Robustness of trait connections across environmental gradients and growth forms

Habacuc Flores-Moreno; Farideh Fazayeli; Arindam Banerjee; Abhirup Datta; Jens Kattge; Ethan E. Butler; Owen K. Atkin; Kirk Wythers; Ming Chen; Madhur Anand; Michael Bahn; Chaeho Byun; J. Hans C. Cornelissen; Joseph Craine; Andres Gonzalez-Melo; Wesley N. Hattingh; Steven Jansen; Nathan J.B. Kraft; Koen Kramer; Daniel C. Laughlin; Vanessa Minden; Ülo Niinemets; Vladimir Onipchenko; Josep Peñuelas; Nadejda A. Soudzilovskaia; Rhiannon L. Dalrymple; Peter B. Reich

doi:10.1111/geb.12996

Robustness of trait connections across environmental gradients and growth forms

Habacuc Flores-Moreno, Farideh Fazayeli, Arindam Banerjee, Abhirup Datta, Jens Kattge, Ethan E. Butler, Owen K. Atkin, Kirk Wythers, Ming Chen, Madhur Anand, Michael Bahn, Chaeho Byun, J. Hans C. Cornelissen, Joseph Craine, Andres Gonzalez-Melo, Wesley N. Hattingh, Steven Jansen, Nathan J.B. Kraft, Koen Kramer, Daniel C. LaughlinVanessa Minden, Ülo Niinemets, Vladimir Onipchenko, Josep Peñuelas, Nadejda A. Soudzilovskaia, Rhiannon L. Dalrymple, Peter B. Reich

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Abstract

Aim: Plant trait databases often contain traits that are correlated, but for whom direct (undirected statistical dependency) and indirect (mediated by other traits) connections may be confounded. The confounding of correlation and connection hinders our understanding of plant strategies, and how these vary among growth forms and climate zones. We identified the direct and indirect connections across plant traits relevant to competition, resource acquisition and reproductive strategies using a global database and explored whether connections within and between traits from different tissue types vary across climates and growth forms. Location: Global. Major taxa studied: Plants. Time period: Present. Methods: We used probabilistic graphical models and a database of 10 plant traits (leaf area, specific leaf area, mass- and area-based leaf nitrogen and phosphorous content, leaf life span, plant height, stem specific density and seed mass) with 16,281 records to describe direct and indirect connections across woody and non-woody plants across tropical, temperate, arid, cold and polar regions. Results: Trait networks based on direct connections are sparser than those based on correlations. Land plants had high connectivity across traits within and between tissue types; leaf life span and stem specific density shared direct connections with all other traits. For both growth forms, two groups of traits form modules of more highly connected traits; one related to resource acquisition, the other to plant architecture and reproduction. Woody species had higher trait network modularity in polar compared to temperate and tropical climates, while non-woody species did not show significant differences in modularity across climate regions. Main conclusions: Plant traits are highly connected both within and across tissue types, yet traits segregate into persistent modules of traits. Variation in the modularity of trait networks suggests that trait connectivity is shaped by prevailing environmental conditions and demonstrates that plants of different growth forms use alternative strategies to cope with local conditions.

Original language	English (US)
Pages (from-to)	1806-1826
Number of pages	21
Journal	Global Ecology and Biogeography
Volume	28
Issue number	12
DOIs	https://doi.org/10.1111/geb.12996
State	Published - Dec 1 2019

Bibliographical note

Publisher Copyright:
© 2019 John Wiley & Sons Ltd

Keywords

leaf traits
plant functional traits
plant strategy integration
seed traits
stem traits
trait interdependence
trait networks

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Flores-Moreno, H., Fazayeli, F., Banerjee, A., Datta, A., Kattge, J., Butler, E. E., Atkin, O. K., Wythers, K., Chen, M., Anand, M., Bahn, M., Byun, C., Cornelissen, J. H. C., Craine, J., Gonzalez-Melo, A., Hattingh, W. N., Jansen, S., Kraft, N. J. B., Kramer, K., ... Reich, P. B. (2019). Robustness of trait connections across environmental gradients and growth forms. Global Ecology and Biogeography, 28(12), 1806-1826. https://doi.org/10.1111/geb.12996

