Intraspecific variation in seedling growth responses of a relict tree species Euptelea pleiospermum to precipitation manipulation along an elevation gradient

• Published in: Plant ecology Vol. 222; no. 12; pp. 1297 - 1312
• Main Authors: Wu, Hao, Wei, Xinzeng, Jiang, Mingxi
• Format: Journal Article
• Language: English
• Published: Dordrecht Springer Netherlands 01.12.2021; Springer; Springer Nature B.V
• Subjects: Applied Ecology; Biodiversity; Biological diversity conservation; Biomedical and Life Sciences; Climate change; Community & Population Ecology; Drought; Droughts; Ecology; Elevation; Euptelea pleiospermum; Global temperature changes; Growth; Herbivores; Leaves; Life Sciences; Mountains; Phenotypic plasticity; Photosynthesis; Plant Ecology; Plant species; Plants; Plastic properties; Plasticity; Precipitation; Precipitation (Meteorology); Seedlings; Seeds; Species; Terrestial Ecology; Trees; Variation; Phenotypic plasticity; Climate change; Precipitation manipulation; Elevation gradient; Local adaptation; Reciprocal transplant
• ISSN: 1385-0237; 1573-5052
• DOI: 10.1007/s11258-021-01178-6

Improving the accuracy of predictions regarding how plants respond to climate change is crucial to protecting biodiversity. However, little is known about the effects of seed source and elevation on the response of mountain plant species to reductions in precipitation. Here, we collected seeds of a tree species ( Euptelea pleiospermum ) from three seed sources and carried out a two-growing-season reciprocal transplant experiment with precipitation manipulation at three sites along an elevation gradient in the Shennongjia Mountains, central China. Variations in whole-plant traits, leaf traits, and root traits were investigated. We found that most plant traits of E. pleiospermum seedlings were affected by reductions in precipitation, and responses varied among different elevations and seed sources. Whole-plant traits, root biomass, and leaf traits related to photosynthesis capacity decreased under reduced precipitation treatments at mid and high elevation sites. Thus, climate change induced drought will likely have a negative influence on seedling growth at mid and high elevation regions. In addition, a home-site advantage in whole-plant traits and root traits was observed. However, the responses of leaf traits in most cases were not affected by seed source because of higher phenotypic plasticity. Our results suggested that both local adaptation and phenotypic plasticity were important in seedling growth responses to reduced precipitation. We also highlight the importance of taking intraspecific variation into account when studying the response of plants to changes in climate.