Liana Functional Assembly Along the Hydrological Gradient in Central Amazonia

Overview

Journal Oecologia

Specialty Environmental Health

Date 2022 Sep 24

PMID 36152059

Authors

E X Rocha

A Nogueira

F R C Costa

R J Burnham

C S Gerolamo

C F Honorato

J Schietti

Affiliations

Soon will be listed here.

Abstract

Soil hydrology, nutrient availability, and forest disturbance determine the variation of tropical tree species composition locally. However, most habitat filtering is explained by tree species' hydraulic traits along the hydrological gradient. We asked whether these patterns apply to lianas. At the community level, we investigated whether hydrological gradient, soil fertility, and forest disturbance explain liana species composition and whether liana species-environment relationships are mediated by leaf and stem wood functional traits. We sampled liana species composition in 18 1-ha plots across a 64 km landscape in Central Amazonia and measured eleven leaf and stem wood traits across 115 liana species in 2000 individuals. We correlated liana species composition, summarized using PCoA with the functional composition summarized using principal coordinate analysis (PCA), employing species mean values of traits at the plot level. We tested the relationship between ordination axes and environmental gradients. Liana species composition was highly correlated with functional composition. Taxonomic (PCoA) and functional (PCA) compositions were strongly associated with the hydrological gradient, with a slight influence from forest disturbance on functional composition. Species in valley areas had larger stomata size and higher proportions of self-supporting xylem than in plateaus. Liana species on plateaus invest more in fast-growing leaves (higher SLA), although they show a higher wood density. Our study reveals that lianas use different functional solutions in dealing with each end of the hydrological gradient and that the relationships among habitat preferences and traits explain lianas species distributions less directly than previously found in trees.

Citing Articles

Local Forest Structure and Host Specificity Influence Liana Community Composition in a Moist Central African Forest.

Kacamak B, Rejou-Mechain M, Rowe N, Rossi V, Barbier N, Bazan S Ecol Evol. 2025; 15(3):e71075.

PMID: 40078322 PMC: 11896882. DOI: 10.1002/ece3.71075.

Lianas in tropical dry seasonal forests have a high hydraulic efficiency but not always a higher embolism resistance than lianas in rainforests.

Gerolamo C, Pereira L, Costa F, Jansen S, Angyalossy V, Nogueira A Ann Bot. 2024; 134(2):337-350.

PMID: 38721801 PMC: 11232521. DOI: 10.1093/aob/mcae077.

Environmental heterogeneity influences liana community differentiation across a Neotropical rainforest landscape.

Ek-Rodriguez I, Meave J, Navarrete-Segueda A, Gonzalez-Arqueros M, Ibarra-Manriquez G Ecol Evol. 2024; 14(3):e11170.

PMID: 38529022 PMC: 10961474. DOI: 10.1002/ece3.11170.

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