Physiological and Proteomic Responses of the Tetraploid Robinia pseudoacacia L. to High CO2 Levels

The increase in atmospheric CO2 concentration is a significant factor in triggering global warming. CO2 is essential for plant photosynthesis, but excessive CO2 can negatively impact photosynthesis and its associated physiological and biochemical processes. The tetraploid Robinia pseudoacacia L., a superior and improved variety, exhibits high tolerance to abiotic stress. In this study, we investigated the physiological and proteomic response mechanisms of the tetraploid R. pseudoacacia under high CO2 treatment. The results of our physiological and biochemical analyses revealed that a 5% high concentration of CO2 hindered the growth and development of the tetraploid R. pseudoacacia and caused severe damage to the leaves. Additionally, it significantly reduced photosynthetic parameters such as Pn, Gs, Tr, and Ci, as well as respiration. The levels of chlorophyll (Chl a and b) and the fluorescent parameters of chlorophyll (Fm, Fv/Fm, qP, and ETR) also significantly decreased. Conversely, the levels of ROS (H2O2 and O2·−) were significantly increased, while the activities of antioxidant enzymes (SOD, CAT, GR, and APX) were significantly decreased. Furthermore, high CO2 induced stomatal closure by promoting the accumulation of ROS and NO in guard cells. Through a proteomic analysis, we identified a total of 1652 DAPs after high CO2 treatment. GO functional annotation revealed that these DAPs were mainly associated with redox activity, catalytic activity, and ion binding. KEGG analysis showed an enrichment of DAPs in metabolic pathways, secondary metabolite biosynthesis, amino acid biosynthesis, and photosynthetic pathways. Overall, our study provides valuable insights into the adaptation mechanisms of the tetraploid R. pseudoacacia to high CO2.


Introduction
CO 2 is a crucial substrate for plant photosynthesis.The levels of atmospheric CO 2 have a significant impact on plant growth, development, and biomass [1].Since the industrial era, atmospheric CO 2 concentrations have increased by more than 40%, and the current ambient CO 2 concentrations exceed 417 ppm [2].The rise in CO 2 concentration has resulted in significant alterations in global temperatures, intensifying the greenhouse effect and exposing plants to elevated CO 2 levels, higher temperatures, and drought.Consequently, this poses a considerable challenge to plant growth and reproduction.The impact of CO 2 enrichment on growth and yield for C3 plants can vary and may be influenced by species-specific factors [3].
Previous studies have consistently shown that higher levels of CO 2 have a significant impact on the physiological functioning of plants [4][5][6].On the one hand, elevated CO 2 directly affects plant photosynthesis.Increased atmospheric CO 2 concentrations lead to a higher number of leaves, longer branches, and greater biomass while also causing a decrease in stomatal density.Additionally, it can result in visible symptoms such as wilting and drooping leaves [3,7].According to previous studies, the net photosynthetic rate and water use efficiency (WUE) of A. marina and R. stylosa increased when exposed to a slight elevation in CO 2 concentration.These findings suggest that the promotion of photosynthesis was facilitated by the elevated CO 2 concentration [7].Furthermore, it has been observed that rising CO 2 concentrations contribute to an increase in phytoplankton growth rate and lipid productivity [8].Another study found that corn exhibits higher biomass and leaf area, as well as enhanced starch synthesis, when exposed to elevated CO 2 concentrations [9].The Rubisco content and light-saturated photosynthetic rate in plant leaves were observed to be significantly reduced in a high CO 2 environment [10].Similarly, when Pinus sylvestris was exposed to this environment for an extended period, both the stomatal conductance and total stomatal number showed a significant decrease [11].On the other hand, in Allium sativum L., the elevated CO 2 atmosphere had a contrasting effect, significantly enhancing the activity of pyruvate decarboxylase (PDC) and alcohol dehydrogenase (ADH).This, in turn, caused a substantial increase in the content of alcohols, aldehydes, and phenols, resulting in toxic effects [12].On the contrary, research has demonstrated that high CO 2 levels can also actually mitigate ozone-induced oxidative damage in wheat [8].Additionally, the impact of CO 2 concentrations varies depending on the plant species.For example, in the case of reticulated melons, low CO 2 has been found to increase both the initial and maximum photosynthetic efficiency.However, when exposed to high CO 2 , the maximum photosynthetic efficiency of reticulated melons actually declines [13].
On the other hand, previous studies have demonstrated that CO 2 -induced stomatal closure is dependent on Ca 2+ and that elevated CO 2 levels stimulate an increase in free Ca 2+ concentration in defense cells [14][15][16][17].Stomata, which are small pores on the leaf surface, play a crucial role in regulating the uptake of carbon dioxide for photosynthesis and the loss of water through transpiration [18].The movement of stomata is influenced by various environmental factors, including CO 2 concentration.Stomatal opening is promoted by low concentrations of CO 2 , while stomatal closure is induced by high concentrations of CO 2 .In the guard cells of Arabidopsis thaliana, the carbonic anhydrases βCA1 and βCA4 are involved in mediating CO 2 -controlled stomatal movement and development [19].Additionally, BIG proteins play a critical role in inhibiting stomatal opening and promoting stomatal closure in response to CO 2 [20].Reactive oxygen species (ROS) and nitric oxide (NO) are important signaling molecules that regulate stomatal movement in plants [21].It has been shown that CO 2 -mediated stomatal closure requires the generation of ROS, which has an important role in the regulation of stomatal aperture [22,23].NO plays a role in both abscisic acid (ABA)-and Ca 2+ -mediated stomatal closure and is located downstream of ROS, an important participant in the stomatal closure process [24,25].In A. thaliana, ROS are mainly produced by NADPH oxidase and peroxidase at the plasma membrane [26,27], while NO is mainly produced by nitrate reductase (NR) and NOA1 and induces stomatal closure [28].
Plant respiration is a significant metabolic process on a global scale, accounting for approximately 40-60% of the rate of carbon assimilation [29].Mitochondria, which are essential organelles involved in cellular material and energy metabolism, possess two respiratory pathways on their inner mitochondrial membrane [30].There are two pathways involved in respiration: the cytochrome pathway, which is found in nearly all organisms, and the alternate respiration pathway.The alternate respiration pathway is activated when the cytochrome pathway experiences stress conditions like low temperature, drought, ozone, and high salinity soils [31].The impact of CO 2 on mitochondrial respiration is of great significance in the investigation of plant respiratory metabolism.Previous studies have demonstrated that there exists an alternate respiration pathway, which is insensitive to cyanide (CN) but sensitive to SHAM and is facilitated by alternate oxidase (AOX) [32][33][34].Additionally, pyruvate, a crucial metabolite in organisms, has been found to have a notable enhancing effect on the activity of AOX [35][36][37].
The respiration rate serves as a primary indicator of plant respiratory metabolism.By examining the respiration rate of plants, we can directly observe the impact of high CO 2 concentration on plant respiratory metabolism.However, the effect of elevated CO 2 concentration on the plant respiration rate varies depending on the specific plants and environmental conditions.It has been discovered that elevated CO 2 concentrations resulted in an 8.4% decrease in the daily respiration rate of wheat and sunflower, as well as a 16.2% decrease in the respiration rate during darkness.This could be attributed to the reduction in leaf nitrogen content and the downregulation of photosynthesis caused by elevated CO 2 concentrations, which subsequently leads to a decrease in plant respiration rate [38].However, previous studies have demonstrated that elevated CO 2 concentrations have the potential to enhance respiratory substrate utilization, upregulate respiratory genes, and increase the number of mitochondria.As a result, this leads to an overall increase in the rate of plant respiration [39,40].
The tetraploid R. pseudoacacia L. is a deciduous ornamental tree species belonging to the genus R. pseudoacacia in the family Leguminosae.It has four sets of chromosomes (4n = 44) and was created through the application of colchicine to the diploid R. pseudoacacia (2n = 22) of a homologous species.This tetraploid species was introduced to China from South Korea [41].Compared to the diploid R. pseudoacacia, the tetraploid R. pseudoacacia is considered an excellent variety due to its higher yield, faster growth rate, larger leaves, and numerous outstanding characteristics such as drought resistance, saline resistance, low-temperature resistance, and heat resistance [42][43][44][45].The tetraploid R. pseudoacacia exhibits a robust root system, strong adaptability to various environments, and a high capacity for photosynthetic carbon sequestration [46].In light of prevalent environmental pollution and global climate change, it is imperative to investigate the effects of high CO 2 levels on the physiological processes of the tetraploid R. pseudoacacia.
Plants display distinct physiological and biochemical traits when subjected to prolonged exposure to elevated CO 2 concentrations.This study focuses on the tetraploid R. pseudoacacia as the experimental material to examine the stomatal movement pattern and physiological alterations in photosynthesis and respiration in response to high CO 2 conditions.Additionally, a proteomic approach was employed to identify crucial regulatory networks and proteins associated with the response of the tetraploid R. pseudoacacia to high CO 2 treatment.The objective of this research is to gain insights into the mechanisms by which plants respond to high CO 2 environments.

