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Article

Silicon Modulates Molecular and Physiological Activities in Lsi1 Transgenic and Wild Lemont Rice Seedlings under Arsenic Stress

Fujian Provincial Key Laboratory of Agroecological Processing and Safety Monitoring, College of Life Sciences, Fujian Agriculture and Forestry University, Fuzhou 350002, China
*
Author to whom correspondence should be addressed.
Agronomy 2021, 11(8), 1532; https://doi.org/10.3390/agronomy11081532
Submission received: 5 July 2021 / Revised: 27 July 2021 / Accepted: 28 July 2021 / Published: 30 July 2021
(This article belongs to the Collection Crop Physiology and Stress)

Abstract

:
Arsenic is one of the most dangerous metalloids, and silicon is a helpful element supporting plants to withstand stress. In this study, three factors were considered, including rice accessions with three different lines, including Lsi1-RNAi line (LE-R), Lsi1 overexpression line (LE-OE), and their wild type (LE-WT), and silicon and arsenic treatments with two different levels. Analysis of variance in dry weight biomass, protein content, arsenic, and silicon concentration has shown a significant interaction between three factors. Further analysis showed that the silicon concentration of all rice seedlings under silicon treatments increased significantly. The LE-OE line has shown a higher ability to absorb silicon in hydroponic conditions than the wild type, and when the seedlings were exposed to arsenic, the concentration of arsenic in all lines increased significantly. Adding silicon to over-expressed rice lines with the Lsi1 gene creates better arsenic resistance than their wild type. These findings confirmed antagonism between silicon and arsenic, and seedlings exposed to arsenic showed a reduction in silicon concentration in all rice lines. RNA-seq analysis showed 106 differentially expressed genes in the LE-OE line, including 75 up-regulated genes and 31 down-regulated genes. DEGs in the LE-R line were 449 genes, including 190 up-regulated and 259 down-regulated genes. Adding treatment has changed the expression of Calcium-binding EGF domain-containing, Os10g0530500, Os05g0240200 in both LE-OE and LE-R roots. They showed that transgenic cultivars were more resistant to arsenic than wild-type, especially when silicon was added to the culture medium.

1. Introduction

The effects of environmental pollution on nature and humans have been increasingly recognized over the past decades. One of the most imminent threats to nature and ecosystems is water and soil pollution by metalloids and heavy metals. They penetrate biological cycles, cause fundamental changes in ecosystems, and have harmful environmental effects [1]. Arsenic (As) is a toxic metalloid with different oxidation numbers (−3, +3, +5). However, it occurs naturally in the soil in low concentrations, mainly originating from human activities [2]. Humans are mainly exposed to As by consuming contaminated foods and water in areas contaminated by mining activities [3]. Arsenic disrupts blood circulation, damages the gastrointestinal tract and nervous system, and damages the skin; therefore, it threatens human health, and its acute poisoning can be fatal [4]. Arsenic compounds penetrate the environment through many materials used in industry; this element is used significantly as herbicides, fungicides, insecticides, algaecides, etc. [5].
Silicon (Si) is a fundamental element in the soil and the earth’s crust [6,7], and it contains 1 to 45% of the dry weight of the soil, but only 0.1 to 0.6% of it is soluble [8]. Si is an immobile element in plants, but it is not an essential element. However, many plants, including rice, need Si for normal growth, especially in stress conditions that can increase plant resistance [7,9]. Plants absorb Si as Si(OH)3O or Si(OH)4 (Orthosilicic acid), and it makes up 0.1 to 10% of the plant’s dry weight. Silicon also increases the resistance of the plant to non-biotic and biotic stresses [10].
Rice is an essential crop in the world that provides 40% of people’s food. It provides two thirds of the calories needed by two billion people in Asia and is also the main source of protein for this population [11]. As rice is a stacked Si plant, it is often used as a model plant for silicon uptake, transport, and accumulation [12]. However, adding Si to soil and water significantly reduces the concentration of As in rice. Some reports have shown that Si can contribute to methylation growth in rice tissues and affect rice accumulation of different As species [13].
Moreover, Si decreases As uptake and transport in plants and reduces the As amount in polished and brown rice to 33% and 22%, respectively [14]. Ali, Isayenkov [15] reported that silicon could reduce arsenic transfer in rice. Thus, it reduced the concentration of As in straw and leaves by 50%. Reports have indicated that different rice genotypes also have different levels of As storage capacity [16,17], and various experiments have shown significant differences in the ability of different types of rice in arsenic accumulation in straw and grain [2,18].
Two silicon carriers in rice (Lsi1 and Lsi2) have reportedly facilitated arsenic transport from soil to plants [19]. Lsi1 is an invasive transporter responsible for transporting silicon and arsenic (III) from culture solutions to rice root cells. Therefore, arsenic transfer from the environment to the plant is mediated by Lsi1 [20]. Research has shown that the Lsi1 expression gene in rice increases plant resistance to As (III) treatment [21].
Plants have different mechanisms for detoxifying As, one of which is the production of compounds between As and thiols, same as glutathione, which reduces the motility of As in vacuoles [22]. Detoxification of reactive oxygen species (ROS) is achieved by synthesizing antioxidants like glutathione S-transferase, superoxide dismutase, catalase, and glutathione [23].
The present study attempts to elucidate Lsi1 mechanisms regulating Si uptake to affect arsenic accumulation in rice seedlings. We hypothesized that detoxification-related genes were involved in regulating As tolerance in rice. To detect it, three different rice lines, including wild Lemont, LE-OE, and LE-R, where the level of Lsi1 transcript was different, were used to study the transcription of As and Si genes in these lines under arsenic stress.

2. Materials and Methods

2.1. Planting Conditions

In the present study, Lemont rice (Oryza sativa L. subsp. Japonica) and its transgenic lines with Lsi1-RNA interference (Lsi1-RNAi) and overexpression of Lsi1 (Lsi1-OE) were used. Lemont rice was stored in the agricultural processing and safety monitoring main laboratory of Fujian University of Agriculture and Forestry (Fuzhou, China), and the Lsi1 Lemont transgenic lines were germinated in the previous studies. [24]. Seeds of different types of rice, for example, wild Lemont (LE-WT) and Lsi1-OE (LE-OE) and Lsi1-RNAi (LE-R) lines, were prepared and disinfected using alcohol and sodium hypochlorite. For germination, the seeds were kept in a damp paper towel in the culture chamber. After one week, the germinated seeds were transferred to pots (2.5 L) containing the culture solution, and the culture solution was prepared, according to Cock, Yoshida [25]. The nutrient solution included: (NH4)2SO4 (48.2 mg L−1), Ca(NO3)2·4H2O (86.43 mg L−1), K2SO4 (14.9 mg L−1), Na2SiO4·9H2O (200 mg L−1), KNO3 (18.5 mg L−1), FeSO4·7H2O (45.7 mg L−1), H3BO3 (1.43 mg L−1), EDTA (48.44 mg L−1), CuSO4·5H2O (0.04 mg L−1), KH2PO4 (24.8 mg L−1), MnCl2·4H2O (0.905 mg L−1), Na2MoO4·2H2O (0.045 mg L−1), ZnSO4·7H2O (0.11 mg L−1), and MgSO4·7H2O (135.06 mg L−1). The acidity of the pot solution was adjusted daily to pH 5.8, and, at the end of each week, the pot solution was replaced.
Treatments began when the rice seedlings had three leaves. In a complete factorial design, we exposed the seedlings to two Si levels (Na2SiO3·9H2O) (0 and 0.70 mM) and two As (III) levels (NaAsO2) (0 and 30 μM). Thus, we had four different treatments: control (I), 0.70 mM Si (II), 30 μM As (III), 30 μM As + 0.70 mM Si (IV). NaCl equivalent was added to the solution to compensate for the sodium amount added to the culture medium in the form of Na2SiO4·9H2O. The experiment was conducted in a completely randomized design with three replications, and random rice samples were selected one and two weeks after the start of treatment. The roots and shoots were cleaned in distilled water, and the remaining residue in the root zone was washed with distilled water in 0.5 mM CaCl2 solution for 30 min. After washing, all samples were transferred to the freezer at −10 °C and stored until enzyme activities were determined.
For Transcriptomic analyses and quantitative RT-PCR, rice seedlings containing three leaves were treated with 30 μM As + 0.70 mM Si for three days. After three days, all seedlings were harvested, and the shoots and roots were separated, instantly immersed in liquid nitrogen, and stored rapidly at -80 °C. In this experiment, we used LE-WT as CK and LE-OE and LE-R as treatments.

