Effects of elevated CO2 concentration and nitrogen addition on foliar phosphorus fractions of Mikania micranatha and Chromolaena odorata under low phosphorus availability

Abstract Invasive plants rapidly spread in habitats with low soil phosphorus (P) availability and have triggered a sharp decline in the diversity of native species. However, no studies have explored how widespread invasive species acclimate to low soil P availability via changing foliar P fractions, especially under elevated atmospheric CO 2 concentrations ([CO 2 ]) and nitrogen (N) deposition. Here, an open‐top chamber experiment was conducted to explore the effect of nutrient addition and elevated [CO 2 ] on leaf traits and foliar functional P fractions (i.e., Pi, metabolite P, lipid P, nucleic acid P, and residual P) of two aggressive invasive species ( Mikania micranatha and Chromolaena odorata ). We found that foliar N/P ratios were more than 20, and P addition significantly increased plant biomass. Both results indicated P‐limited plant growth at our studied site. Elevated [CO 2 ], N and N + P addition greatly increased plant biomass, photosynthetic rates, and photosynthetic P‐use efficiency (PPUE) in invasive species, but PPUE decreased with increasing P addition. Nitrogen addition slightly decreased the concentration of leaf total P, decreased foliar residual P, but increased metabolite P concentrations in invasive species. Similar changes in foliar P fractions were found under N + P addition. Phosphorus addition increased foliar P concentrations, which was strongly correlated with an increase in metabolite P concentrations in invasive species. Elevated [CO 2 ] alleviated these effects and increased PPUE. The present results suggest that future elevated [CO 2 ] and N deposition allow the invasive species to acclimate to low soil P availability and support their successful invasion by greatly reducing P allocation to non‐metabolite foliar P fractions (i.e., nucleic acid P and residual P) to meet their demand of metabolite P for photosynthesis and exhibit a high PPUE.