Response of Morphological and Gas Exchange Parameters of Tetraploid R. pseudoacacia to High CO 2
Under normal CO 2 conditions, the growth of the tetraploid R. pseudoacacia was uniform and healthy (CK-H 2 O).When the respiratory inhibitor SHAM was added (CK-SHAM), the REC increased, and the RWC of the leaves decreased.However, supplementation with the respiratory enhancer PA (CK-PA) did not cause significant changes in REC and RWC compared to the control.After 9 days of treatment with a 5% CO 2 concentration, the leaves exhibited wilting, drooping, yellowing, and even abscission at the apex (T-H 2 O).The yellowing and abscission of leaves worsened with the addition of SHAM (T-SHAM), while the wilting was alleviated with the addition of PA (T-PA) (Figure 1a).After 6 days of treatment, the REC of the CO 2 -treated leaves significantly increased by 34.2%, 27.2%, and 52.2% in T-H 2 O, T-PA, and T-SHAM, respectively (Figure 1b).However, the RWC of T-H 2 O, T-PA, and T-SHAM significantly decreased by 7.6%, 5.3%, and 8.4%, respectively, after 9 days of CO 2 treatment (Figure 1c).Under normal CO 2 conditions, the presence of PA did not have a significant effect on the photosynthetic parameters (Pn, Gs, Ci, and Tr) of the tetraploid R. pseudoacacia's leaves compared to the control (CK-H 2 O).However, after supplementation with SHAM on the 6th day, there was a slight fluctuation and decrease in Pn, Gs, and Tr (excluding Ci) compared to the control.When exposed to high CO 2 , the photosynthetic parameters of the leaves (Pn, Gs, Ci, and Tr) significantly decreased compared to the control (CK-H 2 O), reaching the lowest values on the 9th day.Pn, Gs, Ci, and Tr were 49.5%, 50.5%, 63%, and 63.7% lower than the control, respectively.After the high CO 2 treatment, R. pseudoacacia showed some recovery for three days under normal CO 2 conditions, with an increase in the photosynthetic parameters.However, these parameters were consistently lower than the control (Figure 1d-g).In conclusion, the results indicate that the photosynthetic gas parameters of R. pseudoacacia leaves significantly decreased after exposure to high CO 2 .The addition of the respiration enhancer PA mitigated the inhibition of photosynthesis caused by high CO 2 , while the addition of the respiration inhibitor SHAM enhanced the inhibition of photosynthesis by high CO 2 .

Response of Antioxidant System of Tetraploid R. pseudoacacia to High CO 2
To investigate the impact of high CO 2 on the antioxidant system of the tetraploid R. pseudoacacia, we initially measured the levels of H 2 O 2 and O •− were slightly decreased compared to T-H 2 O but were still higher than CK-H 2 O (Figure 2c,f).In addition, there was no significant difference in the staining intensity of DAB and NBT on the leaves before CO 2 treatment.However, after 6 days of high CO 2 treatment, the mean staining intensities of DAB and NBT on the leaves were significantly higher compared to CK-H 2 O. Similarly, the SHAM treatment increased the mean staining intensity, while PA treatment decreased it compared to T-H 2 O (Figure 2a-f).
Int. J. Mol.Sci.2024, 25, 5262 5 of 25 Under normal CO2 conditions, the presence of PA did not have a significant effect on the photosynthetic parameters (Pn, Gs, Ci, and Tr) of the tetraploid R. pseudoacacia's leaves compared to the control (CK-H2O).However, after supplementation with SHAM on the 6th day, there was a slight fluctuation and decrease in Pn, Gs, and Tr (excluding Ci) compared to the control.When exposed to high CO2, the photosynthetic parameters of the leaves (Pn, Gs, Ci, and Tr) significantly decreased compared to the control (CK-H2O), reaching the lowest values on the 9th day.Pn, Gs, Ci, and Tr were 49.5%, 50.5%, 63%, and 63.7% lower than the control, respectively.After the high CO2 treatment, R. pseudoacacia showed some recovery for three days under normal CO2 conditions, with an increase in the photosynthetic parameters.However, these parameters were consistently lower than the control (Figure 1d-g).In conclusion, the results indicate that the photosynthetic gas parameters of R. pseudoacacia leaves significantly decreased after exposure to high CO2.The addition of the respiration enhancer PA mitigated the inhibition of photosynthesis caused by high CO2, while the addition of the respiration inhibitor SHAM enhanced the inhibition of photosynthesis by high CO2.

Response of Antioxidant System of Tetraploid R. pseudoacacia to High CO2
To investigate the impact of high CO2 on the antioxidant system of the tetraploid R. pseudoacacia, we initially measured the levels of H2O2 and O2 •− .Under normal CO2 conditions, the levels of H2O2 and O2 •− decreased after PA treatment compared to CK-H2O, whereas the levels of H2O2 and O2 •− increased after SHAM supplementation.After 6 days of high CO2 treatment, the levels of H2O2 and O2 •− in the leaves were significantly higher than in CK-H2O.Furthermore, after SHAM supplementation, the levels of H2O2 and O2 •− were further increased compared to T-H2O.On the other hand, after PA treatment, the levels of H2O2 and O2 •− were slightly decreased compared to T-H2O but were still higher than CK-H2O (Figure 2c,f).In addition, there was no significant difference in the staining intensity of DAB and NBT on the leaves before CO2 treatment.However, after 6 days of high CO2 treatment, the mean staining intensities of DAB and NBT on the leaves were significantly higher compared to CK-H2O.Similarly, the SHAM treatment increased the mean staining intensity, while PA treatment decreased it compared to T-H2O (Figure 2af).SOD and CAT are considered the most significant enzymes in the plant antioxidant system, as their activity levels indicate the extent of damage caused by external factors.Meanwhile, GR and APX play a crucial role in maintaining the balance of the ASA-DHA cycle.APX functions to eliminate the excessive accumulation of H 2 O 2 in a plant, while GR is primarily responsible for converting oxidized glutathione to reduced glutathione.When CO 2 conditions are normal, the addition of SHAM slightly enhances the activities of SOD, CAT, GR, and APX.On the other hand, the supplementation of PA does not lead to any significant changes in the activities of these enzymes.However, under high CO 2 levels, the activities of SOD, CAT, GR, and APX decrease.Specifically, in T-H 2 O, T-PA, and T-SHAM, SOD activity decreased by 29.7%, 22.4%, and 54.3%, respectively, CAT activity decreased by 40.3%, 24.1%, and 47.8%, respectively, GR activity decreased by 39.6%, 32.6%, and 46%, respectively, and APX activity decreased by 49.2%, 32.8%, and 62.7%, respectively (Figure 2g-j).

