Nitrogen management under increased atmospheric CO2 concentration in cucumber (Cucumis sativus L.): ameliorating environmental impacts of fertilization.

In the last years, the atmospheric CO2 concentration has increased significantly, and this increase can cause changes in various physiological and biochemical processes of plants. However, the response of plants to elevated CO2 concentration (e[CO2]) will be different depending on the nitrogen form available and the plant species. Therefore, hydroponic trials on cucumber plants, with two CO2 concentrations (400 and 1000 ppm) and two nitrogen sources (NO3-/NH4+; 100/0 and 90/10), were conducted. Physiological parameters-such as gas exchange, GS, GOGAT and GDH activities, cation composition, soluble sugar and starch content- were measured. The results showed that when plants were grown with NH4+ and e[CO2], parameters such as photosynthesis rate (ACO2), instantaneous water use efficiency (WUEi), the content of NH4+, Ca2+ and Mg2+, and the concentration of starch, were higher than in control plants (irrigated with nitrate as sole nitrogen source and ambient CO2 concentration (a[CO2])). Furthermore, an improvement in N assimilation was observed when the GS/GOGAT pathway was enhanced under these conditions (NH4+ and e[CO2]). Thus, our results contribute to the reduction of the negative environmental impacts of the use of nitrogen fertilizers on this crop, both by reducing nitrogen leakage (eutrophication) and greenhouse gas emissions.

Introduction

The atmospheric carbon dioxide (CO2) concentration is increasing at a faster rate and is projected to reach nearly 1000 µmol mol−1 by the end of 2100[1]. Since the current CO2 concentration (413 ppm) (NOAA 2020) is still a limiting factor for plant growth, and the optimal concentration is considered between 800–1000 ppm[2], this increase in CO2 concentration could favor the photosynthetic rate and stimulate plant growth and development. However, the response of plants to e[CO2] varies depending on other environmental factors[3], such as the nitrogen form (NO3− or NH4+) available[4]. Authors such as Rubio-Asensio and Bloom[4] reported that plants irrigated with NH4+ showed a more positive response to e[CO2], than those irrigated with NO3−, as e[CO2] inhibited the assimilation of NO3− in the shoots of C3 plants.

Both N forms (NO3− and NH4+) share the same metabolic pathway, called as glutamate pathway, in which enzymes such as glutamate synthase (GOGAT) and glutamine synthase (GS) are involved; hence, this pathway is also identified as the GS/GOGAT cycle. GS is responsible for assimilating NH4+ as amino acids (glutamine), and GOGAT transforms this glutamine to glutamate[5]. Furthermore, glutamate dehydrogenase (GDH) catalyzes the transformation of α-ketoglutaric acid and NH3 into glutamate through the glutamate pathway. Consequently, GOGAT, GS and GDH are considered the principal enzymes of N metabolism in higher plants[5]. As the response of plants to an increase in CO2 concentration will be different depending on the source of N supplied and the specie considered, it will be very important to better understand the plant’s preference for different N forms under e[CO2], as this knowledge can be used to guide farmers towards the more efficient use of fertilizers. Therefore, because of the high energy cost of production of N fertilizers, and the environmental impact of the nitrate that is not taken up by plants[6], growers must reduce the N losses and pollution associated to fertilization by using the appropriate ratio of inorganic nitrate under future climate scenarios. The nitrogen fertilization of crops is one of main causes of environmental contamination worldwide, through nitrate leaching and as a net contributor to greenhouse gas emission[7,8]. Cucumber (Cucumis sativus L.) is one of the most-cultivated vegetables in the world due to its economic and nutritional benefits[5,9]. However, although many cucumber growth parameters have been studied, such as photosynthesis[10], nitrogen metabolism[11], fruit quality[12], or water use efficiency[13], the combined effects of CO2 and different N forms (NO3− and NH4+) have not been studied. Therefore, this study is the first attempt at understanding how N forms and e[CO2] interact in cucumber plants in a climate change scenario. To stimulate the physiological mechanisms affected by these two factors (N forms and e[CO2]), cucumber plant seedlings were exposed to different N inputs and e[CO2] in a controlled environment. The responses of plants were assessed by measuring the net CO2 assimilation, internal CO2 concentration, instantaneous water use efficiency, cation concentration, nitrogen-metabolizing enzymes, starch, and soluble sugars.

