Phytochemical diversity plays vital roles in determining plant adaptation and fitness and ecosystem functions and services. However, phytochemicals and their ecological adaptations are long ignored. Fine (or absorptive) roots, microorganisms, and soil form the complex interface known as the rhizosphere. However, the variation of fine root chemistry along large-scale environmental gradients is still poorly understood.
In a study published in Science of the Total Environment, researchers from Xishuangbanna Tropical Botanical Garden (XTBG) studied the phytochemical diversity and its adaptation to abiotic and biotic stresses along different climatic gradients. By delving into the chemical constituents in fine roots, they sought to reveal how these chemical constituents help plants cope with various environmental stresses.
The researchers aimed to explore the trends of complexity of phytochemical composition (e.g., alpha diversity) and the variation in composition (e.g.,beta diversity or endemism) and their relationships with microorganisms along environmental gradients. They measured the untargeted metabolomics of fine roots and the rhizosphere microbiome of 315 tree species along a macro-climatic gradient spanning tropical, subtropical, and subalpine regions.
The results showed that the chemical diversity of subalpine tree species was higher than that of tropical tree species, but the variation in chemical diversity was smaller, which is conducive to adapting to higher abiotic stress. Tropical tree species had higher variation in chemical diversity and chemical endemism, which is conducive to species coexistence and adaptation to complex biological stress.
In addition, there was extensive chemo-ecological niche differentiation among closely related tree species in all climate zones, and fine root chemical diversity was weakly influenced by phylogeny and mainly regulated by abiotic and biotic stresses.
"Our study is a positive exploration into phytochemical diversity patterns and their interactions with rhizosphere microorganisms along climatic gradients, which highlights the importance of future phytochemical research," said YANG Jie of XTBG.
Contact
YANG Jie Ph.D Principal Investigator
Key Laboratory of Tropical Forest Ecology, Xishuangbanna Tropical Botanical Garden, Chinese Academy of Sciences, Mengla, Yunnan 666303, China
E-mail:yangjie@xtbg.org.cn
Published: 31 March 2024