4.1 Effect of Exogenous Ca2+ on Yield and Grain Nutritional Quality of Rice under SAR
The nutritional quality of rice is mainly determined by the protein content and amino acid content, especially essential amino acid content (Sarkadi 2019). Proteins can be divided into albumin, globulin, prolamin, and glutelin, of which glutelin is rich in essential amino acids and is a high-quality protein (Guo et al. 2018). In our experiments, SAR1(pH 4.5) treatment did not affect 100-seed weight, seed setting rate, and grain number per panicle in rice, while decreased the contents of total amino acids and essential amino acids. SAR2(pH3.0) treatment decreased the yield and nutritional quality of rice grains, including total amino acids, essential amino acids, total protein, and glutelin content. This indicates that SAR1(pH 4.5) declined the nutritional quality of rice grains, although it did not affect the yield of rice. SAR2(pH 3.0) caused greater damage to the yield and nutritional quality of rice. Exogenous Ca2+ increased the 100-seed weight of rice under SAR1(pH 4.5) treatment, even higher than the control level, and effectively alleviated the decline in total amino acids and essential amino acids. In the SAR2(pH 3.0) + Ca2+ treatment, exogenous Ca2+ alleviated decreased yield and the total content of rice protein, as well as total amino acids and essential amino acids content. However, alleviating the effect of exogenous Ca2+ on total amino acids and essential amino acid contents were limited in the SAR2(pH 3.0) + Ca2+ treatment. This shows that exogenous Ca2+ can effectively guarantee the yield under SAR(pH 4.5/3.0), but the regulatory effect on the nutritional quality of rice was limited by the intensity of acid rain. As the important nutritional quality of rice (Mirtaleb et al. 2021), essential amino acids are essential for a healthy human diet (Borack &Volpi 2016, Mereu 1967). The addition of exogenous Ca2+ alleviated the decrease of essential amino acids caused by SAR (pH 4.5/3.0), which may help to alleviate the lack of nutrient intake caused by AR and avoid the occurrence of “hidden hunger”.
4.2 Effect of Exogenous Ca 2+ on Growth and Total Nitrogen Content of Rice at Different Growth Stages under SAR
The yield and quality of rice are the results of long-term plant growth and development; the sensitivities of different growth stages to environmental changes are different. In addition, nitrogen is an essential macronutrient for the growth and production of nitrogen-containing organic compounds in crops (Han et al. 2020). Therefore, the level of nitrogen in crops has a decisive impact on the productivity and quality of crops (Zhou et al. 2021). Our results show that SAR1(pH 4.5) treatment had no effect on the growth of rice at all three growth stages and the total nitrogen content in rice at the booting stage and maturity stages, whereas it increased the total nitrogen content in rice at the seedling stage. However, SAR2(pH 3.0) significantly reduced the growth and total nitrogen content of rice at the seedling and booting stages. This indicates that the growth of rice at the seedling and booting stages was more sensitive to SAR than it was at the maturity stage. It was consistent with other studies that the activity of Mg2+-ATPase in the rice chloroplast was more sensitive to the SAR treatment at the seedling and booting stages than at the maturity stage (Zhang et al. 2018). This may be related to the stronger defense mechanism of rice at the maturity stage. Combined with no significant effect on the rice yield and a decrease in the total amino acids and essential amino acids contents of rice under SAR1(pH 4.5) stress, we found that the maintenance of total nitrogen level in rice under SAR1(pH 4.5) stress was beneficial for keeping the final yield of rice but cannot maintain the nutritional quality. It may be because SAR1(pH 4.5) did not inhibit nitrogen absorption but affected the utilization process, which contributed more to forming amino acids. Similar to our result, it has been found that earthworm casts improve amino acid contents in rice, which is related to amino acid metabolism, rather than changes of total nitrogen content in grains (Huang et al. 2018). Combining with the significant decrease in yield and contents of total amino acids, essential amino acids, and total protein in of rice under SAR2(pH 3.0), it has also been proved again that the decrease in total nitrogen level in in rice at different growth stages was one of the reasons for the decrease in the productivity and quality of rice. Moreover, a positive relationship between the total nitrogen content and the yield of rice exposed to SAR at each growth stage was observed in our experiment. In the SAR1(pH 4.5) + Ca2+ treatment, the growth and total nitrogen content of rice at the seedling and booting stages were higher than the control. In the SAR2(pH 3.0) + Ca2+ treatment, the growth increased to the control level, the total nitrogen content was still lower than the control at the seedling stage. In contrast, growth was lower than the control, and total nitrogen content increased to the control at booting stage. This shows that exogenous Ca2+ had the best regulatory effect on the growth at the seedlings stage under SAR. This phenomenon was also found in our previous research about soybeans (Li &Liang, 2019). Combined with yield and nutritional quality in the SAR(pH 4.5/3.0) + Ca2+ treatment, we found exogenous Ca2+ alleviated the decrease of yield and the decline of amino acids by promoting the growth and total nitrogen content at the seedling and booting stages. The regulatory effect of Ca2+ may depend on the absorption and utilization of nitrogen.