Results

Gas exchange

The data showed that the treatment with NH4+ (90/10) increased the ACO2 at both CO2 concentrations (Fig. 1A). The ACO2 throughout the experiment slightly decreased at both CO2 concentrations. Curiously, the decrease was more pronounced when the plants were irrigated with the 100/0 treatment at both CO2 concentrations, but mainly under e[CO2]. This decrease was from 21.2 µmoles CO2 m−2 s−1 to 5.2 µmoles CO2 m−2 s−1 in plants irrigated with 100/0 under e[CO2]. In contrast, the decrease in plants irrigated with the 100/0 treatment under a[CO2] was only from 8.7 µmoles CO2 m−2 s−1 on 7 DAT, to 2.1 µmoles CO2 m−2 s−1 on 29 DAT. On the other hand, exposure to e[CO2] markedly increased ACO2 in both N treatments (Fig. 1A). Similarly, the Ci increased by CO2 enrichment (Fig. 1B). However, this parameter obtained higher values in plants irrigated with the 100/0 treatment at both CO2 concentrations, on 18 DAT and 29 DAT. During the rest of the experiment, no significant differences were observed between the irrigation treatments.

Figure 1

Effect of N forms (100% NO3− and 90% NO3−/10% NH4+ combined) under an eCO2 on cucumber plants: (A) net photosynthesis rate (ACO2); (B) internal CO2 concentration (Ci); and (C) instantaneous water-use efficiency (WUEi). Data are means ± SE of six plants. * denotes significant differences (P < 0.05) between plants in different CO2 treatments, with the same nitrogen treatment; X denotes significant differences (P < 0.05) between nitrogen treatments for the same CO2 treatment.

With regard to the WUEi, the levels were higher in plants irrigated with the 90/10 treatment under e[CO2] than under a[CO2] (Fig. 1C). The 90/10 treatment also caused a slight increase of this parameter with respect to plants irrigated with NO3- as the sole N source, but with differences significant only on 29 DAT at a[CO2] (56%) and on 18 and 29 DAT at e[CO2] (49% and 68%, respectively).

Mineral concentration

The mineral composition was affected by CO2 and N form (Table 1). The leaf NH4+ and Ca2+ concentrations were higher at e[CO2] than at a[CO2] in both N treatments, with the only exception found in the NH4+ concentration of plants irrigated with the 100/0 treatment, which was reduced (33%). Also, the addition of NH4+ to the irrigation solution caused an increase in the concentration of Ca2+ and Mg2+ at both CO2 concentrations. But in the case of NH4+ concentration, this increase was only observed under e[CO2] (15%). In contrast, leaf K+ concentration was not affected by neither CO2 nor N form (Table 1).

Table 1

Effect of N forms (100% NO3− and 90% NO3−/10% NH4+ combined) under an elevated CO2 concentration on the cation composition of leaves of cucumber.

[CO2]	Nitrogen form	NH4+ (mmol Kg−1)	Ca2+ (mmol Kg−1)	K+ (mmol Kg−1)	Mg2+ (mmol Kg−1)
400	100/0	5.68 ± 0.08b	6.21 ± 0.38d	118.5 ± 9.8a	19.39 ± 2.46c
	90/10	5.92 ± 0.04b	13.70 ± 0.40b	120.4 ± 4.4a	32.44 ± 2.38ab
1000	100/0	3.83 ± 0.30c	9.41 ± 1.13c	133.2 ± 5.1a	25.53 ± 3.47bc
	90/10	7.00 ± 0.27a	17.98 ± 0.61a	123.7 ± 2.9a	34.26 ± 1.63a
ANOVAb
CO2		ns	***	ns	ns
NFc		***	***	ns	***
CO2 × NF		***	ns	ns	ns

aDifferent letters within a column indicate significant (P ≤ 0.05) differences between treatments.

bAnalysis of variance: ns, not significant.

cNitrogen form.

