Responses of plant species with different genome size to water and nitrogen addition in Inner Mongolia Grassland, China

doi:10.13287/j.1001-9332.201908.018

Abstract

Abstract: Plant genome size (GS) varies greatly over 2400-fold in angiosperms. Genome sizes are closely related to plant traits from cellular to individual level, which would have far-reaching ecolo-gical implications. Genome size may shape the interspecific responses of plants to changes of resource availability in Inner Mongolia grassland which is co-limited by water and nitrogen availabi-lity. We tested the role of genome size in structuring plant community composition after single and combined water (W) amd nitrogen (N) addition in a typical grassland of Inner Mongolia. Plant genome sizes were estimated by flow cytometry. We found that the response of plant aboveground net primary production (ANPP) to change in water availability was significantly affected by genome size. Water and NW addition significantly increased ANPP of small GS plants, instead of large GS species. Nitrogen addition had no effects on ANPP of both small and large GS plants. We found no effects of all the treatments on plant species richness. Results showed that GS modulated the response of grassland plant species to changes in water rather than nitrogen availability in Inner Mongolia. Since GS is a relatively constant trait with substantial interspecific variation, the application of GS in ecological studies would be of great significance to better understanding of ecosystem structure and function under global change.

ZHAO Fang-yuan, WEI Cun-zheng, LYU Xiao-tao, HAN Xing-guo. Responses of plant species with different genome size to water and nitrogen addition in Inner Mongolia Grassland, China[J]. Chinese Journal of Applied Ecology, 2019, 30(8): 2675-2681.

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