Changes in Chlorophyll Levels and Fluorescence Parameters
Under normal CO 2 conditions, there were no significant differences in the content of Chl a and Chl b, as well as the ratio of Chl a/b, among the CK-H 2 O, CK-PA, and CK-SHAM groups.However, in the high CO 2 treatment group, the levels of Chl a and Chl b increased, but the ratio of Chl a/b decreased compared to CK-H 2 O after 3 days.In the CK-PA and CK-SHAM groups, there was a significant decrease in the levels of Chl a and Chl b, while the ratio of Chl a/b significantly increased after 6-9 days.Interestingly, the T-SHAM group had lower levels of Chl a and Chl b, whereas the T-PA group had higher levels of Chl a and Chl b (Figure 3a-c).SOD and CAT are considered the most significant enzymes in the plant antioxidant system, as their activity levels indicate the extent of damage caused by external factors.Meanwhile, GR and APX play a crucial role in maintaining the balance of the ASA-DHA cycle.APX functions to eliminate the excessive accumulation of H2O2 in a plant, while GR is primarily responsible for converting oxidized glutathione to reduced glutathione.When CO2 conditions are normal, the addition of SHAM slightly enhances the activities of SOD, CAT, GR, and APX.On the other hand, the supplementation of PA does not lead to any significant changes in the activities of these enzymes.However, under high CO2 levels, the activities of SOD, CAT, GR, and APX decrease.Specifically, in T-H2O, T-PA, and T-SHAM, SOD activity decreased by 29.7%, 22.4%, and 54.3%, respectively, CAT activity decreased by 40.3%, 24.1%, and 47.8%, respectively, GR activity decreased by 39.6%, 32.6%, and 46%, respectively, and APX activity decreased by 49.2%, 32.8%, and 62.7%, respectively (Figure 2g-j).

Changes in Chlorophyll Levels and Fluorescence Parameters
Under normal CO2 conditions, there were no significant differences in the content of Chl a and Chl b, as well as the ratio of Chl a/b, among the CK-H2O, CK-PA, and CK-SHAM groups.However, in the high CO2 treatment group, the levels of Chl a and Chl b increased, but the ratio of Chl a/b decreased compared to CK-H2O after 3 days.In the CK-PA and CK-SHAM groups, there was a significant decrease in the levels of Chl a and Chl b, while the ratio of Chl a/b significantly increased after 6-9 days.Interestingly, the T-SHAM group had lower levels of Chl a and Chl b, whereas the T-PA group had higher levels of Chl a and Chl b (Figure 3a-c).Under normal CO2 conditions, the leaf chlorophyll fluorescence parameters did not show a significant response to supplementation with SHAM and PA compared to the control.However, after 9 days of high CO2 treatment, Fo and NPQ increased by 15.6% and Under normal CO 2 conditions, the leaf chlorophyll fluorescence parameters did not show a significant response to supplementation with SHAM and PA compared to the control.However, after 9 days of high CO 2 treatment, Fo and NPQ increased by 15.6% and 63.4%, respectively.Fo and NPQ were higher than in T-H 2 O after supplementation with SHAM but lower than in T-H 2 O after supplementation with PA.Upon restoration of normal CO 2 conditions, Fo and NPQ returned to the control values (Figure 3d,g).During the high CO 2 treatment, Fm, Fv/Fm, qP, and ETR exhibited a decreasing trend and were significantly different compared to CK-H 2 O. On day 9 of treatment, Fm, Fv/Fm, qP, and ETR decreased by 7.3%, 51.3%, 31% and 56.5%, respectively.Fm, Fv/Fm, qP, and ETR showed a more significant decrease with SHAM supplementation compared to T-H 2 O, while the addition of the accelerator increased Fm, Fv/Fm, qP, and ETR (Figure 3e,f,h,i).These results indicate that high CO 2 has a severe impact on the chlorophyll levels and fluorescence parameters of the tetraploid R. pseudoacacia.

Effect of High CO 2 on Leaf Respiration Parameters
Under normal CO 2 conditions, the presence of PA contributed to an increase in V alt and V t , while the addition of SHAM inhibited the increase in V cyt , V alt , and V t .After 6 days of high CO 2 treatment, there was a rapid increase in Valt but a significant decrease in V cyt and V t compared to CK-H 2 O.When compared to T-H 2 O, V cyt , V alt , and V t increased with PA supplementation but decreased with SHAM supplementation.Upon restoring normal CO 2 conditions, there were no significant differences in V cyt , V alt , and V t compared to the control (Figure 4a-c These results indicate that high CO2 has a severe impact on the chlorophyll levels and fluorescence parameters of the tetraploid R. pseudoacacia.

Effect of High CO2 on Leaf Respiration Parameters
Under normal CO2 conditions, the presence of PA contributed to an increase in Valt and Vt, while the addition of SHAM inhibited the increase in Vcyt, Valt, and Vt.After 6 days of high CO2 treatment, there was a rapid increase in Valt but a significant decrease in Vcyt and Vt compared to CK-H2O.When compared to T-H2O, Vcyt, Valt, and Vt increased with PA supplementation but decreased with SHAM supplementation.Upon restoring normal CO2 conditions, there were no significant differences in Vcyt, Valt, and Vt compared to the control (Figure 4a-c).The enzyme activities of AOX, complex I, and complex II were increased by PA compared to CK-H 2 O.No significant changes in the enzyme activities of AOX, complex I, and complex II were observed after supplementation with SHAM under normal CO 2 conditions.However, the enzyme activities of AOX, complex I, and complex II were significantly increased under high CO 2 treatment.Furthermore, PA supplementation led to a more significant increase in the enzyme activities of AOX, complex I, and complex II compared to T-H 2 O, while the SHAM treatment also resulted in a significant increase in the enzyme activities of AOX, complex I, and complex II (Figure 4d-f).There were no significant changes in the enzyme activities of complexes III and IV, including after PA and SHAM supplementation, under normal CO 2 conditions.However, under high CO 2 conditions, the enzyme activities of complexes III and IV were significantly reduced.PA increased the enzyme activities of complexes III and IV compared to T-H 2 O, while SHAM decreased the enzyme activities of complexes III and IV.After restoration of normal CO 2 conditions, the mitochondrial electron transport chain enzyme activities were not significantly different from those of the control (Figure 4g,h).

