Population-Level Differentiation in Growth Rates and Leaf Traits in Seedlings of the Neotropical Live Oak Quercus oleoides Grown under Natural and Manipulated Precipitation Regimes.

Jose A Ramírez-Valiente,Timothy Longwell,Alyson Center,Jed P Sparks,Jeannine Cavender-Bares,George Pilz,Julie R Etterson,Kimberlee L Sparks

doi:10.3389/fpls.2017.00585

Abstract

Widely distributed species are normally subjected to spatial heterogeneity in environmental conditions. In sessile organisms like plants, adaptive evolution and phenotypic plasticity of key functional traits are the main mechanisms through which species can respond to environmental heterogeneity and climate change. While extended research has been carried out in temperate species in this regard, there is still limited knowledge as to how species from seasonally-dry tropical climates respond to spatial and temporal variation in environmental conditions. In fact, studies of intraspecific genetically-based differences in functional traits are still largely unknown and studies in these ecosystems have largely focused on in situ comparisons where environmental and genetic effects cannot be differentiated. In this study, we tested for ecotypic differentiation and phenotypic plasticity in leaf economics spectrum (LES) traits, water use efficiency and growth rates under natural and manipulated precipitation regimes in a common garden experiment where seedlings of eight populations of the neotropical live oak Quercus oleoides were established. We also examined the extent to which intraspecific trait variation was associated with plant performance under different water availability. Similar to interspecific patterns among seasonally-dry tropical tree species, live oak populations with long and severe dry seasons had higher leaf nitrogen content and growth rates than mesic populations, which is consistent with a “fast” resource-acquisition strategy aimed to maximize carbon uptake during the wet season. Specific leaf area (SLA) was the best predictor of plant performance, but contrary to expectations, it was negatively associated with relative and absolute growth rates. This observation was partially explained by the negative association between SLA and area-based photosynthetic rates, which is contrary to LES expectations but similar to other recent intraspecific studies on evergreen oaks. Overall, our study shows strong intraspecific differences in functional traits in a tropical oak, Quercus oleoides, and suggests that precipitation regime has played an important role in driving adaptive divergence in this widespread species.

Highlights

Populations of widespread species often experience a broad range of environmental conditions (Marchin et al, 2008; PegueroPina et al, 2014)
The supplemental water supply in the dry season was intended to match that of the most mesic dry season conditions in the species range but not to simulate the wet season; as a consequence, plants in BOTH and WDS treatments had more negative ψpd in the dry season than in the wet season, and season had a strong effect on ψpd regardless of watering treatment (χ12 = 2807.45, P < 0.001, Figure 2)
We tested for population differentiation and phenotypic plasticity of leaf economics traits, water use efficiency and growth rates in seedlings of Quercus oleoides grown under natural and manipulated precipitation regimes in a common garden in southern Honduras

Summary

Introduction

Populations of widespread species often experience a broad range of environmental conditions (Marchin et al, 2008; PegueroPina et al, 2014). Both adaptation of key functional traits to local environments and phenotypic plasticity are the primary mechanisms by which populations of sessile species, like plants, respond to environmental heterogeneity (Kawecki and Ebert, 2004; Valladareset al., 2006; Savolainen et al, 2007; Pfennig et al, 2010; Matesanz and Valladares, 2014). At one end of the spectrum, resource-acquisition strategies are characterized by leaves that require low structural investment and have high productivity but short leaf life-spans. Instantaneous WUE can be estimated using gas exchange measurements, while stable carbon isotope composition can be used to estimate WUE over the period of leaf development and carbon accumulation (Farquhar et al, 1982)

Methods

Results

Conclusion