2.2. As Concentration Measurement

We used the method of Meharg and Jardine [26] for determining As concentration in rice samples. To each 0.2 g of dry samples, 1 mL of condensed nitric acid was added. After the mixture had been stored at room temperature for 24 h, 1 mL of oxygenated water was added. Subsequently, the test tubes were placed at 70 °C for half an hour. Then they were transferred to a temperature of 100 °C for one hour until all nitric acid from the samples had vaporized. After cooling, the obtained solution was filtered, and distilled water was added until the volume reached 50 mL. Then, 10% chloric acid (5 mL), 10% potassium iodide (10 mL), and 5% ascorbic acid (5 mL) were added to 1 mL of the diluted solution of each sample. Arsenic concentration was finally measured using atomic absorption spectrometry (Shimadzu 6200) with a hydride production apparatus (FIG 6200).

2.3. Si Concentration and Dry Weight Measurement

The samples were ground and put into an oven at 70 °C for two days. Then, dry samples (0.5 g) were microwave-digested in the mixture of 62% HNO3 (3 mL), 30% H2O2 (3 mL), and 46% HF (2 mL). The digested samples were diluted with boric acid (4%) to 100 mL. We used a colorimetric molybdenum blue method to measure Si concentration in the digest solution [27]. To sample (0.2 mL) H2O (2.7 mL), by10% (NH4)6 Mo7O2 (0.2 mL), 0.2% NaCl (1.5 mL), 20% tartaric acid (0.2 mL), and then reduced agent (0.2 mL) were added. We prepared a reducing agent by dissolving 1-amino-2-naphthol- 4-sulfonic acid (0.5 g), Na2SO3 (1 g), and NaHSO3 (30 g) in the water (200 mL). We measured the absorbance at 600 nm after 1 h. A series of Na2SiO3 solutions along a concentration gradient was used to create the standard curve.

2.4. Soluble Protein Contents Measurement

The amount of total soluble protein was measured using the Bradford [28] method. Samples of plant material are powdered with liquid nitrogen using precooled mortars and pestles. Each sample supernatant and working standard solution were transferred to assay tubes. A blank containing 20 µL extraction buffer was also prepared. The supernatants (20 µL) were mixed with 1 mL of Bradford solution. An amount of 100 mg Coomassie Brilliant Blue G-250 in 50 mL 95% ethanol was dissolved and 100 mL 85% (w/v) phosphoric acid added. Once the dye had completely dissolved, it was diluted to 1 L with deionized water and, in five minutes, the mixture absorbance was measured at 595. The protein amount was quantified by placing the number onto the standard curve.

2.5. Transcriptomic Analyses

Total RNA was extracted from rice roots by using TRIzol (Invitrogen) according to the manufacturer’s instructions [29]. RNA quality was measured on an Agilent 2100 Bioanalyzer system (Agilent Technologies, Santa Clara, CA, USA). Total RNA (0.75 μg) from each test sample was treated with oligo (dT) beads to enrich mRNA and fragmented using fragmentation buffer (New England Biolabs Ltd., Hitchin, UK). mRNA was reverse-transcribed into cDNA using random hexamers, and double-stranded cDNA (ds cDNA) was synthesized and purified. After filling in the cohesive ends to yield blunt ends, ds cDNA was combined with poly (A) and ligated to Illumina sequencing adapters (Illumina Inc., San Diego, CA, USA). The ligation products were size-selected by AMpure XP beads (Beckman Coulter Life Science) and amplified by PCR, and cDNA libraries were sequenced on an Illumina Hiseq PE150 at Allwegene Tech. (China). Differential expression analysis (DEG) was done by using the DESeq R (1.10.1) package. To check the false discovery rate (FDR), we obtained the p-values via Benjamini and Hochberg’s method. Significant false genes were detected by values < 0.05 [30]. For GO (gene ontology) enrichment analysis, a single enrichment analysis tool (SEA) was done on The Viral Proteomic Tree Server (ViPTree), with default parameters set, and an adjusted FDR threshold was set to p < 0.05.

2.6. Quantitative RT-PCR

RNA was extracted from the roots using the Trizol method with slight modification [29]. We used one µg total RNA for the first-strand cDNA synthesis, according to the instructions of the TransScript One-Step gDNA Removal and cDNA Synthesis SuperMix manufacturer (TransGen Biotech Co., Ltd. Beijing, China). Relative levels of GST-related genes were increased rice plant resistance to arsenic stress, and they were determined through quantitative RT-PCR in three replications. The sequences of primer are specified in Table 1.
Actin-1(Os03g0718100) was used as a reference gene. The primers and probes are designed for Quantitative RT-PCR analysis by using online tools at https://biodb.swu.edu.cn/qprimerdb/. The quantitative RT-PCR reaction system was prepared using TransStart Tip Green qPCR SuperMix and an Eppendorf realplex4 instrument. The reaction process was as follows: predenaturation at 94 °C for 30 s, denaturation at 94 °C for 5 s, annealing at 53 °C for 15 s, extension at 72 °C for 10 s; 42 cycles. When the amplification was finished, the melting curve analysis was conducted, and the specificity of the product was determined based on the melting curve (Figure 1 and Figure 2). Each candidate mRNA was set with four independent replicates. The relative expression of the gene was calculated by the 2△△Ct method with the threshold cycle values (Ct) of each candidate mRNA in both the control and test samples [31].

2.7. Statistical Analyses

This experiment was organized in a completely randomized factorial design and three replications. Total determination was statistically analyzed using one-way ANOVA with pairwise LSD. tests (p ≤ 0.05). Analysis was conducted using SPSS 26.0 software (IBM Corp., Armonk, NY, USA).

