TY - JOUR
T1 - The Influence of Ecosystem and Phylogeny on Tropical Tree Crown Size and Shape
AU - Shenkin, Alexander
AU - Bentley, Lisa Patrick
AU - Oliveras, Imma
AU - Salinas, Norma
AU - Adu-Bredu, Stephen
AU - Marimon-Junior, Ben Hur
AU - Marimon, Beatriz S.
AU - Peprah, Theresa
AU - Choque, Efrain Lopez
AU - Trujillo Rodriguez, Lucio
AU - Clemente Arenas, Edith Rosario
AU - Adonteng, Christian
AU - Seidu, John
AU - Passos, Fabio Barbosa
AU - Reis, Simone Matias
AU - Blonder, Benjamin
AU - Silman, Miles
AU - Enquist, Brian J.
AU - Asner, Gregory P.
AU - Malhi, Yadvinder
N1 - Publisher Copyright:
© Copyright © 2020 Shenkin, Bentley, Oliveras, Salinas, Adu-Bredu, Marimon-Junior, Marimon, Peprah, Choque, Trujillo Rodriguez, Clemente Arenas, Adonteng, Seidu, Passos, Reis, Blonder, Silman, Enquist, Asner and Malhi.
PY - 2020/10/9
Y1 - 2020/10/9
N2 - The sizes and shapes of tree crowns are of fundamental importance in ecology, yet understanding the forces that determine them remains elusive. A cardinal question facing ecologists is the degree to which general and non-specific vs. ecological and context-dependent processes are responsible for shaping tree crowns. Here, we test this question for the first time across diverse tropical ecosystems. Using trees from 20 plots varying in elevation, precipitation, and ecosystem type across the paleo- and neo-tropics, we test the relationship between crown dimensions and tree size. By analyzing these scaling relationships across environmental gradients, biogeographic regions, and phylogenetic distance, we extend Metabolic Scaling Theory (MST) predictions to include how local selective pressures shape variation in crown dimensions. Across all sites, we find strong agreement between mean trends and MST predictions for the scaling of crown size and shape, but large variation around the mean. While MST explained approximately half of the observed variation in tree crown dimensions, we find that local, ecosystem, and phylogenetic predictors account for the half of the residual variation. Crown scaling does not change significantly across regions, but does change across ecosystem types, where savanna tree crowns grow more quickly with tree girth than forest tree crowns. Crowns of legumes were wider and more voluminous than those of other taxa. Thus, while MST can accurately describe the central tendency of tree crown size, local ecological conditions and evolutionary history appear to modify the scaling of crown shape. Importantly, our extension of MST incorporating these differences accounts for the mechanisms driving variation in the scaling of crown dimensions across the tropics. We present allometric equations for the prediction of crown dimensions across tropical ecosystems. These results are critical when scaling the function of individual trees to larger spatial scales or incorporating the size and shape of tree crowns in global biogeochemical models.
AB - The sizes and shapes of tree crowns are of fundamental importance in ecology, yet understanding the forces that determine them remains elusive. A cardinal question facing ecologists is the degree to which general and non-specific vs. ecological and context-dependent processes are responsible for shaping tree crowns. Here, we test this question for the first time across diverse tropical ecosystems. Using trees from 20 plots varying in elevation, precipitation, and ecosystem type across the paleo- and neo-tropics, we test the relationship between crown dimensions and tree size. By analyzing these scaling relationships across environmental gradients, biogeographic regions, and phylogenetic distance, we extend Metabolic Scaling Theory (MST) predictions to include how local selective pressures shape variation in crown dimensions. Across all sites, we find strong agreement between mean trends and MST predictions for the scaling of crown size and shape, but large variation around the mean. While MST explained approximately half of the observed variation in tree crown dimensions, we find that local, ecosystem, and phylogenetic predictors account for the half of the residual variation. Crown scaling does not change significantly across regions, but does change across ecosystem types, where savanna tree crowns grow more quickly with tree girth than forest tree crowns. Crowns of legumes were wider and more voluminous than those of other taxa. Thus, while MST can accurately describe the central tendency of tree crown size, local ecological conditions and evolutionary history appear to modify the scaling of crown shape. Importantly, our extension of MST incorporating these differences accounts for the mechanisms driving variation in the scaling of crown dimensions across the tropics. We present allometric equations for the prediction of crown dimensions across tropical ecosystems. These results are critical when scaling the function of individual trees to larger spatial scales or incorporating the size and shape of tree crowns in global biogeochemical models.
KW - Metabolic Scaling Theory
KW - allometry
KW - tree architecture
KW - tree crowns
KW - tropical trees
UR - http://www.scopus.com/inward/record.url?scp=85097441946&partnerID=8YFLogxK
UR - http://www.scopus.com/inward/citedby.url?scp=85097441946&partnerID=8YFLogxK
U2 - 10.3389/ffgc.2020.501757
DO - 10.3389/ffgc.2020.501757
M3 - Article
AN - SCOPUS:85097441946
SN - 2624-893X
VL - 3
JO - Frontiers in Forests and Global Change
JF - Frontiers in Forests and Global Change
M1 - 501757
ER -