Linking seed size and number to trait syndromes in trees

Michal Bogdziewicz; Marie Claire Aravena Acuña; Robert Andrus; Davide Ascoli; Yves Bergeron; Daniel Brveiller; Thomas Boivin; Raul Bonal; Thomas Caignard; Maxime Cailleret; Rafael Calama; Sergio Donoso Calderon; J. Julio Camarero; Chia Hao Chang-Yang; Jerome Chave; Francesco Chianucci; Natalie L. Cleavitt; Benoit Courbaud; Andrea Cutini; Thomas Curt; Adrian J Das; Hendrik Davi; Nicolas Delpierre; Sylvain Delzon; Michael Dietze; Laurent Dormont; William Farfan-Rios; Catherine A. Gehring; Gregory S. Gilbert; Georg Gratzer; Cathryn H. Greenberg; Arthur Guignabert; Qinfeng Guo; Andrew Hacket-Pain; Arndt Hampe; Qingmin Han; Kazuhiko Hoshizaki; Ines Ibanez; Jill F. Johnstone; Valentin Journé; Thomas Kitzberger; Johannes M.H. Knops; Georges Kunstler; Richard Kobe; Jonathan G.A. Lageard; Jalene M. LaMontagne; Mateusz Ledwon; Theodor Leininger; Jean Marc Limousin; James A. Lutz; Diana Macias; Anders Marell; Eliot J.B. McIntire; Emily Moran; Renzo Motta; Jonathan A Myers; Thomas A. Nagel; Shoji Naoe; Mahoko Noguchi; Michio Oguro; Hiroko Kurokawa; Jean Marc Ourcival; Robert Parmenter; Ignacio M. Perez-Ramos; Lukasz Piechnik; Tomasz Podgórski; John Poulsen; Tong Qiu; Miranda D. Redmond; Chantal D. Reid; Kyle C. Rodman; Pavel Šamonil; Jan Holik; C. Lane Scher; Harald Schmidt Van Marle; Barbara Seget; Mitsue Shibata; Shubhi Sharma; Miles Silman; Michael A. Steele; Jacob N. Straub; I. Fang Sun; Samantha Sutton; Jennifer J Swenson; Peter A. Thomas; Maria Uriarte; Giorgio Vacchiano; Thomas T. Veblen; Boyd Wright; S. Joseph Wright; Thomas G. Whitham; Kai Zhu; Jess K. Zimmerman; Magdalna Zywiec; James S. Clark

doi:10.1111/geb.13652

Linking seed size and number to trait syndromes in trees

Michal Bogdziewicz^*
, Marie Claire Aravena Acuña
, Robert Andrus
, Davide Ascoli
, Yves Bergeron
, Daniel Brveiller
, Thomas Boivin
, Raul Bonal
, Thomas Caignard
, Maxime Cailleret
, Rafael Calama
, Sergio Donoso Calderon
, J. Julio Camarero
, Chia Hao Chang-Yang
, Jerome Chave
, Francesco Chianucci
, Natalie L. Cleavitt
, Benoit Courbaud
, Andrea Cutini
, Thomas Curt