*P ≤ 0.05.

**P ≤ 0.005.

***P ≤ 0.001.

Soluble sugars and starch

The soluble sugars and starch contents were affected by N form (Fig. 2A and B). The sugar content increased mainly under the 90/10 treatment at a[CO2] (from 15 g Kg−1 FW to 21 g Kg−1 FW), while at e[CO2], this increase was not significant (Fig. 2A). The starch content rose under both CO2 concentrations by the combined application of NO3- and NH4+ (from 7 g Kg−1 DW to 13 g Kg−1 DW under a[CO2] and from 15 g Kg−1 DW to 23 g Kg−1 DW under e[CO2]) (Fig. 2B). On the other hand, the e[CO2] provoked an increase in the starch content, from 7 g Kg−1 DW to 15 g Kg−1 DW in plants irrigated with 100/0 and from 13 g Kg−1 DW to 23 g Kg−1 DW, in plants irrigated with 90/10 (Fig. 2B).

Figure 2

Effect of N forms (100% NO3− and 90% NO3−/10% NH4+ combined) under an elevated CO2 concentration on leaves of cucumber: (A) soluble sugars; and (B) starch. Data are means ± SE of six plants. Different letters indicate significant (P ≤ 0.05) differences between treatments.

Nitrogen-metabolizing enzymes

The behaviors of these 3 enzymes (GS, GOGAT, and GDH) against the N source were dependent on the environmental conditions in which the plants were grown (Fig. 3). Plants grown under a[CO2] and irrigated with the 90/10 treatment, suffered a significant reduction in GOGAT activity (62%), and an increase in GDH activity (43%) (Fig. 3B and C). On the contrary, when plants were grown under e[CO2], the treatment with a mixture of N forms caused a slight increase in GS activity (19%) and a reduction in GDH activity (51%) (Fig. 3A and C).

Figure 3

Effect of N forms (100% NO3− and 90% NO3−/10% NH4+ combined) under an elevated CO2 concentration on leaves of cucumber: (A) glutamine synthetase activity (GS); (B) glutamate synthase activity (GOGAT); and (C) glutamate dehydrogenase activity (GDH). Data are means ± SE of six plants. Data are means ± SE of six plants. Different letters indicate significant (P ≤ 0.05) differences between treatments.

Discussion

The effects on plants of the N form(s) used for irrigation depend on several factors such as environmental conditions (temperature, light intensity, atmospheric CO2 concentration, N concentration, average pH, and K supply), the proportions in which they are supplied (NO3−/NH4+), the plant species, and even on the variety. Therefore, studies carried out by various authors about the use of different N sources have shown different results[14-16].

Our data showed that the combination of different N forms (NO3−/NH4+) and e[CO2] provoked a significant increase in the gas exchange parameters. In our previous studies, we observed a similar behavior in pepper plants exposed to similar conditions[17,18]. Something similar was reported by authors such as Cruz et al.[19] and Bloom et al.[20], who observed that plants (cassava and wheat plants, respectively) exposed to e[CO2] and NH4+-based nutrition showed a greater stimulation of photosynthesis than those irrigated with NO3− alone. These results indicates that adding NH4+ to the nutrient solution increases the photosynthetic capacity of plants grown under e[CO2]. This could be due to the energy cost involved in assimilating NO3− versus NH4+: the reduction of NO3− to NH4+ implies the consumption of approximately 10 ATP molecules, while in the conversion of NH4+ to glutamate, the consumption is reduced to only approximately 2 ATP[4]. Therefore, plants fed with NO3- as the N source must efficiently divide and distribute the reducer generated in photosynthesis to cover the additional assimilation demands of NO3− assimilation[4]. In the case of WUEi, Cruz et al.[19] just as in the present study, observed the highest WUEi values under e[CO2] and NH4+ nutrition. However, authors such as Torralbo et al.[21] found the opposite effect on photosynthesis in durum wheat, but a similar behavior in WUEi.