4.3 Effect of Exogenous Ca 2+ on Activities and Genes Expression of Key Enzymes in Nitrogen Assimilation in Rice Leaves under SAR
According to a previous analysis on growth and total nitrogen content in rice, we found the regulating effect of exogenous Ca2+ on rice growth at the seeding stage was the strongest among the three growth stages. Hence, we selected rice at the seedling stage to explore the effect of exogenous Ca2+ on the nitrogen assimilation process in which the inorganic nitrogen is converted into organic nitrogen under SAR. NR is the rate-limiting enzyme for assimilation of NO3− (Andrews &Raven 2022). GS/GOGAT is in charge of assimilation of NH4+, while GS activity is more abundant in plants, and GOGAT activity is the key to affecting the GS/GOGAT cycle (Lee et al. 2020). GS/GOGAT is divided into cytoplasmic GS1 and cytoplasmic NADH-GOGAT, responsible for assimilating NH4+ absorbed from soil to glutamate, and plastid GS2 and Fd-GOGAT responsible for assimilating NH4+ produced by photorespiration (Gayatri et al. 2021, Masclaux-Daubresse et al. 2006). GDH is another way to assimilate NH4+ (Liu et al. 2016). In our experiments, SAR1(pH 4.5) treatment increased expressions of OsNR1 and OsNR2 as well as the activity of NR. In contrast, it did not affect expressions of three genes encoding GS and the activity of GS. However, SAR2(pH 3.0) decreased expressions of OsNR1 and OsNR2 as well as the activity of NR, increased expressions of three genes encoding GS, and the activity of GS. Both in the SAR(pH 4.5/3.0) treatment, the expressions of OsNADH-GOGAT1, OsNADH-GOGAT2, and the activity of GOGAT decreased, and the expressions of OsGDH1, OsGDH4, and the activity of GDH increased, moreover the activity of GOGAT under SAR2(pH 3.0) treatment was lower than under SAR1(pH 4.5) treatment. This shows that SAR2(pH 3.0) treatment caused more damage to the GS/GOGAT cycle to reduced assimilation of NH4+ and restricted the assimilation and utilization of NO3− by inhibiting the activity of NR, resulting in a greater reduction in the efficiency of nitrogen assimilation than that of SAR1(pH 4.5). This may be one of the reasons for a more dramatic reduction in nutritional quality under SAR2(pH 3.0). It was consistent with other studies that the activity of GOGAT is a key factor for the efficiency of the GS/GOGAT cycle (Lee et al. 2020). Moreover, we found that the increase in activity of GS led to a decrease in the nutritional quality of rice. However, it was different from other studies in that the increased activity of GS during the filling stage was found to improve nitrogen metabolism efficiency and promote the synthesis of amino acids and proteins (Zhengxun et al. 2007). It was also found that nanomaterials improve the activity of GS in plants, promoting the synthesis of nitrogen assimilation products (Hu et al. 2021). This difference in results may be related to different growth stages and the responses of species to stress. Similar to our result, it has been found that high-temperature stress increased the activity of GOGAT and reduced the activity of GS, and grain protein content increased (Liang et al. 2011). As the substrate of GDH, the increased NH4+ content may stimulate the activity of GDH (Wei et al. 2021). At the same time, the increase in the activity of GDH may be the mode of action for plants to adapt to SAR(pH 4.5/3.0), which could compensate for the inhibition of GS/GOGAT caused by SAR(pH 4.5/3.0) to a certain extent and alleviate the negative effect of SAR on the efficiency of nitrogen assimilation. The addition of exogenous Ca2+ can maintain the higher expression levels of OsNR1 and OsNR2 and ensure the activity of NR under SAR(pH 4.5/3.0). Moreover, exogenous Ca2+ increased the expression of OsNADH-GOGAT1 and OsNADH-GOGAT2 to maintain the activity of GOGAT to the control level under SAR and increased the expression of OsGDH1 and OsGDH4 to increase the activity of GDH under SAR (pH 4.5/3.0). But under SAR2(pH 3.0) treatment, the expression of OsGS1;1, OsGS1;2, and OsGS1;3 and the activity of GS was still higher than the control. These indicated that exogenous Ca2+ was beneficial to the activity of NR under SAR and could adjust the balance of the GS/GOGAT cycle and increase the activity of GDH. However, exogenous Ca2+ could not effectively reduce the activity of GS to the control level under SAR2(pH 3.0), resulting in lower nitrogen assimilation efficiency than in control. Combined with Ca2+ alleviated the decrease of total amino acids, essential amino acids, and protein contents limited by the intensity of SAR2(pH 3.0), we can speculate that exogenous Ca2+eliminate the disruption of GS/GOGAT balance for maintaining the nutritional quality of rice under SAR. Under other abiotic stresses, the regulatory effects of exogenous Ca2+ on the activities of NR, GOGAT, and GDH were also reported (Liang et al. 2011, Su et al. 2016). Therefore, when the acid rain issue cannot be addressed from the source, exogenous Ca2+ could be an effective way to control the yield and mitigate the reduction in quality. It will be instructive to explore the effect of exogenous Ca2+ on yield and nutritional quality of the crop in field experiments in the future.