Adrian J Das, Hendrik Davi, Nicolas Delpierre, Sylvain Delzon, Michael Dietze, Laurent Dormont, William Farfan-Rios, Catherine A. Gehring, Gregory S. Gilbert, Georg Gratzer, Cathryn H. Greenberg, Arthur Guignabert, Qinfeng Guo, Andrew Hacket-Pain, Arndt Hampe, Qingmin Han, Kazuhiko Hoshizaki, Ines Ibanez, Jill F. Johnstone, Valentin Journé, Thomas Kitzberger, Johannes M.H. Knops, Georges Kunstler, Richard Kobe, Jonathan G.A. Lageard, Jalene M. LaMontagne, Mateusz Ledwon, Theodor Leininger, Jean Marc Limousin, James A. Lutz, Diana Macias, Anders Marell, Eliot J.B. McIntire, Emily Moran, Renzo Motta, Jonathan A Myers, Thomas A. Nagel, Shoji Naoe, Mahoko Noguchi, Michio Oguro, Hiroko Kurokawa, Jean Marc Ourcival, Robert Parmenter, Ignacio M. Perez-Ramos, Lukasz Piechnik, Tomasz Podgórski, John Poulsen, Tong Qiu, Miranda D. Redmond, Chantal D. Reid, Kyle C. Rodman, Pavel Šamonil, Jan Holik, C. Lane Scher, Harald Schmidt Van Marle, Barbara Seget, Mitsue Shibata, Shubhi Sharma, Miles Silman, Michael A. Steele, Jacob N. Straub, I. Fang Sun, Samantha Sutton, Jennifer J Swenson, Peter A. Thomas, Maria Uriarte, Giorgio Vacchiano, Thomas T. Veblen, Boyd Wright, S. Joseph Wright, Thomas G. Whitham, Kai Zhu, Jess K. Zimmerman, Magdalna Zywiec, James S. Clark

^*Corresponding author for this work

Department of Health and Environmental Sciences

Université Grenoble Alpes
Adam Mickiewicz University in Poznań
Centro Austral de Investigaciones Científicas (CADIC – CONICET)
INRAE
University of Turin
Université du Québec en Abitibi-Témiscamingue
Université du Québec à Montréal
Université Paris-Saclay
Complutense University
Université de Bordeaux
Aix-Marseille Université
CSIC
Universidad de Chile
CSIC - Pyrenean Institute of Ecology
National Sun Yat-sen University
CNRS
CREA Research centre for Forestry and Wood
Cornell University
United States Geological Survey
Boston University
Centre National de la Recherche Scientifique (CNRS)
Washington University St. Louis
Northern Arizona University
University of California at Santa Cruz
University of Natural Resources and Life Sciences, Vienna
United States Department of Agriculture
University of Liverpool
and Communities (BIOGECO)
Forestry and Forest Products Research Institute
Akita Prefectural University
University of Michigan, Ann Arbor
University of Alaska Fairbanks
Universidad Nacional del Comahue
Michigan State University
Manchester Metropolitan University
DePaul University
Institute of Systematics and Evolution of Animals of the Polish Academy of Sciences
Université de Montpellier
Utah State University
University of New Mexico
Natural Resources Canada
University of California Merced
University of Ljubljana
U.S. Department of the Interior
CSIC - Institute of Natural Resources and Agrobiology of Seville
Polish Academy of Sciences
Czech University of Life Sciences Prague
Mammal Research Institute of the Polish Academy of Sciences
Duke University
Pennsylvania State University
Colorado State University
University of Wisconsin-Madison
Silva Tarouca Research Institute
Yale University
Wake Forest University
Wilkes University
The College at Brockport, State University of New York
National Dong Hwa University
Keele University
Columbia University
University of Milan
University of Colorado Boulder
University of New England
Smithsonian Institution
University of Puerto Rico

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

16 Citations (Scopus)

Abstract

Aim: Our understanding of the mechanisms that maintain forest diversity under changing climate can benefit from knowledge about traits that are closely linked to fitness. We tested whether the link between traits and seed number and seed size is consistent with two hypotheses, termed the leaf economics spectrum and the plant size syndrome, or whether reproduction represents an independent dimension related to a seed size–seed number trade-off. Location: Most of the data come from Europe, North and Central America and East Asia. A minority of the data come from South America, Africa and Australia. Time period: 1960–2022. Major taxa studied: Trees. Methods: We gathered 12 million observations of the number of seeds produced in 784 tree species. We estimated the number of seeds produced by individual trees and scaled it up to the species level. Next, we used principal components analysis and generalized joint attribute modelling (GJAM) to map seed number and size on the tree traits spectrum. Results: Incorporating seed size and number into trait analysis while controlling for environment and phylogeny with GJAM exposes relationships in trees that might otherwise remain hidden. Production of the large total biomass of seeds [product of seed number and seed size; hereafter, species seed productivity (SSP)] is associated with high leaf area, low foliar nitrogen, low specific leaf area (SLA) and dense wood. Production of high seed numbers is associated with small seeds produced by nutrient-demanding species with softwood, small leaves and high SLA. Trait covariation is consistent with opposing strategies: one fast-growing, early successional, with high dispersal, and the other slow-growing, stress-tolerant, that recruit in shaded conditions. Main conclusions: Earth system models currently assume that reproductive allocation is indifferent among plant functional types. Easily measurable seed size is a strong predictor of the seed number and species seed productivity. The connection of SSP with the functional traits can form the first basis of improved fecundity prediction across global forests.