Flores-Moreno, H, Fazayeli, F, Banerjee, A, Datta, A, Kattge, J, Butler, EE, Atkin, OK, Wythers, K, Chen, M, Anand, M, Bahn, M, Byun, C, Cornelissen, JHC, Craine, J, Gonzalez-Melo, A, Hattingh, WN, Jansen, S, Kraft, NJB, Kramer, K, Laughlin, DC, Minden, V, Niinemets, Ü, Onipchenko, V, Peñuelas, J, Soudzilovskaia, NA, Dalrymple, RL & Reich, PB 2019, 'Robustness of trait connections across environmental gradients and growth forms', Global Ecology and Biogeography, vol. 28, no. 12, pp. 1806-1826. https://doi.org/10.1111/geb.12996

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title = "Robustness of trait connections across environmental gradients and growth forms",

abstract = "Aim: Plant trait databases often contain traits that are correlated, but for whom direct (undirected statistical dependency) and indirect (mediated by other traits) connections may be confounded. The confounding of correlation and connection hinders our understanding of plant strategies, and how these vary among growth forms and climate zones. We identified the direct and indirect connections across plant traits relevant to competition, resource acquisition and reproductive strategies using a global database and explored whether connections within and between traits from different tissue types vary across climates and growth forms. Location: Global. Major taxa studied: Plants. Time period: Present. Methods: We used probabilistic graphical models and a database of 10 plant traits (leaf area, specific leaf area, mass- and area-based leaf nitrogen and phosphorous content, leaf life span, plant height, stem specific density and seed mass) with 16,281 records to describe direct and indirect connections across woody and non-woody plants across tropical, temperate, arid, cold and polar regions. Results: Trait networks based on direct connections are sparser than those based on correlations. Land plants had high connectivity across traits within and between tissue types; leaf life span and stem specific density shared direct connections with all other traits. For both growth forms, two groups of traits form modules of more highly connected traits; one related to resource acquisition, the other to plant architecture and reproduction. Woody species had higher trait network modularity in polar compared to temperate and tropical climates, while non-woody species did not show significant differences in modularity across climate regions. Main conclusions: Plant traits are highly connected both within and across tissue types, yet traits segregate into persistent modules of traits. Variation in the modularity of trait networks suggests that trait connectivity is shaped by prevailing environmental conditions and demonstrates that plants of different growth forms use alternative strategies to cope with local conditions.",

keywords = "leaf traits, plant functional traits, plant strategy integration, seed traits, stem traits, trait interdependence, trait networks",

author = "Habacuc Flores-Moreno and Farideh Fazayeli and Arindam Banerjee and Abhirup Datta and Jens Kattge and Butler, {Ethan E.} and Atkin, {Owen K.} and Kirk Wythers and Ming Chen and Madhur Anand and Michael Bahn and Chaeho Byun and Cornelissen, {J. Hans C.} and Joseph Craine and Andres Gonzalez-Melo and Hattingh, {Wesley N.} and Steven Jansen and Kraft, {Nathan J.B.} and Koen Kramer and Laughlin, {Daniel C.} and Vanessa Minden and {\"U}lo Niinemets and Vladimir Onipchenko and Josep Pe{\~n}uelas and Soudzilovskaia, {Nadejda A.} and Dalrymple, {Rhiannon L.} and Reich, {Peter B.}",

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AU - Flores-Moreno, Habacuc

AU - Fazayeli, Farideh

AU - Banerjee, Arindam

AU - Datta, Abhirup

AU - Kattge, Jens

AU - Butler, Ethan E.

AU - Atkin, Owen K.

AU - Wythers, Kirk

AU - Chen, Ming

AU - Anand, Madhur

AU - Bahn, Michael

AU - Byun, Chaeho

AU - Cornelissen, J. Hans C.