3. Results

3.1. The Role of Si and As Treatments on As Concentration of Rice Shoots and Roots

Data analysis showed a significant interaction between As × Si × lines in rice under different treatments (Table 2). When we increased As in the culture medium, the accumulations of arsenic in different rice tissues increased, and the results showed more As in roots than shoots of different rice (Figure 3A,B). Arsenic treatment significantly increased As concentration (p ≤ 0.05) in rice shoots compared to CK The highest increase was seen in LE-WT shoots in the first and second weeks (30 μM As), with 5.29 mg kg−1 DW and 9.72 mg kg−1 DW, As concentration, respectively. The concentration of As in different seedlings treated with Si was 0 mg kg−1 DW in both weeks. As + Si treatment was decreased As concentration in different rice shoots compared to As treatment only; and the most considerable decrease saw in LE-OE shoots in both weeks (2.32 mg kg−1 DW, and 2.37 mg kg−1 DW, respectively) (Figure 3A).
By adding As to the culture solution, the concentration of root arsenic increased compared to CK (p ≤ 0.05), the highest As concentration was observed in LE-WT roots in the first week, but in LE-R roots in the second weeks (Figure 3B). The highest concentrations of arsenic in the first and second weeks were 256.8 mg kg−1 DW and 376.08 mg kg−1 DW. The arsenic concentration of Si-treated roots was 0 mg kg−1 DW every two weeks. As concentration in rice seedlings treated with As + Si decreased compared to As only exposure, the lowest arsenic concentration was observed in the first and second weeks in LE-WT roots, 48.41 mg kg−1 DW and 67.98 mg kg−1 DW, respectively.

3.2. The Role of Si and As Treatments on Si Concentration of Rice Shoots and Roots

Figure 4 determined Si concentration in the shoots and roots of three rice lines under different treatments and also showed the Lsi1 gene increase the capacity of different tissues for further Si accumulation.
Adding Si only to the culture medium increased Si concentration in the first and second weeks after treatment, and the highest Si concentration was seen in LE-OE line shoots. Si concentration in LE-OE shoots increased by 61.98% in the first week after treatment but was 58.43% higher than CK in the second week (p ≤ 0.05).
One and two weeks after As treatments, the concentration of Si in rice seedlings was significantly different compared with CK (p ≤ 0.05). The lowest Si concentration was seen in LE-R in the first and second weeks, which showed a decrease of 87.93% and 85.08%, respectively, compared to the control. Si concentration in seedlings treated with both As and Si was higher than seedlings treated with As alone. The highest Si concentration was observed in shoots of LE-OE in the first and second weeks, showing a 4.07% and 2.45% increase compared to the control (p ≤ 0.05), respectively (Figure 4A).
Si concentration decreased compared to control after adding As to the culture medium, and the lowest concentration of Si was observed in the first and second weeks in LE-R roots (Figure 4B). This decrease in Si concentration was 59.45% and 67.60% compared to CK (p ≤ 0.05). Rice seedlings treated with Si showed increased Si concentration, and the greatest Si concentration was observed in LE-OE roots every two weeks, with a 54.62% and 56.16% increase compared to CK (p ≤ 0.05), respectively. Si concentration in seedlings treated with As + Si was significantly different from CK, and the lowest Si concentration, both in the first and second weeks, was observed in LE-R line roots, with 2.40% and 2.9% decreases compared to CK (p ≤ 0.05), respectively.

3.3. The Role of Si and As Treatments on Dry Weight of Rice Shoots and Roots

The present study on different treatments showed that the addition of As treatment can significantly reduce the dry weight of different rice roots and shoots every two weeks, and the LE-WT line showed a more considerable decrease in dry weight than LE-OE and LE-R, but the dry weight in the LE-OE line increased further with the addition of different Si treatments. For example, when we added Si, the dry weight of shoots and roots increased in the first and second weeks, and the dry weight was 1.508, 1.912 mg and 0.538, 0.613 mg, respectively, but in the LE-WT line was 1.139, 1.56 mg, and 0.429, 0.497 mg, respectively. Under 30 μM As the same results have been shown in the shoots and roots of LE-WT, LE-R, and LE-OE (Figure 5A,B; Table 2), when we added As the tolerance of LE-OE and LE-R lines in the presence of Si was higher than LE-WT. Silicon treatments can reduce arsenic uptake, and translocation in roots and shoots indicates the role of the Lsi1 gene in increasing antagonism between As and Si in rice.

3.4. The Role of Si and As Treatments on Soluble Protein Contents of Rice Shoots and Roots

Soluble protein content was significantly increased on the seedlings treated with Si, and in both weeks, the highest amount was observed in the LE-OE shoots with a 10.01% and 11.34% increase, compared with CK (p ≤ 0.05), respectively. Compared to the control, soluble protein contents decreased after adding As to the culture solution (p ≤ 0.05), and the lowest amount was observed in shoots of LE-WT in the first and second weeks. These decreases were 22.80% and 12.34% compared to CK, respectively (Figure 6A). The soluble protein contents of As + Si treated rice decreased compared to CK (p ≤ 0.05), and the lowest soluble protein contents were seen in the LE-WT shoots in the first and second weeks (11.25% and 6.66% reduction, respectively).
Si treatment showed a significant difference in soluble protein contents in different rice roots compared to CK (p ≤ 0.05), and the highest increase in the first and second weeks after exposing to Si treatment was observed in LE-R roots, which represented 22.03% and 7.31% increase compared to CK, respectively. Our results also showed that soluble protein contents in different rice lines roots decreased compared to CK at the time of arsenic exposure (p ≤ 0.05). The most considerable decrease was observed in LE-WT roots, both with 47.42% and 44.15% decrease compared to CK in the first and second weeks, respectively (Figure 6B). Decreased soluble protein content was also observed in the roots of seedlings treated with As + Si in both exposure periods. The most significant decrease was in LE-WT roots in the first and second weeks, representing 37.92% and 29.32% decreased compared to CK.

3.5. Transcriptomic Analyses

To gain global insight, we used Illumina high-throughput sequencing related to the role of As and Si on Oxidative enzymes and non-oxidative enzymes, the seedlings of rice treated with 30 μM As + 0.70 mM Si. Three biological replicates were designed, and Pearson’s correlation. The coefficient was calculated to evaluate their reproducibility. By using DESeq, the DEGs were known between the CKs and treatments. Differentially expressed genes (down-regulated and up-regulated genes) are in Figure 7.
The list of background queries comprised 106 genes for the LE-OE line and 449 genes for the LE-R line (Figure 7A,B). However, the amount of up-regulated genes was 75 and 190, respectively. We used ViPTree to classify GO on expressed genes to understand the function of As-affected genes and GO enrichment terms of the cellular component, biological process, and molecular function categories. In the biological process classification (GO: 0008150), the enriched DEGs were mainly associated with the metabolic process (GO: 0008152), and in the molecular function classification (GO: 0008150), differentially expressed genes enrichment was mainly related to the metabolic process (GO: 0008152) and catalytic activity (GO: 0003824). In the cellular component classification (GO: 0005575), enriched differentially expressed genes were mainly associated with the cell (GO: 0005623) and cell part (GO: 0044464) (Figure 8).
Among the differentially expressed genes of the LE-OE line and LE-R lines 31 and 259, annotated down-regulated genes were identified. GO enrichment terms of the biological process and molecular function categories. Biological process classification (GO: 0008150), enriched differential expressed genes were mainly associated with the cellular process (GO: 0009987), metabolic process (GO: 0008152), and response to the stimulus (GO: 0050896), but in molecular function (GO: 0003674) enriched differentially expressed genes were mainly associated with the nutrient reservoir activity (GO: 0045735), catalytic activity (GO: 0003824) and binding (GO: 0005488) (Figure 8).
KEGG enrichment analysis showed that in LE-OE line roots, DEGs in plant hormone signal transduction included four genes, three down-regulated and one up-regulated, DEGs in metabolic pathways included six genes, five up-regulated and one down-regulated. Differentially expressed genes in starch and sucrose metabolism included two genes, two up-regulated and zero down-regulated. DEGs in Biosynthesis of secondary metabolites included two genes, two up-regulated and zero down-regulated (Figure 9), and in LE-R roots, DEGs are enriched in plant hormone signal transduction including seven genes, one up-regulated and six down-regulated. DEGs in metabolic pathways contained 35 genes, 21 down-regulated and 14 up-regulated. Differentially expressed genes in Biosynthesis of secondary metabolites included 24 genes, 10 up-regulated and 14 down-regulated. DEGs in glutathione metabolism included six genes, one up-regulated and five down-regulated. It has been observed that the factors that cause rice resistance to As are regulated by the expression patterns of these genes (Figure 9).