Original language	English
Pages (from-to)	683-694
Number of pages	12
Journal	Global Ecology and Biogeography
Volume	32
Issue number	5
DOIs	https://doi.org/10.1111/geb.13652
Publication status	Published - May 2023

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

SDG 13 Climate Action

Keywords

fecundity
functional traits
leaf economics
life history strategies
size syndrome
tree recruitment

Access to Document

10.1111/geb.13652

Cite this

Bogdziewicz, M., Acuña, M. C. A., Andrus, R., Ascoli, D., Bergeron, Y., Brveiller, D., Boivin, T., Bonal, R., Caignard, T., Cailleret, M., Calama, R., Calderon, S. D., Camarero, J. J., Chang-Yang, C. H., Chave, J., Chianucci, F., Cleavitt, N. L., Courbaud, B., Cutini, A., ... Clark, J. S. (2023). Linking seed size and number to trait syndromes in trees. Global Ecology and Biogeography, 32(5), 683-694. https://doi.org/10.1111/geb.13652

@article{c096131f5ead432cb7bfcc097e141724,

title = "Linking seed size and number to trait syndromes in trees",

abstract = "Aim: Our understanding of the mechanisms that maintain forest diversity under changing climate can benefit from knowledge about traits that are closely linked to fitness. We tested whether the link between traits and seed number and seed size is consistent with two hypotheses, termed the leaf economics spectrum and the plant size syndrome, or whether reproduction represents an independent dimension related to a seed size–seed number trade-off. Location: Most of the data come from Europe, North and Central America and East Asia. A minority of the data come from South America, Africa and Australia. Time period: 1960–2022. Major taxa studied: Trees. Methods: We gathered 12 million observations of the number of seeds produced in 784 tree species. We estimated the number of seeds produced by individual trees and scaled it up to the species level. Next, we used principal components analysis and generalized joint attribute modelling (GJAM) to map seed number and size on the tree traits spectrum. Results: Incorporating seed size and number into trait analysis while controlling for environment and phylogeny with GJAM exposes relationships in trees that might otherwise remain hidden. Production of the large total biomass of seeds [product of seed number and seed size; hereafter, species seed productivity (SSP)] is associated with high leaf area, low foliar nitrogen, low specific leaf area (SLA) and dense wood. Production of high seed numbers is associated with small seeds produced by nutrient-demanding species with softwood, small leaves and high SLA. Trait covariation is consistent with opposing strategies: one fast-growing, early successional, with high dispersal, and the other slow-growing, stress-tolerant, that recruit in shaded conditions. Main conclusions: Earth system models currently assume that reproductive allocation is indifferent among plant functional types. Easily measurable seed size is a strong predictor of the seed number and species seed productivity. The connection of SSP with the functional traits can form the first basis of improved fecundity prediction across global forests.",

keywords = "fecundity, functional traits, leaf economics, life history strategies, size syndrome, tree recruitment",