Under e[CO2] conditions, the foliar NH4+ concentration results were different depending on the N source supplied to the roots. This is in agreement with the results found by Rubio-Asensio and Bloom[4], who observed that CO2 enrichment inhibited NO3− assimilation in plants grown with NO3- nutrition, but did not affect those grown with NH4+ nutrition. This would explain the lower NH4+ concentration observed in plants treated with 100/0 under e[CO2]. In these plants, as NH4+ is not provided in the nutrient solution, the foliar NH4+ concentration observed came from the assimilation of NO3-, which changes from NO3- to nitrite (NO2−) and next, to NH4+[22]. This suggests that futures increase in atmospheric CO2 concentrations may compromise the productivity of some plants if we not change the fertilization strategies.

Curiously, other nutrients such as Ca2+ and Mg2+ increased in concentration with the 90/10 treatments at both CO2 concentrations. However, authors such Boschiero et al.[23] reported contrary effects in sugarcane plants, which showed a reduction in the leaf nutrients with the increase in the NO3−/NH4+ ratio. The fact that the 90/10 treatment produced an increase in the foliar Ca2+ concentration, despite the antagonistic effect that exists between these two elements[18], could indicate that at a low concentration of NH4+, this antagonistic effect does not occur for cucumber plants. A significant positive correlation was found between foliar Ca2+ content and WUEi (R2 = 0.6708, data no shown). It is known that Ca2+ plays an important role in multiple photosynthetic pathways, it can both interfere with gas exchange by regulating stomatal movement, and can directly or indirectly regulate the activity of enzymes involved in photosynthesis. Authors such as Brestic et al.[24] observed that Ca2+ improved Rubisco activity, and the higher activity seemed to be associated with a higher photosynthetic rate.

Concerning the values of K+, the finding that no differences were observed in foliar K+ concentration between treatments, could be another indication that the NH4+ concentration provided was not toxic for cucumber plants, as K+ deficiencies have been observed in toxic concentrations due to competition in absorption between K+ and NH4+[23]. Regarding the CO2 effect on the foliar nutrient content, curiously the cucumber plants responded in the opposite manner to the pepper plants under similar growth conditions[18], which reinforces the idea of significant species-dependent-response.

Authors such as Teng et al.[25], Markelz et al.[26] and Rubio-Asensio and Bloom[4], observed that e[CO2] provoked an increase in the photosynthesis rate of Arabidopsis, which was related with a rise in starch and the total non-structural carbohydrates. In our experiment, something similar was observed with the starch, but no changes were observed in the soluble sugars. This could be due to the increase in starch or other carbohydrates storage polymers being greater than the increase in sugar concentrations, but the extent of the changes vary considerably between species[27]. Also, it is known that the N supplied can have an influence on the accumulation of starch and soluble sugars under e[CO2][27]. In our results, a relationship was once more observed between the increase caused by NH4+ in photosynthesis and the higher leaf starch content observed.

Regarding the behavior observed in the metabolic enzymes measured, our data showed that the treatment with NH4+ under an atmosphere enriched with CO2 provoked an increase in the GS activity and a reduction in the GDH activity, which indicate that the combination of the 90/10 treatment and e[CO2] may promote the GS/GOGAT pathway of N metabolism. This increase in the GS/GOGAT pathway could be partly responsible for a higher photosynthesis rate, as it would favor N assimilation[5]. On the contrary, the treatment with NH4+ under a[CO2] conditions resulted in a higher GDH activity and lesser GOGAT activity than the 100/0 treatment. These results suggest that GDH played a decisive role when the GS/GOGAT pathway was restricted. Authors such as Ma et al.[5] and Torralbo et al.[21] consider that the role of GDH in N metabolism becomes more important when plants are subjected to stress, specifically NH4+ toxicity. GDH removes excess NH4+ and thus reduces its toxic effect.

