The xylem of plant stem performs several important functions. Elucidating the coordination or trade-offs between xylem functions is critical for understanding plant ecological strategy and adaptation to different environments. However, it remains unclear how xylem cell tissues influence their functions among different growth forms.

In a study published in American Journal of Botany, researchers from the Xishuangbanna Tropical Botanical Garden (XTBG) of the Chinese Academy of Sciences investigated the variation and associations in stem xylem water transport, mechanical support, and storage functions between lianas and trees in three different ecosystems in southwest China.

The researchers measured 18 xylem functional traits related to water transport, mechanical support, and storage in 15 liana species and 16 tree species from three different sites, including a tropical rainforest, a hot and dry valley savanna, and a subtropical evergreen broadleaved forest in Yunnan Province, Southwest China.

They aimed to analyze differences in stem xylem functional traits between lianas and trees, identify key traits associated with these functions, and examine the relationships among water transport, mechanical support, and storage functions in both growth forms.

The results revealed distinct ecological strategies between lianas and trees, with liana species having greater hydraulic efficiency and tree species having greater mechanical strength. Variation in stem hydraulic and mechanical traits were certainly related to xylem structure, besides growth form and habitat, while variation in stem storage traits was mainly related to site (environment). Starch and soluble sugars appear to help lianas adapt to changing environmental conditions.

In lianas, there is a consistent trade-off between the water transport capacity and mechanical support by xylem, in contrast to trees where such trade-offs are less common or infrequent. In addition, the relationships between water transport and storage functions in both lianas and trees are complex and multifaceted.

"Our study addresses the existing gap in research on storage functions in different plant species accross different environments. It provides valuable insights into how plants adapt to environmental changes and the different ecological strategies used by lianas and by trees to balance the demands of hydraulic transport, mechanical support, and storage," said ZHANG Jiaolin of XTBG.