3.6. Expression of Some Genes in Different Varieties of Rice Exposed to Si and As Treatments

Calcium-binding EGF domain-containing protein (LOC_Os10g10130) regulates calcium ion binding and ATP binding in rice. LOC_Os10g10130 expression in LE-OE and LE-R lines was highly up-regulated (Figure 10A) in the presence of 30 μM As + 0.70 mM Si. Si and As increased the relative mRNA of LOC_Os10g10130 in LE-OE and LE-R lines compare to CK (15.40-fold and 29.44-fold, respectively).
The effect of 30 μM As + 0.70 mM Si treatment on ATG8D expression in LE-R line was slightly down-regulated, 0.73-fold, respectively (Figure 10B). However, using qRT-PCR observed that ATG8D expression in the LE-OE line was up-regulated compared to CK (1.13-fold). ATG8D gene regulates the cellular response to nitrogen starvation, Protein transport, transport, and Ubl conjugation pathway in rice.
By using Quantitative RT-PCR, the mRNA expressions of Os10g0530500 that regulates glutathione transferase activity in rice were investigated under 30 μM As + 0.70 mM Si treatments. The results showed that the expression of Os10g0530500 in LE-OE and LE-R lines was up-regulated compared to CK, which was 1.63-fold and 4.33-fold, respectively (Figure 10C).
The relative mRNAs of Os05g0240200 (regulates Plant defense, ADP binding, glutathione transferase activity) in LE-OE and LE-R lines were highly up-regulated compared to CK (1.90-fold and 1.79-fold, respectively) in 30 μM As + 0.70 mM Si treatments (Figure 10D).
Os02g0685200 expression in LE-OE line was highly up-regulated (Figure 10E), Si, and As increased the relative mRNA of Os02g0685200 compared to CK (15.40 fold), but it was slightly down-regulated in LE-R (0.0001 fold), in the attendance of 30 μM As + 0.70 mM Si.
Os08g0522400 regulates peroxidase activity and oxidative stress in rice. Os08g0522400 expression in the presence of 30 μM As + 0.70 mM Si in LE-OE line was increased (Figure 10F), but Os08g0522400 expression in LE-R line was slightly down-regulated (0.45-fold).
The effect of 30 μM As + 0.70 mM Si treatment on GSTU1, Os01g0369700, and GSTZ5 expression in LE-OE and LE-R lines were slightly down-regulated (Figure 10G–I).

4. Discussion

The present study compared arsenic and silicon antagonism on the physiological and molecular properties of Lsi1 transgenic and wild-type Lemont rice lines. Lsi1 is a capable transporter found mainly in cells of mature plant root regions and affects the accumulation of As (III) and Si in plant tissues [20,32]. Research has shown that Lsi1-inhibitor or Lsi1-overexpressing transgenic rice is more resistant to cadmium toxicity in the presence of silicon. The increase in cadmium stress resistance depends not only on the amount of Si in the culture medium but also on the expression of Lsi1 in plants. [33].
Si is very valuable for plant growth, especially in stressful conditions [34], and this is an essential element in plants to reduce the toxicity of various metals such as Zn, As, and Cd. It can also reduce the absorption and transport of metals in plants, especially rice. Many studies have reported that Si application improves the tolerance of toxic metals in various plants, which reduces the absorption of heavy metals in the roots and their transfer to the shoots, and ultimately their toxicity in plant tissues [14,35]. It should be noted that research on Indica rice has also shown that Lsi1 plays a key role in Si accumulation in transgenic rice lines. [36]. According to research, Si and As have the same transport routes in rice [20], and Si application reduced its adsorption due to direct competition between Si and As during adsorption [20,37].
Similar research has shown that the use of Si reduces the concentration of As in various organs of rice plants such as straw, stamen, and leaves by half [13,14]. Additionally, the phenotypic difference of rice causes Si accumulation in different organs to be different [38], and these results are similar to our experiment.
Some studies have shown that various rice genotypes have different potential for As uptake and accumulation, and adding the same level of As to different rice genotypes causes the different As accumulation [3,16]. Similar greenhouse experiments also showed changes in As content in pots and made a significant difference in As accumulation of different types of rice and different parts of plants [2]. Studies have also shown that suppression of the Lsi1 gene reduces arsenic accumulation in rice roots and shoots [39], and similar results were found in our study.
The role of different stresses on the amount of soluble protein has been investigated less than antioxidant enzymes. In this study, the addition of Si solution to As significantly increased the soluble protein content of different rice strains compared to arsenic treatment alone. It suggests that Si plays a vital role in neutralizing ROS toxicity, reducing excessive stress, and ultimately reducing oxidative damage, reducing protein degradation, improving protein synthesis, and increasing protein metabolism under stress [40,41]. These results are consistent with other research observations that show the effect of Si on increasing soluble protein in plants under stress, which is also dependent on Si concentration [42,43]. This study found that the soluble protein of rice seedlings treated with As was reduced, indicating that damaged seedlings and protein metabolism were disrupted by arsenic stress. Decreases in the soluble protein levels may be due to the following reasons: As reacts with sulfhydryl groups of proteins that cause the damage in rice tissues, potent inhibition of rice growth and photosynthetic activity, more oxidative damage, which inhibits protein synthesis, increases the rate of destruction by disrupting the membrane system, reduces the level of As (V) to As (Ⅲ) in cells responsible for protein damage via oxidation of thiol groups [41,42]. Decreased protein content in rice and other plants under various stresses has been observed [40,43,44].
The effects of the Lsi1 gene are not completely limited to increasing Si in roots and shoots of Lsi1 transgenic rice lines, but different studies in hydroponic and in vitro conditions have shown that adding Si to the culture medium significantly increased the root and shoot dry weight and fresh weight, root length, chlorophyll content of Lsi1 transgenic rice lines more than their wild type [32,36].
Heavy metal pollution is an increasing environmental problem, which is very toxic and dangerous to plants. Much research has been done to establish the molecular, physiological, and genetic basis of As tolerance in plants [22]. However, uptake, transport, and accumulation mechanism of As in plants and the transcriptional regulation of this process is unknown. Therefore, there is an urgent need to address these questions significantly when As is growing in the rice mediums and abundant in different parts of rice [37]. Prior studies used microarray techniques to check the transcriptional response regulation of As stress in the plant. The Illumina sequencing approach has also been used to determine many differentially expressed genes [22]. We tried to investigate genes and mechanisms related to arsenic stress through GO (gene ontology) enrichment analysis in this experiment. The present study tried to examine arsenic stress on DEGs in different pathways in rice roots. These pathways included glutathione metabolism, biosynthesis of amino acids, RNA degradation, biosynthesis of secondary metabolites, plant hormone signal transduction, metabolic pathways, etc. Different studies have also emphasized the effect of these mechanisms in reducing arsenic stress [22,37].
Our study investigated the differences in susceptibility among three different rice cultivars to As. This study also tried to determine GST genes and other antioxidative enzyme genes’ effect on reducing arsenic contamination. The number of genes related to glutathione S-transferase (GST) was significantly increased. These intracellular proteins (GST) are found in prokaryotes, eukaryotes, and aerobics, supporting cells against other chemical toxicity [45].
GSTs are the essential enzymatic systems for phase II metabolism, which enter the plant system as the primary system of exogenous chemical metabolizing enzymes. GSTs detoxify heavy metals and herbicides by catalyzing their binding to glutathione [46]. GST genes had different expressions in different varieties, which indicates that different GST genes have different expressions in several varieties under stress conditions. These results align with studies on other plants and under different stresses [47,48].
As ROS due to abiotic stresses was increased, the related genes’ expression also grew to improve the plant defence situation [49]. The decrease and increase in antioxidative enzymes due to different stress cause the decrease and increase in H2O2 in the plants; thus, it induces antioxidant-related gene expression. These genes’ expression is also different in diverse lines of a plant [50]. In our study, the genes related to antioxidative enzymes also showed similar results.
Rice is known as an efficient Si collector among all crops. It has been reported that exposure to Si contributes to the plant’s growth under metal stress, such as As. Different studies have been conducted to clarify the role of Si in reducing heavy metal toxicity at the gene level. The Si-mediated mechanisms in reducing heavy metal toxicity are not understood at the molecular and genetic levels. Still, they have shown that Si application in rice treated with heavy metals significantly activated some genes [51,52]. The plant cells have different transporters, facilitating arsenic uptake and accumulation and other elements present in the plants. These include ATP binding cassette transporter, aquaglyceroporins, phosphate transporters, and nitrogen transporters [53]. It is essential to decrease unwanted elements such as heavy metals by regulating these necessary transporters, which reduces the toxic elements in the plant [54]. The present study showed that gene expression involved in elemental transport was up-regulated when some lines were exposed to Si and As.