To achieve a better understanding of the trends and relationships among all the studied parameters in relation to the N supply, a PCA was applied to the results. The results of the PCA are presented in Table 2 and presents a clearer distinction of the effects of nitrogen form and CO2 concentration. The first two principal components (PCs) accounted for 71.38% of the total variance, attributing 42.26% to PC1 and 29.13% to PC2 (Table 2). Most of the variables examined were positively correlated with PC1, and only two variables were negative correlated with PC1. The variables with the highest positive correlation coefficients were Ca2+ (0.925) and WUEi (0.877), and others with a high correlation were soluble sugars (0.685), Mg2+ (0.559), ACO2 (0.772) and NH4+ (0.780). PC1 was negatively correlated with GDH (− 0.402) and K+ (0.762), allowed for a clear separation of plants irrigated with NH4+ in the nutrient solution, and suggested that plant growth with the 90/10 treatment was characterized by a higher Ca2+ (Table 1), and higher WUEi (Fig. 1C). PC2 was positively correlated with GS (0.871), starch (0.690) and Ci (0.944), and was negatively correlated with GOGAT activity (− 0.669). The PC2 clearly separated plants grown under e[CO2], characterized by a higher GS activity (Fig. 2A), and higher Ci (Fig. 1B).

Table 2

Eigenvalues, proportion of variation, accumulated proportion of variation, and eigenvectors associated with the two axes of the PCA.

Principal components	1	2
Eigenvalues	5.493	3.786
Proportion of variation	42.256	29.125
Accumulated proportion of variation	42.256	71.381

The data obtained in this experiment highlight the complexity and importance of using the correct type of nitrogen fertilization in the plant irrigation solution to face the environmental changes that are currently taking place (increase in CO2). We have demonstrated that physiological parameters such as the ACO2 and WUEi can be improved in cucumber plants with the addition of NH4+ in low amounts in the nutrient solution under a CO2-enriched atmosphere. Also, under these conditions (NH4+ and e[CO2]), the GS/GOGAT cycle is promoted, which favors the assimilation of N, and the increase in the concentrations of other nutrients such as NH4+, Ca2+, and Mg2+, and the starch content.

Consequently, this study reveals the strong interaction between the N form supplied and e[CO2], in terms of N assimilation, and therefore, of a better performance of the photosynthetic apparatus.

Material and methods

Plant material, growth conditions and treatments

Cucumber (Cucumis sativus L.), cv. Ashley seeds (Semillas Batlle, S.A., Barcelona, Spain) were germinated on a mixture of peat and perlite (3:1). Seedlings with two true leaves stages were selected for uniformity after the 12 days, and transplanted to 8-L black containers filled with coconut coir fiber (Pelemix, Alhama de Murcia, Murcia, Spain). Each container was rinsed with 1 L of water after transplanting. Irrigation was supplied by self-compensating drippers (2 lh−1), and fresh nutrient solution was applied with a minimum of 35% drainage.

The plant growth responses to different nitrogen forms and e[CO2] were determined in an experiment carried out in a climate chamber designed by our department specifically for plant research proposals[28], with fully-controlled environmental conditions: 30% relative humidity, 16/8 h day/night photoperiod, an air temperature ranging from 28 to 20 °C, and a photosynthetically-active radiation (PAR) of 250 µmol m−2 s−1 provided by a combination of fluorescent lamps (TL-D Master reflex 830 and 840, Koninklijke Philips Electronics N.V., the Netherlands) and high-pressure sodium lamps (Son-T Agro, Philips). During the first seven days after transplanting (7 DAT), the plants were irrigated with Hoagland’s solution (control), and then, the plants were irrigated with Hoagland’s solutions that differed in their NO3−/NH4+ ratios (in concentration percentages, 100/0 or 90/10) for twenty-two days.