AU - Craine, Joseph

AU - Gonzalez-Melo, Andres

AU - Hattingh, Wesley N.

AU - Jansen, Steven

AU - Kraft, Nathan J.B.

AU - Kramer, Koen

AU - Laughlin, Daniel C.

AU - Minden, Vanessa

AU - Niinemets, Ülo

AU - Onipchenko, Vladimir

AU - Peñuelas, Josep

AU - Soudzilovskaia, Nadejda A.

AU - Dalrymple, Rhiannon L.

AU - Reich, Peter B.

PY - 2019/12/1

Y1 - 2019/12/1

N2 - Aim: Plant trait databases often contain traits that are correlated, but for whom direct (undirected statistical dependency) and indirect (mediated by other traits) connections may be confounded. The confounding of correlation and connection hinders our understanding of plant strategies, and how these vary among growth forms and climate zones. We identified the direct and indirect connections across plant traits relevant to competition, resource acquisition and reproductive strategies using a global database and explored whether connections within and between traits from different tissue types vary across climates and growth forms. Location: Global. Major taxa studied: Plants. Time period: Present. Methods: We used probabilistic graphical models and a database of 10 plant traits (leaf area, specific leaf area, mass- and area-based leaf nitrogen and phosphorous content, leaf life span, plant height, stem specific density and seed mass) with 16,281 records to describe direct and indirect connections across woody and non-woody plants across tropical, temperate, arid, cold and polar regions. Results: Trait networks based on direct connections are sparser than those based on correlations. Land plants had high connectivity across traits within and between tissue types; leaf life span and stem specific density shared direct connections with all other traits. For both growth forms, two groups of traits form modules of more highly connected traits; one related to resource acquisition, the other to plant architecture and reproduction. Woody species had higher trait network modularity in polar compared to temperate and tropical climates, while non-woody species did not show significant differences in modularity across climate regions. Main conclusions: Plant traits are highly connected both within and across tissue types, yet traits segregate into persistent modules of traits. Variation in the modularity of trait networks suggests that trait connectivity is shaped by prevailing environmental conditions and demonstrates that plants of different growth forms use alternative strategies to cope with local conditions.

AB - Aim: Plant trait databases often contain traits that are correlated, but for whom direct (undirected statistical dependency) and indirect (mediated by other traits) connections may be confounded. The confounding of correlation and connection hinders our understanding of plant strategies, and how these vary among growth forms and climate zones. We identified the direct and indirect connections across plant traits relevant to competition, resource acquisition and reproductive strategies using a global database and explored whether connections within and between traits from different tissue types vary across climates and growth forms. Location: Global. Major taxa studied: Plants. Time period: Present. Methods: We used probabilistic graphical models and a database of 10 plant traits (leaf area, specific leaf area, mass- and area-based leaf nitrogen and phosphorous content, leaf life span, plant height, stem specific density and seed mass) with 16,281 records to describe direct and indirect connections across woody and non-woody plants across tropical, temperate, arid, cold and polar regions. Results: Trait networks based on direct connections are sparser than those based on correlations. Land plants had high connectivity across traits within and between tissue types; leaf life span and stem specific density shared direct connections with all other traits. For both growth forms, two groups of traits form modules of more highly connected traits; one related to resource acquisition, the other to plant architecture and reproduction. Woody species had higher trait network modularity in polar compared to temperate and tropical climates, while non-woody species did not show significant differences in modularity across climate regions. Main conclusions: Plant traits are highly connected both within and across tissue types, yet traits segregate into persistent modules of traits. Variation in the modularity of trait networks suggests that trait connectivity is shaped by prevailing environmental conditions and demonstrates that plants of different growth forms use alternative strategies to cope with local conditions.

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KW - plant functional traits

KW - plant strategy integration

KW - seed traits

KW - stem traits

KW - trait interdependence

KW - trait networks

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Robustness of trait connections across environmental gradients and growth forms

Abstract

Bibliographical note

Keywords

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