5. Conclusions

The experiment compared wild-type rice with its transgenic lines, and it has shown a direct relationship between the concentration of As and Si in the culture medium and their accumulation in rice. Moreover, increasing Si had an active role in reducing arsenic stress, and this effect was more significant in the LE-OE line than in other varieties. The study also showed that adding As to the culture medium in all lines reduced the soluble protein in both root and shoot, which the highest decrease in soluble protein was observed in LE-WT. However, adding Si has gained the soluble protein in all rice and reduced the effect of arsenic on soluble protein in the shoots and roots. Gene ontology (GO) enrichment analysis of roots treated by As and Si showed 106 DEGs in the LE-OE line and 449 DEGs in the LE-R line, and the different genes expressed were belonged to different gene families indicating the complex mechanism of rice to respond to arsenic stress conditions.
The study results showed that the genes that had a role in antioxidant enzymes and element transport in rice were up-regulated, and this highlights the significant role of these genes in reducing arsenic contamination in transgenic Lemont rice lines. Therefore, we suggest that future experiments focus on the effect of different levels of Si and As on gene expression. Since transgenic rice is more resistant to arsenic toxicity in the presence of silicon, planting transgenic rice on farms can improve yield and food safety. In addition, if Si fertilizers are added to the culture medium, the best option for rice cultivation is the LE-OE line because it has low As accumulation and high soluble protein.

Author Contributions

M.R.B., W.L., C.F. designed the experiment. M.R.B. and Y.J. performed most of the experiments. M.R.B. analyzed data and wrote the manuscript. W.L. and C.F. edited the manuscript. All authors read and agreed to the published version of the manuscript.

Funding

This work was supported by the Outstanding Youth Scientific Fund of Fujian Agriculture and Forestry University (Grant No. xjq201805). The funders had no role in study design, data collection, analysis, data interpretation, or manuscript writing.

Institutional Review Board Statement

Not applicable.

Informed Consent Statement

Not applicable.

Data Availability Statement

All data generated during this study are included in this published article and its supplementary information files, and the raw data used or analyzed during the current study are available from the corresponding author on reasonable request.

Acknowledgments

We thank Gabor Pozsgai and Jiang Yuhang for their constructive comments and suggestions to complete this paper.

Conflicts of Interest

The authors declare that they have no competing interest.