Effect of High CO 2 on Leaf Stomatal Movement
To investigate the movement of stomata in the tetraploid R. pseudoacacia under high CO 2 conditions, we conducted observations on stomatal morphology and counted the stomatal apertures.When exposed to normal CO 2 levels, SHAM caused stomata closure, while PA had a lesser effect on the stomata and did not significantly change the stomatal aperture compared to CK-H 2 O.However, under the high CO 2 treatment, T-H 2 O showed a 67.9% reduction in stomatal apertures compared to CK-H 2 O. Additionally, supplementation with SHAM further decreased the stomatal apertures by 30% compared to T-H 2 O, whereas supplementation with PA increased the stomatal apertures by 81.7% (Figure 5).
Int. J. Mol.Sci.2024, 25, 5262 8 The enzyme activities of AOX, complex I, and complex II were increased b compared to CK-H2O.No significant changes in the enzyme activities of AOX, comp and complex II were observed after supplementation with SHAM under normal conditions.However, the enzyme activities of AOX, complex I, and complex II significantly increased under high CO2 treatment.Furthermore, PA supplementatio to a more significant increase in the enzyme activities of AOX, complex I, and comp compared to T-H2O, while the SHAM treatment also resulted in a significant increa the enzyme activities of AOX, complex I, and complex II (Figure 4d-f).There wer significant changes in the enzyme activities of complexes III and IV, including afte and SHAM supplementation, under normal CO2 conditions.However, under high conditions, the enzyme activities of complexes III and IV were significantly reduced increased the enzyme activities of complexes III and IV compared to T-H2O, while SH decreased the enzyme activities of complexes III and IV.After restoration of normal conditions, the mitochondrial electron transport chain enzyme activities were significantly different from those of the control (Figure 4g,h).

Effect of High CO2 on Leaf Stomatal Movement
To investigate the movement of stomata in the tetraploid R. pseudoacacia under CO2 conditions, we conducted observations on stomatal morphology and counted stomatal apertures.When exposed to normal CO2 levels, SHAM caused stomata clo while PA had a lesser effect on the stomata and did not significantly change the stom aperture compared to CK-H2O.However, under the high CO2 treatment, T-H2O sho a 67.9% reduction in stomatal apertures compared to CK-H2O.Addition supplementation with SHAM further decreased the stomatal apertures by 30% comp to T-H2O, whereas supplementation with PA increased the stomatal apertures by 8 (Figure 5).The fluorescence staining intensity of the guard cells was significantly enhanced after high CO 2 treatment, as observed through the use of the fluorescent probes H 2 DCF-DA and DAF-2DA.This indicates that high CO 2 treatment increased the accumulation of ROS and NO in the guard cells.Supplementation with SHAM further increased the fluorescence staining intensity, suggesting an increase in the accumulation of ROS and NO.On the other hand, supplementation with PA decreased the fluorescence staining intensity, indicating a decrease in the accumulation of ROS and NO in the guard cells (Figure 6).In conclusion, the tetraploid R. pseudoacacia regulates stomatal closure in response to a high CO 2 environment by inducing the accumulation of ROS and NO in the guard cells.The fluorescence staining intensity of the guard cells was significantly enhanced after high CO2 treatment, as observed through the use of the fluorescent probes H2DCF-DA and DAF-2DA.This indicates that high CO2 treatment increased the accumulation of ROS and NO in the guard cells.Supplementation with SHAM further increased the fluorescence staining intensity, suggesting an increase in the accumulation of ROS and NO.On the other hand, supplementation with PA decreased the fluorescence staining intensity, indicating a decrease in the accumulation of ROS and NO in the guard cells (Figure 6).In conclusion, the tetraploid R. pseudoacacia regulates stomatal closure in response to a high CO2 environment by inducing the accumulation of ROS and NO in the guard cells.

Proteomic Analysis of Tetraploid R. pseudoacacia Based on High CO 2 Conditions
To investigate the response of the tetraploid R. pseudoacacia to high CO 2 levels, we conducted a proteomic analysis on six groups of R. pseudoacacia leaves (CK-H 2 O, CK-PA, CK-SHAM, T-H 2 O, T-PA, and T-SHAM).The quality of the samples was confirmed by analyzing the total ion chromatograms, which showed uniform peaks (Figure S1).Additionally, the PCA analysis indicated low variability among samples within each group, as the distribution of the three biological replicates was relatively concentrated.Two-dimensional plots demonstrated significant differences in the principal components between the high CO 2 treatment groups and the groups under normal CO 2 conditions (Figure S2).A total of 1652 proteins were quantified below the protein threshold of the 1.0% FDR criterion.Furthermore, we randomly selected six DAPs from the proteome sequencing data and examined the variations in their transcript levels using qRT-PCR.The results showed that the abundance variations of the six candidate proteins under high CO 2 treatment were consistent with the trend of transcriptional expression (Figure S6).
Under normal CO 2 conditions, the comparison of CK-PA/CK-H 2 O and CK-SHAM/CK-H 2 O revealed 26 overlapping DAPs (Figure S3A).However, under high CO 2 treatment, there was a significant increase in the number of DAPs in the tetraploid R. pseudoacacia, with a total of 388 overlapping DAPs in T-PA/CK-H 2 O and T-SHAM/CK-H 2 O (Figure S3B).

When comparing T-PA/T-H 2 O and T-SHAM/T-H 2 O to T-H 2 O
, there were only 19 overlapping DAPs after PA and SHAM treatments at high CO 2 concentrations (Figure S3C).

KOG Functional Annotation and GO Enrichment Analysis of Tetraploid R. pseudoacacia DAPs' Response to High CO 2
The distribution of KOG functions was analyzed, and the results showed that, under high CO 2 treatment, the most abundant functions in T-H 2 O/CK-H 2 O (52 DAPs) were posttranslational modification, protein turnover, and chaperones; nucleotide transport and metabolism, translation, ribosomal structure and biogenesis, and energy production and conversion included 48, 41, and 35 DAPs, respectively (Figure 8a).In the case of normal CO 2 treatment, the DAPs in CK-PA/CK-H 2 O were mainly associated with general function prediction only, lipid transport and metabolism, posttranslational modification, protein turnover, and chaperones (Figure 8b), whereas the DAPs in CK-SHAM/CK-H 2 O were mainly distributed in translation, ribosomal structure and biogenesis, posttranslational modification, protein turnover, and energy production and conversion (Figure 8c).Under Under normal CO2 conditions, the comparison of CK-PA/CK-H2O and CK-SHAM/CK-H2O revealed 26 overlapping DAPs (Figure S3A).However, under high CO2 treatment, there was a significant increase in the number of DAPs in the tetraploid R. pseudoacacia, with a total of 388 overlapping DAPs in T-PA/CK-H2O and T-SHAM/CK-H2O (Figure S3B).When comparing T-PA/T-H2O and T-SHAM/T-H2O to T-H2O, there were only 19 overlapping DAPs after PA and SHAM treatments at high CO2 concentrations (Figure S3C).

KOG Functional Annotation and GO Enrichment Analysis of Tetraploid R. pseudoacacia DAPs' Response to High CO2
The distribution of KOG functions was analyzed, and the results showed that, under high CO2 treatment, the most abundant functions in T-H2O/CK-H2O (52 DAPs) were posttranslational modification, protein turnover, and chaperones; nucleotide transport and metabolism, translation, ribosomal structure and biogenesis, and energy production and conversion included 48, 41, and 35 DAPs, respectively (Figure 8a).In the case of normal CO2 treatment, the DAPs in CK-PA/CK-H2O were mainly associated with general In the GO enrichment analysis, DAPs were categorized into three groups: biological processes, molecular functions, and cellular components.Under normal CO 2 conditions, there were fewer DAPs in the CK-PA/CK-H 2 O group with no significant differential enrichment (Figure S5a).For the CK-SHAM/CK-H 2 O group, the most enriched biological processes were cellular (128 DAPs) and metabolic (118 DAPs) processes; the most enriched molecular functions were catalytic activity (107 DAPs) and binding (99 DAPs); and the most enriched cellular components were cell parts (142 DAPs) and intracellular parts (135 DAPs) (Figure S5c).Under high CO 2 treatment, the most responsive biological processes were cellular (287 DAPs) and metabolic ( 252 (Figure 8c).Under high CO2 treatment, the DAPs in T-PA/CK-H2O were mainly associated with general function prediction only, posttranslational modification, protein turnover, chaperones, and energy production and conversion (Figure 8d).Similarly, the DAPs in T-SHAM/CK-H2O were mainly related to general function prediction only, posttranslational modification, protein turnover, chaperones, intracellular trafficking, secretion, and vesicular transport (Figure 8e).There was no significant difference in the distribution of KOG function between T-PA/T-H2O and T-SHAM/T-H2O after supplementation with PA and SHAM under high CO2 treatment (Figure 8f,g).