author = "Michal Bogdziewicz and Acu{\~n}a, \{Marie Claire Aravena\} and Robert Andrus and Davide Ascoli and Yves Bergeron and Daniel Brveiller and Thomas Boivin and Raul Bonal and Thomas Caignard and Maxime Cailleret and Rafael Calama and Calderon, \{Sergio Donoso\} and Camarero, \{J. Julio\} and Chang-Yang, \{Chia Hao\} and Jerome Chave and Francesco Chianucci and Cleavitt, \{Natalie L.\} and Benoit Courbaud and Andrea Cutini and Thomas Curt and Adrian J Das and Hendrik Davi and Nicolas Delpierre and Sylvain Delzon and Michael Dietze and Laurent Dormont and William Farfan-Rios and Gehring, \{Catherine A.\} and Gilbert, \{Gregory S.\} and Georg Gratzer and Greenberg, \{Cathryn H.\} and Arthur Guignabert and Qinfeng Guo and Andrew Hacket-Pain and Arndt Hampe and Qingmin Han and Kazuhiko Hoshizaki and Ines Ibanez and Johnstone, \{Jill F.\} and Valentin Journ{\'e} and Thomas Kitzberger and Knops, \{Johannes M.H.\} and Georges Kunstler and Richard Kobe and Lageard, \{Jonathan G.A.\} and LaMontagne, \{Jalene M.\} and Mateusz Ledwon and Theodor Leininger and Limousin, \{Jean Marc\} and Lutz, \{James A.\} and Diana Macias and Anders Marell and McIntire, \{Eliot J.B.\} and Emily Moran and Renzo Motta and Jonathan A Myers and Nagel, \{Thomas A.\} and Shoji Naoe and Mahoko Noguchi and Michio Oguro and Hiroko Kurokawa and Ourcival, \{Jean Marc\} and Robert Parmenter and Perez-Ramos, \{Ignacio M.\} and Lukasz Piechnik and Tomasz Podg{\'o}rski and John Poulsen and Tong Qiu and Redmond, \{Miranda D.\} and Reid, \{Chantal D.\} and Rodman, \{Kyle C.\} and Pavel {\v S}amonil and Jan Holik and Scher, \{C. Lane\} and Van Marle, \{Harald Schmidt\} and Barbara Seget and Mitsue Shibata and Shubhi Sharma and Miles Silman and Steele, \{Michael A.\} and Straub, \{Jacob N.\} and Sun, \{I. Fang\} and Samantha Sutton and Jennifer J Swenson and Thomas, \{Peter A.\} and Maria Uriarte and Giorgio Vacchiano and Veblen, \{Thomas T.\} and Boyd Wright and Wright, \{S. Joseph\} and Whitham, \{Thomas G.\} and Kai Zhu and Zimmerman, \{Jess K.\} and Magdalna Zywiec and Clark, \{James S.\}",

note = "Publisher Copyright: {\textcopyright} 2023 John Wiley \& Sons Ltd.",

year = "2023",

month = may,

doi = "10.1111/geb.13652",

language = "English",

volume = "32",

pages = "683--694",

journal = "Global Ecology and Biogeography",

issn = "1466-822X",

number = "5",

}

Bogdziewicz, M, Acuña, MCA, Andrus, R, Ascoli, D, Bergeron, Y, Brveiller, D, Boivin, T, Bonal, R, Caignard, T, Cailleret, M, Calama, R, Calderon, SD, Camarero, JJ, Chang-Yang, CH, Chave, J, Chianucci, F, Cleavitt, NL, Courbaud, B, Cutini, A, Curt, T, Das, AJ, Davi, H, Delpierre, N, Delzon, S, Dietze, M, Dormont, L, Farfan-Rios, W, Gehring, CA, Gilbert, GS, Gratzer, G, Greenberg, CH, Guignabert, A, Guo, Q, Hacket-Pain, A, Hampe, A, Han, Q, Hoshizaki, K, Ibanez, I, Johnstone, JF, Journé, V, Kitzberger, T, Knops, JMH, Kunstler, G, Kobe, R, Lageard, JGA, LaMontagne, JM, Ledwon, M, Leininger, T, Limousin, JM, Lutz, JA, Macias, D, Marell, A, McIntire, EJB, Moran, E, Motta, R, Myers, JA, Nagel, TA, Naoe, S, Noguchi, M, Oguro, M, Kurokawa, H, Ourcival, JM, Parmenter, R, Perez-Ramos, IM, Piechnik, L, Podgórski, T, Poulsen, J, Qiu, T, Redmond, MD, Reid, CD, Rodman, KC, Šamonil, P, Holik, J, Scher, CL, Van Marle, HS, Seget, B, Shibata, M, Sharma, S, Silman, M, Steele, MA, Straub, JN, Sun, IF, Sutton, S, Swenson, JJ, Thomas, PA, Uriarte, M, Vacchiano, G, Veblen, TT, Wright, B, Wright, SJ, Whitham, TG, Zhu, K, Zimmerman, JK, Zywiec, M & Clark, JS 2023, 'Linking seed size and number to trait syndromes in trees', Global Ecology and Biogeography, vol. 32, no. 5, pp. 683-694. https://doi.org/10.1111/geb.13652