References

  1. Bhattacharya, S.; Gupta, K.; Debnath, S.; Ghosh, U.C.; Chattopadhyay, D.; Mukhopadhyay, A. Arsenic bioaccumulation in rice and edible plants and subsequent transmission through food chain in Bengal basin: A review of the perspectives for environmental health. Toxicol. Environ. Chem. 2012, 94, 429–441. [Google Scholar] [CrossRef]
  2. Bhattacharya, P.; Samal, A.C.; Majumdar, J.; Banerjee, S.; Santra, S.C. In Vitro assessment on the impact of soil arsenic in the eight rice varieties of West Bengal, India. J. Hazard. Mater. 2013, 262, 1091–1097. [Google Scholar] [CrossRef]
  3. Bhattacharya, P.; Samal, A.C.; Majumdar, J.; Santra, S.C. Uptake of arsenic in rice plant varieties cultivated with arsenic rich groundwater. Environ. Asia 2010, 3, 34–37. [Google Scholar]
  4. Chen, C.-L.; Chiou, H.-Y.; Hsu, L.-I.; Hsueh, Y.-M.; Wu, M.-M.; Chen, C.-J. Ingested arsenic, characteristics of well water consumption and risk of different histological types of lung cancer in northeastern Taiwan. Environ. Res. 2010, 110, 455–462. [Google Scholar] [CrossRef] [PubMed]
  5. Sanaei, G. Industrial Toxicology; Tehran University Press: Tehran, Iran, 2004; Volume I. [Google Scholar]
  6. Richmond, K.E.; Sussman, M. Got silicon? The non-essential beneficial plant nutrient. Curr. Opin. Plant Biol. 2003, 6, 268–272. [Google Scholar] [CrossRef]
  7. Song, Z.; Wang, H.; Strong, P.J.; Shan, S. Increase of available soil silicon by Si-rich manure for sustainable rice production. Agron. Sustain. Dev. 2014, 34, 813–819. [Google Scholar] [CrossRef] [Green Version]
  8. Cuong, T.X.; Ullah, H.; Datta, A.; Hanh, T.C. Effects of silicon-based fertilizer on growth, yield and nutrient uptake of rice in tropical zone of Vietnam. Rice Sci. 2017, 24, 283–290. [Google Scholar] [CrossRef]
  9. He, C.; Ma, J.; Wang, L. A hemicellulose-bound form of silicon with potential to improve the mechanical properties and regeneration of the cell wall of rice. New Phytol. 2015, 206, 1051–1062. [Google Scholar] [CrossRef] [PubMed]
  10. You-Qiang, F.; Hong, S.; Dao-Ming, W.; Kun-Zheng, C. Silicon-mediated amelioration of Fe2+ toxicity in rice (Oryza sativa L.) roots. Pedosphere 2012, 22, 795–802. [Google Scholar]
  11. Hoogenkamp, H.; Kumagai, H.; Wanasundara, J. Rice protein and rice protein products. In Sustainable Protein Sources; Elsevier: Amsterdam, The Netherlands, 2017; pp. 47–65. [Google Scholar]
  12. Kim, Y.-H.; Khan, A.L.; Shinwari, Z.K.; Kim, D.-H.; Waqas, M.; Kamran, M.; Lee, I.-J. Silicon treatment to rice (Oryza sativa L. cv.‘Gopumbyeo’) plants during different growth periods and its effects on growth and grain yield. Pak. J. Bot. 2012, 44, 891–897. [Google Scholar]
  13. Seyfferth, A.L.; Fendorf, S. Silicate mineral impacts on the uptake and storage of arsenic and plant nutrients in rice (Oryza sativa L.). Environ. Sci. Technol. 2012, 46, 13176–13183. [Google Scholar] [CrossRef] [PubMed]
  14. Fleck, A.T.; Mattusch, J.; Schenk, M.K. Silicon decreases the arsenic level in rice grain by limiting arsenite transport. J. Plant. Nutrition. 2013, 176, 785–794. [Google Scholar] [CrossRef]
  15. Ali, W.; Isayenkov, S.V.; Zhao, F.-J.; Maathuis, F.J. Arsenite transport in plants. Cell. Mol. Life Sci. 2009, 66, 2329–2339. [Google Scholar] [CrossRef]
  16. Bhattacharya, P. Assessment of Arsenic Accumulation by Different Varieties of Rice (Oryza sativa L.) Irrigated with Arsenic-contaminated Groundwater in West Bengal (India). Environ. Pollut. Prot. 2017, 2, 92–99. [Google Scholar] [CrossRef]
  17. Pinson, S.R.; Tarpley, L.; Yan, W.; Yeater, K.; Lahner, B.; Yakubova, E.; Huang, X.-Y.; Zhang, M.; Guerinot, M.L.; Salt, D.E. Worldwide genetic diversity for mineral element concentrations in rice grain. Crop. Sci. 2015, 55, 294–311. [Google Scholar] [CrossRef]
  18. Rahman, M.A.; Hasegawa, H.; Rahman, M.M.; Rahman, M.A.; Miah, M. Accumulation of arsenic in tissues of rice plant (Oryza sativa L.) and its distribution in fractions of rice grain. Chemosphere 2007, 69, 942–948. [Google Scholar] [CrossRef] [Green Version]
  19. Kumar, N.; Dubey, A.K.; Upadhyay, A.K.; Gautam, A.; Ranjan, R.; Srikishna, S.; Sahu, N.; Behera, S.K.; Mallick, S. GABA accretion reduces Lsi-1 and Lsi-2 gene expressions and modulates physiological responses in Oryza sativa to provide tolerance towards arsenic. Sci. Rep. 2017, 7, 1–11. [Google Scholar] [CrossRef] [Green Version]
  20. Ma, J.F.; Yamaji, N.; Mitani, N.; Xu, X.-Y.; Su, Y.-H.; McGrath, S.P.; Zhao, F.-J. Transporters of arsenite in rice and their role in arsenic accumulation in rice grain. Proc. Natl. Acad. Sci. USA 2008, 105, 9931–9935. [Google Scholar] [CrossRef] [Green Version]
  21. Ranjan, R.; Kumar, N.; Dubey, A.K.; Gautam, A.; Pandey, S.N.; Mallick, S. Diminution of arsenic accumulation in rice seedlings co-cultured with Anabaena sp.: Modulation in the expression of lower silicon transporters, two nitrogen dependent genes and lowering of antioxidants activity. Ecotoxicol. Environ. Saf. 2018, 151, 109–117. [Google Scholar] [CrossRef]
  22. Yu, L.j.; Luo, Y.f.; Liao, B.; Xie, L.j.; Chen, L.; Xiao, S.; Li, J.t.; Hu, S.n.; Shu, W.s. Comparative transcriptome analysis of transporters, phytohormone and lipid metabolism pathways in response to arsenic stress in rice (Oryza sativa). New Phytol. 2012, 195, 97–112. [Google Scholar] [CrossRef]
  23. Hartley-Whitaker, J.; Ainsworth, G.; Meharg, A.A. Copper-and arsenate-induced oxidative stress in Holcus lanatus L. clones with differential sensitivity. Plant Cell Environ. Res. 2001, 24, 713–722. [Google Scholar] [CrossRef]
  24. Fang, C.-X.; Wang, Q.-S.; Yu, Y.; Li, Q.-M.; Zhang, H.-L.; Wu, X.-C.; Chen, T.; Lin, W.-X. Suppression and overexpression of Lsi1 induce differential gene expression in rice under ultraviolet radiation. Plant Growth Regul. 2011, 65, 1–10. [Google Scholar] [CrossRef]
  25. Cock, J.; Yoshida, S.; Forno, D.A. Laboratory Manual for Physiological Studies of Rice. Int. Rice Res. Inst. 1976. [Google Scholar]
  26. Meharg, A.A.; Jardine, L. Arsenite transport into paddy rice (Oryza sativa) roots. New Phytol. 2003, 157, 39–44. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  27. Hallmark, C.; Wilding, L.; Smeck, N. Silicon. Methods of Soil Analysis: Part. 2 Chemical Microbiological Properties; John Wiley & Sons: Hoboken, NJ, USA, 1983; Volume 9, pp. 263–273. [Google Scholar]
  28. Bradford, M.M. A rapid and sensitive method for the quantitation of microgram quantities of protein utilizing the principle of protein-dye binding. Anal. Biochem. 1976, 72, 248–254. [Google Scholar] [CrossRef]
  29. Chomczynski, P.; Mackey, K. Short technical reports. Modification of the TRI reagent procedure for isolation of RNA from polysaccharide-and proteoglycan-rich sources. Biotechniques 1995, 19, 942–945. [Google Scholar] [PubMed]
  30. Wang, L.; Feng, Z.; Wang, X.; Wang, X.; Zhang, X. DEGseq: An R package for identifying differentially expressed genes from RNA-seq data. Bioinformatics 2010, 26, 136–138. [Google Scholar] [CrossRef] [PubMed]