Pathway Analysis of DAPs in Tetraploid R. pseudoacacia under High CO 2 Treatment
To further elucidate the metabolic pathways involved in the DAPs of the tetraploid R. pseudoacacia, DAPs were analyzed for KEGG enrichment.Under normal CO 2 conditions, the DAPs in the CK-PA/CK-H 2 O group were mainly enriched in fatty acid biosynthesis, fatty acid metabolism, and biotin metabolism (Figure 9b).In the CK-SHAM/CK-H 2 O group, the DAPs were mainly enriched in metabolic pathways, the biosynthesis of secondary metabolites, glutathione metabolism, and carotenoid biosynthesis (Figure 9c).Under high CO 2 treatment, the DAPs in the T-H 2 O/CK-H 2 O group were significantly enriched in metabolic pathways, carbon metabolism, the biosynthesis of secondary metabolites, the biosynthesis of amino acids, and photosynthesis (Figure 9a).The DAPs in the T-PA/CK-H 2 O and T-SHAM/CK-H 2 O groups were significantly enriched in metabolic pathways, the biosynthesis of secondary metabolites, the biosynthesis of amino acids, phenylalanine metabolism, phenylacetone biosynthesis, and glutathione metabolism (Figure 9d,e

Discussion
Short-term CO2 enrichment has been found to alleviate the impact of abiotic stresses, such as drought and salt, on plants [47,48].In the tetraploid R. pseudoacacia, prolonged exposure to high CO2 resulted in a gradual decrease in the relative water content of its leaves over time, ultimately leading to the inhibition of its growth and development.In the present study, we observed the yellowing, wilting, and abscission of leaves, as well as a decrease in the relative water content in the tetraploid R. pseudoacacia at high CO2