TY - JOUR

T1 - Linking seed size and number to trait syndromes in trees

AU - Bogdziewicz, Michal

AU - Acuña, Marie Claire Aravena

AU - Andrus, Robert

AU - Ascoli, Davide

AU - Bergeron, Yves

AU - Brveiller, Daniel

AU - Boivin, Thomas

AU - Bonal, Raul

AU - Caignard, Thomas

AU - Cailleret, Maxime

AU - Calama, Rafael

AU - Calderon, Sergio Donoso

AU - Camarero, J. Julio

AU - Chang-Yang, Chia Hao

AU - Chave, Jerome

AU - Chianucci, Francesco

AU - Cleavitt, Natalie L.

AU - Courbaud, Benoit

AU - Cutini, Andrea

AU - Curt, Thomas

AU - Das, Adrian J

AU - Davi, Hendrik

AU - Delpierre, Nicolas

AU - Delzon, Sylvain

AU - Dietze, Michael

AU - Dormont, Laurent

AU - Farfan-Rios, William

AU - Gehring, Catherine A.

AU - Gilbert, Gregory S.

AU - Gratzer, Georg

AU - Greenberg, Cathryn H.

AU - Guignabert, Arthur

AU - Guo, Qinfeng

AU - Hacket-Pain, Andrew

AU - Hampe, Arndt

AU - Han, Qingmin

AU - Hoshizaki, Kazuhiko

AU - Ibanez, Ines

AU - Johnstone, Jill F.

AU - Journé, Valentin

AU - Kitzberger, Thomas

AU - Knops, Johannes M.H.

AU - Kunstler, Georges

AU - Kobe, Richard

AU - Lageard, Jonathan G.A.

AU - LaMontagne, Jalene M.

AU - Ledwon, Mateusz

AU - Leininger, Theodor

AU - Limousin, Jean Marc

AU - Lutz, James A.

AU - Macias, Diana

AU - Marell, Anders

AU - McIntire, Eliot J.B.

AU - Moran, Emily

AU - Motta, Renzo

AU - Myers, Jonathan A

AU - Nagel, Thomas A.

AU - Naoe, Shoji

AU - Noguchi, Mahoko

AU - Oguro, Michio

AU - Kurokawa, Hiroko

AU - Ourcival, Jean Marc

AU - Parmenter, Robert

AU - Perez-Ramos, Ignacio M.

AU - Piechnik, Lukasz

AU - Podgórski, Tomasz

AU - Poulsen, John

AU - Qiu, Tong

AU - Redmond, Miranda D.

AU - Reid, Chantal D.

AU - Rodman, Kyle C.

AU - Šamonil, Pavel

AU - Holik, Jan

AU - Scher, C. Lane

AU - Van Marle, Harald Schmidt

AU - Seget, Barbara

AU - Shibata, Mitsue

AU - Sharma, Shubhi

AU - Silman, Miles

AU - Steele, Michael A.

AU - Straub, Jacob N.

AU - Sun, I. Fang

AU - Sutton, Samantha

AU - Swenson, Jennifer J

AU - Thomas, Peter A.

AU - Uriarte, Maria

AU - Vacchiano, Giorgio

AU - Veblen, Thomas T.

AU - Wright, Boyd

AU - Wright, S. Joseph

AU - Whitham, Thomas G.

AU - Zhu, Kai

AU - Zimmerman, Jess K.