  31. Livak, K.J.; Schmittgen, T.D. Analysis of relative gene expression data using real-time quantitative PCR and the 2− ΔΔCT method. Methods 2001, 25, 402–408. [Google Scholar] [CrossRef] [PubMed]
  32. Lin, Y.; Sun, Z.; Li, Z.; Xue, R.; Cui, W.; Sun, S.; Liu, T.; Zeng, R.; Song, Y. Deficiency in silicon transporter Lsi1 compromises inducibility of anti-herbivore defense in rice plants. Front. Plant Sci. 2019, 10, 652. [Google Scholar] [CrossRef] [Green Version]
  33. Lin, H.; Fang, C.; Li, Y.; Lin, W.; He, J.; Lin, R.; Lin, W. Cadmium-stress mitigation through gene expression of rice and silicon addition. Plant Growth Regul. 2017, 81, 91–101. [Google Scholar] [CrossRef]
  34. Liang, Y.; Wong, J.; Wei, L. Silicon-mediated enhancement of cadmium tolerance in maize (Zea mays L.) grown in cadmium contaminated soil. Chemosphere 2005, 58, 475–483. [Google Scholar] [CrossRef]
  35. Wang, H.-Y.; Wen, S.-L.; Chen, P.; Zhang, L.; Cen, K.; Sun, G.-X. Mitigation of cadmium and arsenic in rice grain by applying different silicon fertilizers in contaminated fields. Environ. Sci. Pollut. Res. 2016, 23, 3781–3788. [Google Scholar] [CrossRef]
  36. Sahebi, M.; Hanafi, M.M.; Rafii, M.; Azizi, P.; Abiri, R.; Kalhori, N.; Atabaki, N. Screening and expression of a silicon transporter gene (Lsi1) in wild-type indica rice cultivars. BioMed Res. Int. 2017, 2017. [Google Scholar] [CrossRef] [Green Version]
  37. Tripathi, P.; Tripathi, R.D.; Singh, R.P.; Dwivedi, S.; Goutam, D.; Shri, M.; Trivedi, P.K.; Chakrabarty, D. Silicon mediates arsenic tolerance in rice (Oryza sativa L.) through lowering of arsenic uptake and improved antioxidant defence system. Ecol. Eng. 2013, 52, 96–103. [Google Scholar] [CrossRef]
  38. Ma, J.F.; Yamaji, N.; Tamai, K.; Mitani, N. Genotypic difference in silicon uptake and expression of silicon transporter genes in rice. Plant Physiol. 2007, 145, 919–924. [Google Scholar] [CrossRef] [Green Version]
  39. Dubey, A.K.; Kumar, N.; Ranjan, R.; Gautam, A.; Pande, V.; Sanyal, I.; Mallick, S. Application of glycine reduces arsenic accumulation and toxicity in Oryza sativa L. by reducing the expression of silicon transporter genes. Ecotoxicol. Environ. Saf. 2018, 148, 410–417. [Google Scholar] [CrossRef]
  40. Ashfaque, F.; Inam, A.; Iqbal, S.; Sahay, S. Response of silicon on metal accumulation, photosynthetic inhibition and oxidative stress in chromium-induced mustard (Brassica juncea L.). South Afr. J. Bot. 2017, 111, 153–160. [Google Scholar] [CrossRef]
  41. Zhen, S.; van Iersel, M.W. Far-red light is needed for efficient photochemistry and photosynthesis. J. Plant Physiol. 2017, 209, 115–122. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  42. Geng, A.; Wang, X.; Wu, L.; Wang, F.; Wu, Z.; Yang, H.; Chen, Y.; Wen, D.; Liu, X. Silicon improves growth and alleviates oxidative stress in rice seedlings (Oryza sativa L.) by strengthening antioxidant defense and enhancing protein metabolism under arsanilic acid exposure. Ecotoxicol. Environ. Saf. 2018, 158, 266–273. [Google Scholar] [CrossRef] [PubMed]
  43. Bharwana, S.; Ali, S.; Farooq, M.; Iqbal, N.; Abbas, F.; Ahmad, M. Alleviation of lead toxicity by silicon is related to elevated photosynthesis, antioxidant enzymes suppressed lead uptake and oxidative stress in cotton. Bioremed. Biodeg. 2013, 4, 187. [Google Scholar]
  44. Farooq, M.A.; Ali, S.; Hameed, A.; Ishaque, W.; Mahmood, K.; Iqbal, Z. Alleviation of cadmium toxicity by silicon is related to elevated photosynthesis, antioxidant enzymes; suppressed cadmium uptake and oxidative stress in cotton. Ecotoxicol. Environ. Saf. 2013, 96, 242–249. [Google Scholar] [CrossRef] [PubMed]
  45. Dirr, H.; Reinemer, P.; Huber, R. X-ray crystal structures of cytosolic glutathione S-transferases: Implications for protein architecture, substrate recognition and catalytic function. Eur. J. Biochem. 1994, 220, 645–661. [Google Scholar] [CrossRef] [PubMed]
  46. Li, G.; Wu, S.; Yu, R.; Cang, T.; Chen, L.; Zhao, X.; Cai, L.; Wu, C. Identification and expression pattern of ag lutathione S-transferase in E chinochloa crus-galli. Weed Res. 2013, 53, 314–321. [Google Scholar] [CrossRef]
  47. Jain, M.; Ghanashyam, C.; Bhattacharjee, A. Comprehensive expression analysis suggests overlapping and specific roles of rice glutathione S-transferase genes during development and stress responses. BMC Genom. 2010, 11, 73. [Google Scholar] [CrossRef] [Green Version]
  48. Wagner, U.; Edwards, R.; Dixon, D.P.; Mauch, F. Probing the diversity of the Arabidopsis glutathione S-transferase gene family. Plant Mol. Biol. 2002, 49, 515–532. [Google Scholar] [CrossRef] [PubMed]
  49. Nounjan, N.; Nghia, P.T.; Theerakulpisut, P. Exogenous proline and trehalose promote recovery of rice seedlings from salt-stress and differentially modulate antioxidant enzymes and expression of related genes. J. Plant Physiol. 2012, 169, 596–604. [Google Scholar] [CrossRef]
  50. Radyukina, N.; Shashukova, A.; Makarova, S.; Kuznetsov, V.V. Exogenous proline modifies differential expression of superoxide dismutase genes in UV-B-irradiated Salvia officinalis plants. Russ. J. Plant Physiol. 2011, 58, 51–59. [Google Scholar] [CrossRef]
  51. Kim, Y.-H.; Khan, A.L.; Kim, D.-H.; Lee, S.-Y.; Kim, K.-M.; Waqas, M.; Jung, H.-Y.; Shin, J.-H.; Kim, J.-G.; Lee, I.-J. Silicon mitigates heavy metal stress by regulating P-type heavy metal ATPases, Oryza sativa low silicon genes, and endogenous phytohormones. BMC Plant Biol. 2014, 14, 13. [Google Scholar] [CrossRef] [Green Version]
  52. Meharg, C.; Meharg, A.A. Silicon, the silver bullet for mitigating biotic and abiotic stress, and improving grain quality, in rice? Environ. Exp. Bot. 2015, 120, 8–17. [Google Scholar] [CrossRef] [Green Version]
  53. Bouain, N.; Shahzad, Z.; Rouached, A.; Khan, G.A.; Berthomieu, P.; Abdelly, C.; Poirier, Y.; Rouached, H. Phosphate and zinc transport and signalling in plants: Toward a better understanding of their homeostasis interaction. J. Exp. Bot. 2014, 65, 5725–5741. [Google Scholar] [CrossRef] [Green Version]
  54. Khan, E.; Gupta, M. Arsenic–silicon priming of rice (Oryza sativa L.) seeds influence mineral nutrient uptake and biochemical responses through modulation of Lsi-1, Lsi-2, Lsi-6 and nutrient transporter genes. Sci. Rep. 2018, 8, 1–16. [Google Scholar] [CrossRef] [PubMed] [Green Version]
Figure 1. The melt curve of the amplified fragment of the Actin-1(Os03g0718100) gene.
Figure 1. The melt curve of the amplified fragment of the Actin-1(Os03g0718100) gene.
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Figure 2. Amplification curve of the Actin-1(Os03g0718100) gene.
Figure 2. Amplification curve of the Actin-1(Os03g0718100) gene.
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Figure 3. As concentration in shoots (A) and roots (B) of LE-WT, LE-OE, and LE-R first and second weeks after adding different treatments. The different letters on the bars significantly showed differences (p ≤ 0.05) between treatments, respectively (DW: dry weight).
Figure 3. As concentration in shoots (A) and roots (B) of LE-WT, LE-OE, and LE-R first and second weeks after adding different treatments. The different letters on the bars significantly showed differences (p ≤ 0.05) between treatments, respectively (DW: dry weight).
