Abstract
The concurrent effect of elevated CO(2) (eCO(2)) concentrations and arbuscular mycorrhizal fungi (AMF) on plant growth, carbon (C), nitrogen (N), phosphorus (P) and potassium (K) accumulations in plant and soil is largely unknown. To understand the mechanisms of eCO(2) and mycorrhization on wheat (Triticum aestivum) performance and soil fertility, wheat seedlings were grown under four different CO(2) environments for 12 weeks, including (1) ambient CO(2) (ACO(2), 410/460 ppm, daytime/nighttime), (2) sole daytime eCO(2) (DeCO(2), 550/460 ppm), (3) sole nighttime eCO(2) (NeCO(2), 410/610 ppm), and (4) dual or continuous daytime/nighttime eCO(2) ((D + N)eCO(2), 550/610 ppm), and with or without AMF (Funneliformis mosseae) colonization. DeCO(2), NeCO(2) and (D + N)eCO(2) generally significantly increased shoot and root biomass, plant C, N, P and K accumulation, soil invertase and urease activity, but decreased shoot and root N, P and K concentrations, and soil available N, P and K. Compared with non-AMF, AMF effects on above-mentioned characteristics were significantly positive under ACO(2), DeCO(2) and (D + N)eCO(2), but negative on plant biomass, C, N, P and K accumulation under NeCO(2). Overall, AMF colonization alleviated soil nutrient constraints on plant responses to DeCO(2), while NeCO(2) decreased AMF's beneficial effects on plants. These results demonstrated that an integration of AMF's benefits to plants under factual field DeCO(2) and/or NeCO(2) will be critical for managing the long-term consequence of future CO(2) rising on global cropping systems.