the function of an organism's morphology, physiology, growth and life history, with effects on fitness, behaviour, interactions with the environment and ecosystem processes. However, measuring, compiling and analysing trait data comes with data-scientific challenges. We offer 10 (mostly) simple rules, with some detailed extensions, as a guide in making critical decisions that consider the entire life cycle of trait data. This article is particularly motivated by its last rule, that is, to propagate good practice. It has the intention of bringing awareness of how data on the traits of organisms can be collected and managed for reuse by the research community. Trait observations are relevant to a broad interdisciplinary community of field biologists, synthesis ecologists, evolutionary biologists, computer scientists and database managers. We hope these basic guidelines can be useful as a starter for active communication in disseminating such integrative knowledge and in how to make trait data future-proof. We invite the scientific community to participate in this effort at http://opentraits.org/best-practices.html.",

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author = "Alexander Keller and Ankenbrand, {Markus J.} and Helge Bruelheide and Stefanie Dekeyzer and Enquist, {Brian J.} and Erfanian, {Mohammad Bagher} and Falster, {Daniel S.} and Gallagher, {Rachael V.} and Jennifer Hammock and Jens Kattge and Leonhardt, {Sara D.} and Madin, {Joshua S.} and Brian Maitner and Margot Neyret and Onstein, {Renske E.} and Pearse, {William D.} and Poelen, {Jorrit H.} and Roberto Salguero-Gomez and Schneider, {Florian D.} and T{\'o}th, {Anik{\'o} B.} and Caterina Penone",

note = "Publisher Copyright: {\textcopyright} 2022 The Authors. Methods in Ecology and Evolution published by John Wiley & Sons Ltd on behalf of British Ecological Society.",

year = "2023",

month = feb,

doi = "10.1111/2041-210X.14033",

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Keller, A, Ankenbrand, MJ, Bruelheide, H, Dekeyzer, S, Enquist, BJ, Erfanian, MB, Falster, DS, Gallagher, RV, Hammock, J, Kattge, J, Leonhardt, SD, Madin, JS, Maitner, B, Neyret, M, Onstein, RE, Pearse, WD, Poelen, JH, Salguero-Gomez, R, Schneider, FD, Tóth, AB & Penone, C 2023, 'Ten (mostly) simple rules to future-proof trait data in ecological and evolutionary sciences', Methods in Ecology and Evolution, vol. 14, no. 2, pp. 444-458. https://doi.org/10.1111/2041-210X.14033

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T1 - Ten (mostly) simple rules to future-proof trait data in ecological and evolutionary sciences

AU - Keller, Alexander

AU - Ankenbrand, Markus J.

AU - Bruelheide, Helge

AU - Dekeyzer, Stefanie

AU - Enquist, Brian J.

AU - Erfanian, Mohammad Bagher

AU - Falster, Daniel S.

AU - Gallagher, Rachael V.

AU - Hammock, Jennifer

AU - Kattge, Jens

AU - Leonhardt, Sara D.

AU - Madin, Joshua S.

AU - Maitner, Brian

AU - Neyret, Margot

AU - Onstein, Renske E.

AU - Pearse, William D.

AU - Poelen, Jorrit H.

AU - Salguero-Gomez, Roberto

AU - Schneider, Florian D.

AU - Tóth, Anikó B.

AU - Penone, Caterina

PY - 2023/2

Y1 - 2023/2

N2 - Traits have become a crucial part of ecological and evolutionary sciences, helping researchers understand the function of an organism's morphology, physiology, growth and life history, with effects on fitness, behaviour, interactions with the environment and ecosystem processes. However, measuring, compiling and analysing trait data comes with data-scientific challenges. We offer 10 (mostly) simple rules, with some detailed extensions, as a guide in making critical decisions that consider the entire life cycle of trait data. This article is particularly motivated by its last rule, that is, to propagate good practice. It has the intention of bringing awareness of how data on the traits of organisms can be collected and managed for reuse by the research community. Trait observations are relevant to a broad interdisciplinary community of field biologists, synthesis ecologists, evolutionary biologists, computer scientists and database managers. We hope these basic guidelines can be useful as a starter for active communication in disseminating such integrative knowledge and in how to make trait data future-proof. We invite the scientific community to participate in this effort at http://opentraits.org/best-practices.html.

AB - Traits have become a crucial part of ecological and evolutionary sciences, helping researchers understand the function of an organism's morphology, physiology, growth and life history, with effects on fitness, behaviour, interactions with the environment and ecosystem processes. However, measuring, compiling and analysing trait data comes with data-scientific challenges. We offer 10 (mostly) simple rules, with some detailed extensions, as a guide in making critical decisions that consider the entire life cycle of trait data. This article is particularly motivated by its last rule, that is, to propagate good practice. It has the intention of bringing awareness of how data on the traits of organisms can be collected and managed for reuse by the research community. Trait observations are relevant to a broad interdisciplinary community of field biologists, synthesis ecologists, evolutionary biologists, computer scientists and database managers. We hope these basic guidelines can be useful as a starter for active communication in disseminating such integrative knowledge and in how to make trait data future-proof. We invite the scientific community to participate in this effort at http://opentraits.org/best-practices.html.

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KW - data science

KW - FAIR principles

KW - good practices

KW - metadata

KW - open science

KW - phenotype

KW - trait data

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DO - 10.1111/2041-210X.14033

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AN - SCOPUS:85142620212

SN - 2041-210X

VL - 14

SP - 444

EP - 458

JO - Methods in Ecology and Evolution

JF - Methods in Ecology and Evolution

IS - 2

ER -

Ten (mostly) simple rules to future-proof trait data in ecological and evolutionary sciences

Abstract

Bibliographical note

Keywords

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