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Figure 4. Si concentration in shoots (A) and roots (B) of LE-WT, LE-OE, and LE-R first and second weeks after adding different treatments. The different letters significantly showed differences (p ≤ 0.05) between treatments, respectively (DW: dry weight).
Figure 4. Si concentration in shoots (A) and roots (B) of LE-WT, LE-OE, and LE-R first and second weeks after adding different treatments. The different letters significantly showed differences (p ≤ 0.05) between treatments, respectively (DW: dry weight).
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Figure 5. Dry weight in shoots (A) and roots (B) of LE-WT, LE-OE, and LE-R first and second weeks after adding different treatments. The different letters on the bars significantly showed differences (p ≤ 0.05) between treatments, respectively.
Figure 5. Dry weight in shoots (A) and roots (B) of LE-WT, LE-OE, and LE-R first and second weeks after adding different treatments. The different letters on the bars significantly showed differences (p ≤ 0.05) between treatments, respectively.
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Figure 6. Soluble protein contents in shoots (A) and roots (B) of LE-WT, LE-OE, and LE-R first and second weeks after adding different treatments. The different letters significantly showed differences (p ≤ 0.05) between treatments, respectively (FW: fresh weight).
Figure 6. Soluble protein contents in shoots (A) and roots (B) of LE-WT, LE-OE, and LE-R first and second weeks after adding different treatments. The different letters significantly showed differences (p ≤ 0.05) between treatments, respectively (FW: fresh weight).
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Figure 7. Differentially expressed genes LE-OE (A) and LE-R (B) lines (total, up-regulated, and down-regulated genes).
Figure 7. Differentially expressed genes LE-OE (A) and LE-R (B) lines (total, up-regulated, and down-regulated genes).
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Figure 8. GO classification of LE-OE up-regulated (A) and down-regulated (B) differentially expressed genes, and LE-R up-regulated (C) and down-regulated (D) differentially expressed genes.
Figure 8. GO classification of LE-OE up-regulated (A) and down-regulated (B) differentially expressed genes, and LE-R up-regulated (C) and down-regulated (D) differentially expressed genes.
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Figure 9. The Kyoto Encyclopedia of Genes and Genomes (KEGG) pathway enrichment scatter plot of up-regulated (A) and down-regulated (B) of LE-OE differentially expressed genes and up-regulated (C) and down-regulated (D) of LE-R differentially expressed genes.
Figure 9. The Kyoto Encyclopedia of Genes and Genomes (KEGG) pathway enrichment scatter plot of up-regulated (A) and down-regulated (B) of LE-OE differentially expressed genes and up-regulated (C) and down-regulated (D) of LE-R differentially expressed genes.
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Figure 10. Relative expression levels of LOC_Os10g10130 (A), ATG8D (B), Os10g0530500 (C), Os05g0240200 (D), Os02g0685200 (E) and Os08g0522400 (F), GSTU1 (G), Os01g0369700 (H), GSTZ5 (I) RNA transcript in LE-OE, LE-R roots.
Figure 10. Relative expression levels of LOC_Os10g10130 (A), ATG8D (B), Os10g0530500 (C), Os05g0240200 (D), Os02g0685200 (E) and Os08g0522400 (F), GSTU1 (G), Os01g0369700 (H), GSTZ5 (I) RNA transcript in LE-OE, LE-R roots.
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Table 1. Primers of gene used for qRT-PCR in this study.
Table 1. Primers of gene used for qRT-PCR in this study.
GenePrimer Sequence (5′-3′)Primer Length (nt)Tm (°C)PCR Product Length (bp)
Os10g0530500-FACAACATGTTCCCTGGAATGG2155.6166
Os10g0530500-RTCGACGTACCCGATGGAGTC2059.5
Os08g0522400-FCAAAGACAAGCTTTCACCGTAA2253.9282
Os08g0522400-RCAGAAAAGAACGCTGCCTTTAA2253.9
Os01g0369700-FGTTCGGTGAGATTCCAGTACTG2257.786
Os01g0369700-RTGTACTTGCGAAAGATGTACCT2253.9
GSTU1-FGTGAGTTTGTTGTTACCGTTGA2253.984
GSTU1-RTGACAATCTCAGAGAATCGGAG2255.8
GSTZ5-FAAGATTGTCGCGATTGATCTTG2253.995
GSTZ5-RTGATTGTTGTGCTCAAGTGAAG2253.9
Os05g0240200-FCTGAAGATGTTGGCTACTTTCG2255.8177
Os05g0240200-RCATCTTTCAGGAACCGCATATG2255.8
ATG8D-FTCTTCTGGAGTCTACACGTCTA2255.8111
ATG8D-RGTCTTCTTCCTTGATGCGAATC2255.8
LOC_Os10g10130-FTTTGGATGCTGTCTTGAAACTG2253.987
LOC_Os10g10130-RATCTGGATGAAGTAGTCCGAAC2255.8
Os02g0685200-FCGGTGGGTTCTCGAATAACTC2157.6193
Os02g0685200-RCGTGGTTGCAATTGACATCTTA2253.9
actin1(Os03g0718100)-FCTTCATAGGAATGGAAGCTGCGGGTA2661.2197
actin1(Os03g0718100)-RCGACCACCTTGATCTTCATGCTGCTA2661.2
Table 2. Results (F value) of ANOVA on effects of line, As, Si, and interactions among them on As concentration and dry weight of shoot and root of Lemont rice lines at different sampling times.
Table 2. Results (F value) of ANOVA on effects of line, As, Si, and interactions among them on As concentration and dry weight of shoot and root of Lemont rice lines at different sampling times.
Sampling TimeParameterLineAsSiLine × AsLine × SiAs × SiLine × As × Si
1st weekShoot
As concentration
344.84 **15,523.48 **2192.96 **236.03 **85.79 **848.92 **151.63 **
Root
As concentration
182.45 **25,123.40 **5047.21 **122.71 **270.55 **1568.16 **213.83 **
Shoot
dry weight
6.96 **69.76 **34.11 **0.32 ns0.55 ns1.05 ns0.32 ns
Root
dry weight
3.29 *62.42 **35.89 **0.37 ns0.33 ns1.90 ns0.09 ns
2nd weekShoot
As concentration
987.26 **14,477.16 **3755.15 **861.59 **359.47 **1547.55 **299.44 **
Root
As concentration
395.65 **28,989.96 **7140.00 **244.32 **273.65 **1789.42 **122.37 **
Shoot
dry weight
3.98 *77.01 **41.90 **0.17 ns0.29 ns2.22 ns0.16 ns
Root
dry weight
1.69 ns74.41 **47.70 **0.12 ns0.28 ns2.23 ns0.11 ns
** Significant at the level of 1%, * significant at the level of 5%, ns nonsignificant.
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Boorboori, M.R.; Lin, W.; Jiao, Y.; Fang, C. Silicon Modulates Molecular and Physiological Activities in Lsi1 Transgenic and Wild Lemont Rice Seedlings under Arsenic Stress. Agronomy 2021, 11, 1532. https://doi.org/10.3390/agronomy11081532

AMA Style

Boorboori MR, Lin W, Jiao Y, Fang C. Silicon Modulates Molecular and Physiological Activities in Lsi1 Transgenic and Wild Lemont Rice Seedlings under Arsenic Stress. Agronomy. 2021; 11(8):1532. https://doi.org/10.3390/agronomy11081532

Chicago/Turabian Style

Boorboori, Mohammad Reza, Wenxiong Lin, Yanyang Jiao, and Changxun Fang. 2021. "Silicon Modulates Molecular and Physiological Activities in Lsi1 Transgenic and Wild Lemont Rice Seedlings under Arsenic Stress" Agronomy 11, no. 8: 1532. https://doi.org/10.3390/agronomy11081532

APA Style

Boorboori, M. R., Lin, W., Jiao, Y., & Fang, C. (2021). Silicon Modulates Molecular and Physiological Activities in Lsi1 Transgenic and Wild Lemont Rice Seedlings under Arsenic Stress. Agronomy, 11(8), 1532. https://doi.org/10.3390/agronomy11081532

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