The experiment lasted twenty-nine days and was carried out at standard CO2 (400 µmol mol−1 CO2) (a[CO2]), and elevated CO2 (1000 µmol mol−1 CO2) (e[CO2]) concentrations, with nine plants per treatment. Thus, four treatments were studied, corresponding to two nutrient solutions and two ambient CO2 concentrations.

Statistical analysis

Data were statistically analyzed using the SPSS 13.0 software package (IBM SPSS Statistics 25.0, Armonk, NY, USA), with an ANOVA and Duncan’s multiple range test (P ≤ 0.05) using the treatments as a statistical variable to determine significant differences between means.

The gas exchange measurements were performed just before starting the nitrogen treatments (7 DAT), and throughout the experiment (11, 18, 22, and 29 DAT). A CIRAS-2 (PP system, Amesbury, MA, USA) with a PLC6 (U) Automatic Universal Leaf Cuvette, was used to measure the net CO2 assimilation (ACO2), internal CO2 concentration (Ci) and instantaneous water-use efficiency (WUEi, ACO2/E). The measurements were conducted on the youngest fully-expanded leaf from each plant. The cuvette provided light (LED) with a photon flux of 1300 µmol m−2 s−1, 400 or 1000 µmol mol−1 CO2, 70% relative humidity, and a leaf temperature of 26 °C.

Ion concentrations

The NH4+, K+, Ca2+ and Mg2+ ions were extracted from ground leaf lyophilized (1 g) with bi-distilled water, and their concentrations were determined in an ion chromatograph (METROHM 861 Advanced Compact IC; METROHM 838 Advanced Sampler); the column used was a METROHM Metrosep C1 125/4.6 mm.

Starch and soluble sugars

Soluble sugars were extracted by incubating 30–40 mg of lyophilized leaf tissue twice in 5 mL of 60% ethanol, 30 min each time, at 35 °C. The extract was centrifuged at 3500×g for 10 min at 20 °C, and the two supernatants were combined. Chloroform (5 mL) was added and the mixture shaken before centrifugation at 2700×g for 10 min at 20 °C. The sample was diluted fourfold with absolute ethanol to produce an extract in 80% ethanol for the measurement of soluble sugars according to Buysse and Merckx[29]. The residual material from the extraction with 60% ethanol was hydrolyzed with 3% HCl for 3 h at 125 °C, and the soluble sugars released were measured as an estimate of the starch content[30].

Nitrogen-metabolizing enzymes extraction and assay

Fresh leaf tissue samples were frozen with liquid nitrogen and stored at − 20 °C until analysis. Between 0.5 g of plant tissue were pulverized under liquid nitrogen with a chilled pestle and mortar and then homogenized with 5 mL ice-cold enzyme extraction buffer containing 50 mM Tris–HCl, pH 8; 1 mM EDTA, 10 mM β-mercaptoethanol, 5 mM dithiothreitol (DTT), 10 mM MgSO2 7H2O, 6.6% of PVPP (polyvinylpolypyrrolidone), 1 mM Cysteine, and 0.5 mM phenylmethylsulfonyl (PMSF).

After centrifugation at 17,000×g at 4 °C for 20 min, the supernatant was collected and used for enzyme assays. The activity of NADH-GOGAT (EC 1.4.1.14.) and GDH (EC 1.4.1.2.) were assayed spectrophotometrically according to Groat and Vance[31] by monitoring the oxidation of NADH at 340 nm. The activity of glutamine synthetase (GS, EC 6.3.1.2) was assayed spectrophotometrically according to the modified method by Setién et al.[32], and the absorbance of γ-glutamyl monohydroxamate (γ-GHM) was measured at 540 nm.