Abstract

An increase in plant biomass under elevated CO2 (eCO2) is usually lower than expected. N-deficiency induced by eCO2 is often considered to be a reason for this. Several hypotheses explain the induced N-deficiency: (1) eCO2 inhibits nitrate assimilation, (2) eCO2 lowers nitrate acquisition due to reduced transpiration, or (3) eCO2 reduces plant N concentration with increased biomass. We tested them using C3 (wheat, rice, and potato) and C4 plants (guinea grass, and Amaranthus) grown in chambers at 400 (ambient CO2, aCO2) or 800 (eCO2) μL L−1 CO2. In most species, we could not confirm hypothesis (1) with the measurements of plant nitrate accumulation in each organ. The exception was rice showing a slight inhibition of nitrate assimilation at eCO2, but the biomass was similar between the nitrate and urea-fed plants. Contrary to hypothesis (2), eCO2 did not decrease plant nitrate acquisition despite reduced transpiration because of enhanced nitrate acquisition per unit transpiration in all species. Comparing to aCO2, eCO2 remarkably enhanced water-use efficiency, especially in C3 plants, decreasing water demand for CO2 acquisition. As our results supported hypothesis (3) without any exception, we then examined if lowered N concentration at eCO2 indeed limits the growth using C3 wheat and C4 guinea grass under various levels of nitrate-N supply. While eCO2 significantly increased relative growth rate (RGR) in wheat but not in guinea grass, each species increased RGR with higher N supply and then reached a maximum as no longer N was limited. To achieve the maximum RGR, wheat required a 1.3-fold N supply at eCO2 than aCO2 with 2.2-fold biomass. However, the N requirement by guinea grass was less affected by the eCO2 treatment. The results reveal that accelerated RGR by eCO2 could create a demand for more N, especially in the leaf sheath rather than the leaf blade in wheat, causing N-limitation unless the additional N was supplied. We concluded that eCO2 amplifies N-limitation due to accelerated growth rate rather than inhibited nitrate assimilation or acquisition. Our results suggest that plant growth under higher CO2 will become more dependent on N but less dependent on water to acquire both CO2 and N.

Highlights

  • 90% of plant dry matter consists of C and O (Epstein and Bloom, 2005), mainly derived from atmosphericCO2

  • The relative growth rate (RGR) was not affected by the form of N fertilizer in wheat, rice, potato, and guinea grass under elevated CO2 (eCO2) and under ambient CO2 concentration (aCO2) (Table 1) without any visible symptoms, implying that toxic effects of ammonia released from urea were not detectable

  • As the data in Experiment 1 indicated that CO2 enrichment did not necessarily inhibit nitrate assimilation and N acquisition but decreased the plant N concentration on a mass basis, we examined whether an increase in the N supply could improve plant growth while at the same time prevent N deficiency under CO2 enrichment

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Summary

Introduction

90% of plant dry matter consists of C and O (Epstein and Bloom, 2005), mainly derived from atmospheric. Higher atmospheric CO2 concentrations have the potential to increase plant biomass because (1) CO2 is the substrate for photosynthesis in plants, and (2) the photosynthetic rate is not yet saturated under the current ambient CO2 concentration (aCO2), in C3 plants (Lemonnier and Ainsworth, 2018). (eCO2) is almost always lower than expected (Kimball et al, 1993; Ainsworth and Long, 2005). It is frequently pointed out that the reason for this growth shortness is that plants under eCO2 suffer from N-deficiency. To fully realize the effects of CO2 fertilization, such eCO2-

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