Discussion
Short-term CO 2 enrichment has been found to alleviate the impact of abiotic stresses, such as drought and salt, on plants [47,48].In the tetraploid R. pseudoacacia, prolonged exposure to high CO 2 resulted in a gradual decrease in the relative water content of its leaves over time, ultimately leading to the inhibition of its growth and development.In the present study, we observed the yellowing, wilting, and abscission of leaves, as well as a decrease in the relative water content in the tetraploid R. pseudoacacia at high CO 2 concentrations (Figure 1a).This phenomenon could be attributed to a reduction in water flux caused by high CO 2 and weakened upward water transport due to a decreased transpiration rate [49,50].These factors contribute to the recovery of plants once the CO 2 concentration is restored (Figure 1c).The magnitude of the REC can indicate the condition of the plant membrane system.When plants face adversity or injuries, the cell membrane may rupture, causing a leakage of cytoplasmic cytosol and consequently increasing the conductivity.The substantial increase in REC observed at high CO 2 concentrations suggests that the plant experienced stress injury and cell damage (Figure 1b).PA, known as a facilitator of the alternate respiration pathway, and SHAM, an inhibitor [32, 33,35], have shown contrasting effects on the stress symptoms of the tetraploid R. pseudoacacia.PA supplementation alleviated the stress response of the tetraploid R. pseudoacacia to high CO 2 , whereas SHAM supplementation exacerbated this stress response (Figure 1).
Photosynthesis involves important physiological indicators used to study the impact of abiotic stress on plants.High levels of CO 2 can reduce the photosynthetic capacity of plants.This reduction is mainly seen through decreased CO 2 assimilation capacity and photochemical activities [10,13,51].In our study, we observed a decrease in photosynthetic parameters in the tetraploid R. pseudoacacia's leaves when exposed to high CO 2 , indicating the inhibition of photosynthetic performance.However, after treatment with PA, the photosynthetic performance showed signs of recovery.After SHAM treatment, photosynthesis in the tetraploid R. pseudoacacia was found to be even more inhibited (Figure 1e-g).This could be due to a decrease in photosynthetic parameters resulting from a reduction in the amount and activity of Rubisco, stomatal conductance, and photorespiration [52,53].
A high concentration of CO 2 induces an accumulation of ROS in plants [54,55].Previous studies have shown that an excessive accumulation of electrons in the PSII leads to an over-reduction in electrons, which in turn causes the electron transport chain to become highly reduced, resulting in the formation of ROS.This oxidative stress not only causes damage to plants but also triggers retrograde signals to the nucleus, leading to responses at the gene expression level [56,57].In the tetraploid R. pseudoacacia, there was a significant increase in ROS levels compared to the control group under high CO 2 .This change in ROS levels was observed when the AOX pathway was stimulated or inhibited (Figure 2a-c), which aligns with Dinakar's study [58].Algae have developed various antioxidant defense mechanisms to mitigate the oxidative stress caused by H 2 O 2 .These mechanisms include enzymatic processes involving the ascorbate-glutathione cycle, glutathione S-transferase (GST), glutathione peroxidase (GPX), and CAT.Additionally, nonenzymatic mechanisms related to carotenoids and glutathione also play a role [59][60][61].Most ROS-scavenging enzymes, such as CAT, SOD, and APX, are predominantly bound to cystoid membranes and exhibit similarities.When plants experience stress, they promptly remove ROS to prevent toxicity caused by ROS diffusion into the matrix [61].To maintain ROS homeostasis, the activity of antioxidant enzymes is typically enhanced to eliminate excess ROS, thus safeguarding the plant from oxidative damage and enhancing its stress tolerance [62,63].However, this mechanism is effective against mild oxidative damage, and if the damage surpasses the plant's tolerance threshold, the inability to eliminate ROS will hinder the functioning of antioxidant enzymes [64,65].In this study, high concentrations of CO 2 led to a significant increase in ROS levels in the tetraploid R. pseudoacacia, exceeding the capacity of the antioxidant system and resulting in the suppression of SOD, CAT, GR, and APX activities, ultimately causing damage to the plant (Figure 2d-f).
Chlorophyll content can have a direct impact on a plant's capacity to capture light energy.The decrease in chlorophyll content can be attributed to two factors: the blockage of chlorophyll synthesis and the degradation of chlorophyll [66].In our study, we observed that the levels of both Chl a and b initially increased and then decreased under high CO 2 treatments (Figure 3a,b).This finding aligns with previous research and suggests that high concentrations of CO 2 may inhibit chlorophyll synthesis [67].We investigated the impact of an elevated CO 2 concentration on the activity of PSII using the chlorophyll fluorescence technique.The intensity of chlorophyll fluorescence is an indicator of the redox state of the main receptor Q in PSII [68].Our findings revealed that the treatment with high CO 2 levels resulted in an increase in Fo but a significant decrease in Fm and Fv/Fm in the tetraploid R. pseudoacacia (Figure 3d-f).This suggests that the activity of PSII was hindered, leading to an excessive accumulation of electrons in PSII.Additionally, qP and NPQ represent the capacities for photochemical and nonphotochemical excitation quenching, respectively, and the quantum yields of these two types of fluorescence quenching are interconnected [69].A decrease in ETR signifies a decline in photosynthetic activity.In the tetraploid R. pseudoacacia, photosynthesis is hindered, disrupting the balance of the system.When the plant is under stress, PSII is inhibited (Figure 3), resulting in the generation of a chlorophyll triplet state and singlet oxygen ( 1 O 2 ), which ultimately leads to the accumulation of ROS.
The regulation of the mitochondrial electron transport chain, which includes the cytochrome respiratory (COX) and AOX respiratory pathways, is influenced by abiotic stress.Under high CO 2 conditions, AOX respiration is upregulated in plant mitochondria to support normal plant physiological activities [70].Research has demonstrated the significance of the AOX pathway in A. thaliana in response to elevated CO 2 [71].It was observed that the rate of cytochrome respiration in the tetraploid R. pseudoacacia decreased, while the rate of AOX respiration increased under high CO 2 stress.However, overall respiration was inhibited.AOX respiration, which is a SHAM-sensitive type of respiration, was stimulated by PA treatment and had a significant effect on AOX [32,33,35].PA treatment notably enhanced the AOX respiration pathway, while the response of AOX respiration in the tetraploid R. pseudoacacia to high CO 2 was inhibited by SHAM (Figure 4d).In contrast, the mitochondrial transfer chain (ETC) complexes (I, II, III, and IV) exhibited distinct responses under high CO 2 .The activities of complexes I and II were decreased, while the activities of complexes III and IV were downregulated (Figure 4e-h).This alteration in activity levels could be attributed to mitochondrial damage resulting from the accumulation of ROS.
Low CO 2 promotes stomatal opening, while high CO 2 induces stomatal closure.Stomata, which serve as the primary site for gas exchange, can adjust the pore size in response to changes in the external environment.Studies have shown that high CO 2 stimulates an increase in the concentration of free Ca 2+ in guard cells, leading to the induction of stomatal closure [14][15][16][17].Transient changes in the pH and membrane potential of guard cells occur alongside stomatal closure when the CO 2 concentration is increased [72].Stomata control the size of pores in the leaf in response to CO 2 concentration, and elevated CO 2 also inhibits stomatal development [73,74].Previous studies have demonstrated that high levels of CO 2 can induce stomatal closure, with ROS playing a crucial role in this regulatory process [22,75].NO plays a role in both ABA-and Ca 2+ -mediated stomatal closure, which is an important participant in the stomatal closure process [24,25,76].When compared with normal CO 2 , high CO 2 significantly induces stomatal closure.PA alleviates this process, while SHAM exacerbates the degree of closure.Additionally, SHAM also causes a slight closure of stomata at normal CO 2 concentrations.Through fluorescence staining, it was observed that CO 2 -induced stomatal closure is accompanied by a large accumulation of H 2 O 2 and NO in the guard cells (Figures 5 and 6).This provides evidence for the crucial role of ROS and NO in the stomatal closure of the tetraploid R. pseudoacacia in response to high CO 2 stress.
In C3 plants, glucose is primarily biosynthesized through the Calvin cycle.A crucial step in this process is the formation of glycerate-3-phosphate (3PGA) through the action of 1,5-bisphosphate ribulose carboxylase using CO 2 [28].Rubiscos, which are photosynthetic CO 2 -fixing enzymes, are activated by Rubisco activase (Rcas).However, if the N-terminus of the large subunit is missing, Rubiscos are not activated [78].The involvement of carbon dioxide is also essential for the activation of Rubiscos [79].In this study, we observed a significant downregulation of many 1,5-bisphosphate ribulose carboxylase-related subunits (I6QMJ2, A0A0F6Y5S8, C0J370, A0A898CTM2) under high CO 2 treatment.This downregulation resulted in the inability of Rubiscos to be activated under light and CO 2 conditions, leading to a decrease in the photosynthesis rate.Furthermore, the inhibition of photosynthesis was also attributed to the impact on photosystem protein synthesis, electron transfer between photosystems, and chlorophyll binding [80][81][82].Pigment-protein complexes CP43 and CP47 are known to transfer excitation energy from the outer antenna of photosystem II to the photochemical reaction center, as well as being involved in the process of water oxidation [83,84].The excess energy absorbed by the photosystem I complex is transferred to P700 via chlorophyll, thus protecting the pigment-protein complex from photodestruction [85].The photosystem II D1/D2 complex proteins catalyze the oxidation of water due to a high REDOX potential [86].Light trapping and the conversion of light energy to chemical energy occur through the iron-sulfur center in photosystem I [87,88].In our study, we observed a significant downregulation of various photosystem constitutive proteins in the tetraploid R. pseudoacacia.These proteins include photosystem II CP43/47 reaction center proteins (A0A6H0EHP1, A0A1C7D4D5), photosystem I P700 chlorophyll a apoprotein A1/A2 (A0A1C7D3U7, A0A1C7D4C6, A0A6H0EHR0), photosystem I reaction center subunit II (I3STB2), photosystem II D1/D2 proteins (A0A1C7D3T6, A0A1C7D3V4), electron-transfermediating protein cytochrome f (A0A1C7D3W5), plastoquinone-plastocyanin reductase (I3RZ73, I1LUB3), the photosystem I iron-sulfur center (A0A1C7D3Z6), and the chlorophyll a-b binding protein (I3SIW2).This downregulation resulted in the inhibition of electron transfer and light capture, ultimately leading to the blockage of photosynthesis in the tetraploid R. pseudoacacia.
Glutathione (GSH) plays a crucial role in various biological processes.When GSH is oxidized to oxidized glutathione (GSSG) by GPX, it catalyzes the reduction of H 2 O 2 .Additionally, GR helps in regenerating GSH.Additionally, GSH has been found to effectively increase the antioxidant capacity of plants and enhance the activity of respiratory enzymes [89].In certain studies, advanced GSH treatment has proven to be effective in preventing broccoli fermentation in a high CO 2 atmosphere.This is achieved by promoting the AsA-GSH cycle and the electron (ETC) pathway [78].Exogenous PA can maintain intracellular glutathione levels in H 2 O 2 -treated cells and enhance their antioxidant capacity [90].The presence of GSH is vital for copepods in defending against seawater acidification induced by varying CO 2 concentrations [91].In this study, the expression of GPX (I3SK85, I1KP94, I1MX60, C6SY48) was significantly decreased by high CO 2 treatment.However, this decrease was reversed when PA was applied, indicating that the antioxidant capacity of the tetraploid R. pseudoacacia was restored.The decrease in GPX expression resulted in the accumulation of ROS.GR plays a crucial role in the interconversion between oxidized and reduced glutathione, facilitating the recirculation of GSH.In soybeans, enhancing GR can effectively improve the removal of ROS [92].In the context of this experiment, high CO 2 levels led to the downregulation of GR and diminished the regeneration ability of GSH.However, the application of PA facilitated the conversion between GSH and GSSG under high CO 2 conditions, which enhanced the scavenging of H 2 O 2 and alleviated oxidative damage.