AU - Zywiec, Magdalna

AU - Clark, James S.

PY - 2023/5

Y1 - 2023/5

N2 - Aim: Our understanding of the mechanisms that maintain forest diversity under changing climate can benefit from knowledge about traits that are closely linked to fitness. We tested whether the link between traits and seed number and seed size is consistent with two hypotheses, termed the leaf economics spectrum and the plant size syndrome, or whether reproduction represents an independent dimension related to a seed size–seed number trade-off. Location: Most of the data come from Europe, North and Central America and East Asia. A minority of the data come from South America, Africa and Australia. Time period: 1960–2022. Major taxa studied: Trees. Methods: We gathered 12 million observations of the number of seeds produced in 784 tree species. We estimated the number of seeds produced by individual trees and scaled it up to the species level. Next, we used principal components analysis and generalized joint attribute modelling (GJAM) to map seed number and size on the tree traits spectrum. Results: Incorporating seed size and number into trait analysis while controlling for environment and phylogeny with GJAM exposes relationships in trees that might otherwise remain hidden. Production of the large total biomass of seeds [product of seed number and seed size; hereafter, species seed productivity (SSP)] is associated with high leaf area, low foliar nitrogen, low specific leaf area (SLA) and dense wood. Production of high seed numbers is associated with small seeds produced by nutrient-demanding species with softwood, small leaves and high SLA. Trait covariation is consistent with opposing strategies: one fast-growing, early successional, with high dispersal, and the other slow-growing, stress-tolerant, that recruit in shaded conditions. Main conclusions: Earth system models currently assume that reproductive allocation is indifferent among plant functional types. Easily measurable seed size is a strong predictor of the seed number and species seed productivity. The connection of SSP with the functional traits can form the first basis of improved fecundity prediction across global forests.

AB - Aim: Our understanding of the mechanisms that maintain forest diversity under changing climate can benefit from knowledge about traits that are closely linked to fitness. We tested whether the link between traits and seed number and seed size is consistent with two hypotheses, termed the leaf economics spectrum and the plant size syndrome, or whether reproduction represents an independent dimension related to a seed size–seed number trade-off. Location: Most of the data come from Europe, North and Central America and East Asia. A minority of the data come from South America, Africa and Australia. Time period: 1960–2022. Major taxa studied: Trees. Methods: We gathered 12 million observations of the number of seeds produced in 784 tree species. We estimated the number of seeds produced by individual trees and scaled it up to the species level. Next, we used principal components analysis and generalized joint attribute modelling (GJAM) to map seed number and size on the tree traits spectrum. Results: Incorporating seed size and number into trait analysis while controlling for environment and phylogeny with GJAM exposes relationships in trees that might otherwise remain hidden. Production of the large total biomass of seeds [product of seed number and seed size; hereafter, species seed productivity (SSP)] is associated with high leaf area, low foliar nitrogen, low specific leaf area (SLA) and dense wood. Production of high seed numbers is associated with small seeds produced by nutrient-demanding species with softwood, small leaves and high SLA. Trait covariation is consistent with opposing strategies: one fast-growing, early successional, with high dispersal, and the other slow-growing, stress-tolerant, that recruit in shaded conditions. Main conclusions: Earth system models currently assume that reproductive allocation is indifferent among plant functional types. Easily measurable seed size is a strong predictor of the seed number and species seed productivity. The connection of SSP with the functional traits can form the first basis of improved fecundity prediction across global forests.

KW - fecundity

KW - functional traits

KW - leaf economics

KW - life history strategies

KW - size syndrome

KW - tree recruitment

UR - https://www.scopus.com/pages/publications/85150412945

U2 - 10.1111/geb.13652

DO - 10.1111/geb.13652

M3 - Article

AN - SCOPUS:85150412945

SN - 1466-822X

VL - 32

SP - 683

EP - 694

JO - Global Ecology and Biogeography

JF - Global Ecology and Biogeography

IS - 5

ER -

Linking seed size and number to trait syndromes in trees

Abstract

UN SDGs

Keywords

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