Plant Materials and Stress Treatment
The plant materials comprised the tetraploid R. pseudoacacia, which was two years old.In the spring, bare-root seedlings were planted in uniform-sized pots (diameter × height × bottom diameter = 20 × 28 × 20 cm), and seedlings with uniform growth were chosen for CO 2 treatment after 2 months of growth under normal conditions.The potted seedlings were placed in a light incubator for 3 days for pre-cultivation to acclimate to the new environment.The soil moisture was maintained at 70% throughout, and the culture conditions were as follows: 16 h of light, 8 h of darkness, temperature set at 25 • C, air humidity at 70%, and light intensity at 6000 Lux.The seedlings undergoing the high CO 2 treatment were divided into a control group (natural conditions, a CO 2 concentration of about 0.031%) and treatment groups (a CO 2 concentration of 5%), and the seedlings were subjected to high CO 2 treatment for 9 days before being incubated again under normal CO 2 concentration for 3 days.On day 6 of CO 2 treatment, a respiration accelerator (pyruvic acid, 0.1 mM) and a respiration inhibitor (salicylhydroxamic acid, 1 mM) were sprayed on the leaves of the tetraploid R. pseudoacacia every 3 h.Morphological observations on leaves were made after 0 d, 3 d, 6 d, 9 d, and 12 d.For each treatment, leaves were collected for physiological and proteomic measurements, with three or six biological replicates.

Determination of Relative Water Content and Relative Electrical Conductivity
After 0.5 g of fresh leaves (FWs) moistened in distilled water for 4 h, the surface water was removed, weighed, and recorded as TW, and then the leaves were dried in a drying oven and recorded as DW.Relative water content: RWC (%) = (FW − DW)/(TW − DW) × 100.
A total of 0.1 g of evenly chopped leaves were poured in 5 mL of ddH 2 O and shaken at 160 rpm for 1 h.The electrical conductivity was measured and recorded as L2 using a DDS-IIA conductivity meter (INESA Scientific Instruments Co., Shanghai, China), and the control of ddH 2 O was recorded as L1.After cooling to ambient temperature, the samples were immersed in a boiling water bath for 15 min, and the electrical conductivity was measured and recorded as L3.Relative electrical conductivity (%) = (L2 − L1)/(L3 − L1) × 100.

Determination of Chlorophyll Content and Photosynthetic and Fluorescence Parameters
The chlorophyll content of the fourth and fifth leaves from the end, located in the middle of the acacia branches, was determined.A total of 0.2 g of leaves were immersed in the extraction solution (80% acetone/ethanol/ddH 2 O = 4.5:4.5:1).The leaves were then kept in the dark for 24 h.The optical density at wavelengths of 470 nm, 645 nm, and 663 nm was The photosynthetic parameters of leaves were determined using a Li-COR 6400 photosynthesis system (LI-COR, Lincoln, NE, USA).Six leaves per group were analyzed, and the measurements were repeated three times.These parameters included the net photosynthetic rate (Pn), the transpiration rate (Tr), the intercellular carbon dioxide concentration (Ci), and the stomatal conductance (Gs).The measurements were conducted under specific conditions, including a temperature of 24 • C, a photon flux density (PFD) of 90 µmol m −2 •s −1 , a relative humidity of 70%, and an ambient CO 2 concentration of 400 µmol CO 2 mol −1 .
The chlorophyll fluorescence parameters of leaves were measured using an FC800-O fluorescence imaging system (FluorCam, Drásov, Czech Republic) [93].The leaves were dark-adapted for 30 min, following the previously described method.The data collected included initial fluorescence yield (Fo), maximum fluorescence yield (Fm), photochemical quenching (qP), the maximum photochemical efficiency of photosystem II (PSII) (Fv/Fm), nonphotochemical quenching (NPQ), and the relative electron transfer rate (ETR).A total of six leaves were measured for each treatment group.

Determination of Leaf Respiration Parameters
The leaf respiration rate was determined using the OXYTHE-RM oxygen electrode.The total respiration rate (V t ) was determined by incubating 0.1 g leaves of R. pseudoacacia from the same location in a reaction medium containing 2 mM HEPES, 10 mM MES (pH 10.7), and 2 mM CaCl 2 for 30 min in the dark.To determine the residual respiration (V res ), SHAM (200 mM) and KCN (200 mM) were added to the assay.V res was then subtracted from the respiratory activity observed when SHAM was added alone to obtain the activity of the major cytochrome pathway (V cyt ).Similarly, V t was subtracted from the respiratory activity observed when SHAM was added alone to obtain the actual activity of the alternative pathway (V alt ).
The activity of mitochondrial electron transport chain complex I-IV (complex I-IV) and AOX was measured in the central leaves of R. pseudoacacia using the Plant Mitochondrial Respiratory Chain Complex I-IV and Plant AOX Activity Kit (Hengyuan Biologicals, Shanghai, China).

Stomatal Movement
Under controlled light and temperature conditions, fresh leaves were collected from plants grown under normal conditions and with high CO 2 treatments.The upper epidermis and leaf pulp of both the proximal and distal axes of the leaf blades were gently scraped.Stomatal morphology was then observed randomly using a microscope.More than 100 stomata were selected for each treatment sample.The length and width of the stomatal images were measured using ImageJ v1.8.0 to calculate the stomatal openness.

Fluorescent Probe Staining
Fresh leaves were collected from plants under both normal conditions and high CO 2 treatments after 0, 6, and 12 days.Leaf blades, excluding the main veins, were cut into 1 cm pieces.These pieces were then immersed in 50 mM H 2 DCF-DA or 0.1 mM DAF-2DA for 30 min in the absence of light.Subsequently, they were photographed using a fluorescence microscope in 10 randomly selected fields of view.The average fluorescence intensity was calculated using ImageJ.

Histochemical Staining
The leaves were fully immersed in a staining solution containing 10 mg•mL −1 DAB and NBT.To eliminate air bubbles, a vacuum pump was used for 30 min.Subsequently, the leaves were stained under dark conditions for 24 h.Chlorophyll was completely removed by submerging the leaves in a decolorizing solution.The leaves were then photographed and recorded, and the average fluorescence intensity was measured using ImageJ.

Determination of H 2 O 2 and O 2
•− Content A total of 0.5 g of leaves were homogenized in 0.1% TCA in an ice bath.The homogenate was then centrifuged at 12,000 rpm for 10 min.The extract was mixed with phosphate buffer solution (PBS) (pH 7.5) and KI (1 M).The absorbance of the mixture was measured at 390 nm.
Similarly, a total of 0.5 g of leaves were homogenized in hydroxylamine hydrochloride in an ice bath and then centrifuged at 12,000 rpm for 10 min.The supernatant obtained was incubated with 1-Naphthylamine and aminobenzenesulfonic acid for 2 min at room temperature.Subsequently, the absorbance of the solution was measured at 520 nm [94].

Determination of Antioxidant Enzyme Activity
Crude enzyme extract was prepared by grinding 0.5 g of leaves in liquid nitrogen and centrifuging in PBS at 12,000 rpm for 10 min.A mixture of 20 µL of extract, 50 mM PBS (pH 7.8), 100 µM ethylene diamine tetraacetic acid (EDTA), and 10 mM pyrogallic acid was thoroughly mixed.Superoxide dismutase (SOD) activity was measured by UV spectrophotometry at 420 nm.Another mixture of 0.2 mL of extract, 50 mM PBS, and ddH 2 O was thoroughly mixed, and the reaction was carried out in a water bath at 25 • C for 10 min; catalase (CAT) activity was measured at 240 nm.Additionally, 0.05 mL of extract, PBS, and 5 mM ASA were mixed thoroughly.This mixture was then followed by the addition of 0.1 mM H 2 O 2 , and the activity of ascorbate peroxidase (APX) was measured at 290 nm.Furthermore, a mixture of 10 µL of extract, 100 mM PBS, 2 mM EDTA, and 0.5 mM glutathione was mixed thoroughly.This mixture was then followed by the addition of 0.2 mM NADPH, and the activity of glutathione reductase (GR) was detected at 340 nm [45].

Quantitative Proteomics Analysis
Six sets of samples were pretreated using the iST Sample Pretreatment Kit (PreOmics, Planegg, Germany) and stored at −80 • C under vacuum conditions.The samples were crushed in liquid nitrogen and then mixed with buffer (1:10) and protease inhibitors.After vortexing for 10 min, the samples were vortexed for another 10 min with an equal volume of Tris-saturated phenol (pH 8.0).Subsequently, they were centrifuged at 12,000 rpm for 20 min at 4 • C, and the phenol phase was combined with buffer and vortexed before centrifugation.The precipitate was then treated with pre-cooled ammonium acetate-methanol solution, precipitated overnight at −20 • C, and finally centrifuged at 12,000 rpm for 20 min at 4 • C. The supernatant was discarded, and the precipitate was washed twice with 90% acetone.The precipitate was then suspended in an appropriate volume of lysate to solubilize the sample proteins, followed by centrifugation at 12,000 rpm for 20 min at 4 • C to collect the supernatant.This step was repeated to ensure maximum collection of the supernatant.Each sample was then suspended in 30 µL of solvent A, and 1 µL of 10×iTR peptide was added to 9 µL of each sample.After thorough mixing, the samples were subjected to nanoliquid chromatography.For tandem mass spectrometry analysis, 4 µL of the samples were taken.The separation of the sample occurred over a 90 min gradient with a column flow rate of 600 nL•min −1 and a column temperature of 55 • C. The gradient started at 4% B-phase and was equilibrated for 4 min, followed by a nonlinear gradient increase to 30% over 80 min.Subsequently, the gradient increased to 90% in 2 min and was held for 8 min.
Data analysis: DIA data were analyzed using Spectronaut 15.0 default parameters (Omicsolution Co., Ltd., Shanghai, China).The sequence database used was the uniprotrobinioid clade database, and trypsin enzymatic digestion was applied.The search library parameters included a fixed modification, carbamidomethyl (C), and a variable modification, methionine oxidation.The criteria for protein characterization were a precursor threshold of 1.0% false discovery rate (FDR) and a protein threshold of a 1.0% FDR.To generate the decoy database, a mutation strategy was employed, similar to perturbing a random number of amino acid sequences.Spectronaut 15.0 performed auto-correction, and a local normalization strategy was implemented for data normalization.Protein group quantification was conducted by calculating the average of the peak areas of the first 3 peptides below 1.0% FDR.For differential screening, proteins with a p adj value < 0.05 and |fold change| > 1.5 were considered significant after analysis by a one-way ANOVA test.

Functional Annotation and Cluster Analysis
An unsupervised principal component analysis (PCA) was conducted on the entire dataset to provide a comprehensive overview of the quantitative proteomics data, assessing its relevance and reproducibility.Volcano plots were then analyzed using a one-way ANOVA test, with a significance threshold of a p adj value < 0.05.To identify differen-

Figure 4 .
Figure 4. Effect of high CO 2 concentration on respiratory parameters and mitochondrial electron transport chain complex enzyme activities in R. pseudoacacia.Cytochrome pathway capacity (V cyt ) (a), alternative pathway capacity (V alt ) (b), total respiration (V t ) (c), AOX enzyme activity (d), complex I enzyme activity (e), complex II enzyme activity (f), complex III enzyme activity (g), and complex IV enzyme activity (h).Six biological replicates were analyzed, and the error bars represent the SE.Asterisks indicate significant differences as determined by Dunnett's test.(* p ≤ 0.05; ** p ≤ 0.01; *** p ≤ 0.001).

25 Figure 7 .
Figure 7. Volcano maps of differentially expressed proteins (DEPs) in R. pseudoacacia under CO2 treatment.The horizontal coordinate is log2 (fold change), and the vertical coordinate is the negative logarithm of the p-value of the t-test significance test -log10 (padj).(a) T-H2O vs. CK-H2O; (b) CK-PA vs. CK-H2O; (c) CK-SHAM vs. CK-H2O; (d) T-PA vs. CK-H2O; (e) T-SHAM vs. CK-H2O; (f) T-PA vs. T-H2O; and (g) T-SHAM vs. T-H2O.Red represents upregulated proteins, blue represents downregulated proteins, grey represents proteins with no differential change, and the dotted grey line in the middle represents the threshold line for the DAP screening criteria.

Figure 7 .
Figure 7. Volcano maps of differentially expressed proteins (DEPs) in R. pseudoacacia under CO 2 treatment.The horizontal coordinate is log2 (fold change), and the vertical coordinate is the negative logarithm of the p-value of the t-test significance test -log10 (padj).(a) T-H 2 O vs. CK-H 2 O; (b) CK-PA vs. CK-H 2 O; (c) CK-SHAM vs. CK-H 2 O; (d) T-PA vs. CK-H 2 O; (e) T-SHAM vs. CK-H 2 O; (f) T-PA vs. T-H 2 O; and (g) T-SHAM vs. T-H 2 O. Red represents upregulated proteins, blue represents downregulated proteins, grey represents proteins with no differential change, and the dotted grey line in the middle represents the threshold line for the DAP screening criteria.
DAPs) processes in the T-H 2 O/CK-H 2 O group; the most responsive molecular functions were catalytic activity (259 DAPs) and binding (259 DAPs); and the most responsive cellular components were cell parts (327 DAPs) and intracellular parts (309 DAPs) (Figure S5b).The significantly enriched categories of each GO classification in the T-PA/CK-H 2 O and T-SHAM/T-H 2 O groups largely overlapped with those in the T-H 2 O/CK-H 2 O group (Figure S5d,e).These results indicate a significant increase in GO-enriched DAPs under high CO 2 treatment.
).Finally, the DAPs in the T-PA/T-H 2 O and T-SHAM/T-H 2 O groups were mainly enriched in

Figure 9 .
Figure 9. KEGG enrichment analysis of DEPs identified in R. pseudoacacia under CO 2 treatment.(a) T-H 2 O vs. CK-H 2 O; (b) CK-PA vs. CK-H 2 O; (c) CK-SHAM vs. CK-H 2 O; (d) T-PA vs. CK-H 2 O; (e) T-SHAM vs. CK-H 2 O; (f) T-PA vs. T-H 2 O; and (g) T-SHAM vs. T-H 2 O.The x-axis represents the enrichment factor, and the y-axis represents the pathway of enrichment.Larger orange points represent major pathway enrichment and higher pathway impact values, respectively.
were further increased compared to T-H 2 O. On the other hand, after PA treatment, the levels of H 2 O 2 and O 2 2 ). Fo and NPQ were higher than in T-H2O after supplementation with SHAM but lower than in T-H2O after supplementation with PA.Upon restoration of normal CO2 conditions, Fo and NPQ returned to the control values (Figure3d,g).During the high CO2 treatment, Fm, Fv/Fm, qP, and ETR exhibited a decreasing trend and were significantly different compared to CK-H2O.On day 9 of treatment, Fm, Fv/Fm, qP, and ETR decreased by 7.3%, 51.3%, 31% and 56.5%, respectively.Fm, Fv/Fm, qP, and ETR showed a more significant decrease with SHAM supplementation compared to T-H2O, while the addition of the accelerator increased Fm, Fv/Fm, qP, and ETR (Figure3e,f,h,i).