Skip to main content
Advertisement
Browse Subject Areas
?

Click through the PLOS taxonomy to find articles in your field.

For more information about PLOS Subject Areas, click here.

  • Loading metrics

Hydrogen Sulfide Improves Drought Tolerance in Arabidopsis thaliana by MicroRNA Expressions

  • Jiejie Shen ,

    Contributed equally to this work with: Jiejie Shen, Tongji Xing

    Affiliations School of Life Science, Shanxi University, Taiyuan, Shanxi, PR China, College of Life Science, Zhejiang University, Hangzhou, Zhejiang, PR China

  • Tongji Xing ,

    Contributed equally to this work with: Jiejie Shen, Tongji Xing

    Affiliation Department of Biology, Appalachian State University, Boone, North Carolina, United States of America

  • Huihong Yuan,

    Affiliation School of Life Science, Shanxi University, Taiyuan, Shanxi, PR China

  • Zhiqiang Liu,

    Affiliation School of Life Science, Shanxi University, Taiyuan, Shanxi, PR China

  • Zhuping Jin,

    Affiliations School of Life Science, Shanxi University, Taiyuan, Shanxi, PR China, School of Chemical Engineering and Environment, North University of China, Taiyuan, Shanxi, PR China

  • Liping Zhang,

    Affiliation School of Life Science, Shanxi University, Taiyuan, Shanxi, PR China

  • Yanxi Pei

    peiyanxi@sxu.edu.cn

    Affiliation School of Life Science, Shanxi University, Taiyuan, Shanxi, PR China

Abstract

Hydrogen sulfide (H2S) is a gasotransmitter and plays an important role in many physiological processes in mammals. Studies of its functions in plants are attracting ever growing interest, for example, its ability to enhance drought resistance in Arabidopsis. A general role of microRNAs (miRNAs) in plant adaptive responses to drought stress has thereby increased our interest to delve into the possible interplay between H2S and miRNAs. Our results showed that treating wild type (WT) Arabidopsis seedlings with polyethylene glycol 8000 (PEG8000) to simulate drought stress caused an increase in production rate of endogenous H2S; and a significant transcriptional reformation of relevant miRNAs, which were also triggered by exogenous H2S in WT. When lcd mutants (with lower H2S production rate than WT) were treated with PEG8000, they showed lower levels of miRNA expression changes than WT. In addition, we detected significant changes in target gene expression of those miRNAs and the corresponding phenotypes in lcd, including less roots, retardation of leaf growth and development and greater superoxide dismutase (SOD) activity under drought stress. We thereby conclude that H2S can improve drought resistance through regulating drought associated miRNAs in Arabidopsis.

Introduction

Hydrogen sulfide (H2S) is emerging as an important endogenous gasotransmitter along with nitric oxide (NO) and carbon monoxide (CO) in eukaryotic organisms [1][3]. It has been implicated in regulating vasodilatation, smooth muscle relaxation, and cardio-protective processes in mammals [4]. In plants such studies are still at their beginning stages though they are attracting ever-growing attention. Currently H2S has been reported to participate in various physiological processes to improve drought resistance [5], [6]; increase longevity of cut flowers [7]; alleviate boron toxicity in cucumber seedlings [8]; alleviate cadmium induced oxidative damage in alfalfa seedling roots [9] and in Escherichia coli [10]; induce heat tolerance in tobacco suspension cultured cells [11]; enhance salt tolerance in alfalfa seed germination [12], etc.

To date, coding genes for several H2S-generating enzymes have been reported in different plant species. l-cysteine (Cys) desulfhydrase (LCD, At3g62130) and d-Cys desulfhydrase 1 (DCD1, At1g48420) code for two classes of such enzymes that decompose l- and d-Cys into H2S, ammonia (NH3) and pyruvate [13]. d-Cys desulfhydrase 2 (DCD2, At3g26115) is responsible for catalyzation of the decomposition of l- and d-Cys into H2S [14]. Another Cys desulfuration reaction catalyzed by the l-Cys desulfurases occurs in iron-sulfur cluster biosynthesis and involves the formation of l-Ala and elemental sulfur or H2S from Cys. Their coding genes are known as NFS1 (At5g65720) and NFS2 (At1g08490). Álvarez et al. reported that DES1 (At5g28030) also codes for enzymes that catalyze the formation of H2S with l-Cys as substrate [15].

MicroRNAs (miRNAs) are a class of single-stranded non-coding RNAs that range in length from roughly 18–25 nucleotides, and are encoded by endogenous miRNA genes [16]. They have been reported to be involved in plant development, signal transduction, protein degradation and their own biogenesis regulation. In particular, miRNAs are known to regulate plant responses to a variety of biotic and abiotic stresses including drought, cold, salinity and bacterial infection [17]. In Arabidopsis, miR156, miR158, miR159, miR165, miR167, miR168, miR169, miR171, miR319, miR393, miR394 and miR396 are drought-responsive. Under drought stress, miR167, miR393 and miR396 are upregulated, miR169 is downregulated and miR398 is differentially regulated [17]. Jay et al. reported that miR167 targets auxin response factor 8 (ARF8) [18], which is involved in determining hypocotyl length, stamen development, and light signal transduction pathways [19]. miR393 targets transport inhibitor response 1 (TIR1), auxin signaling F-box proteins 1, 2 and 3 (AFB1, AFB2 and AFB3) [20], which are involved in determining the length of the main root and hypocotyl and the number of lateral roots [21]. miR396 targets growth-regulating factor coding genes GRF1, GRF2, GRF3, GRF4, GRF7, GRF8 and GRF9, which play an important role in leaf growth and development [22]. miR398 targets superoxide dismutase (SOD) coding genes. SOD is a major reactive oxygen species (ROS) scavenging enzyme and is also known as CSD1 in the cytoplasm and CSD2 in the chloroplast [23].

In a previous study, we found that H2S interacts with ABA in the stomatal regulation of drought stress in Arabidopsis [5]. Jin et al. reported that H2S upregulates several drought responsive genes including dehydration-responsive element-binding protein 2A and 2B (DREB2A and DREB2B), responsive to desiccation 29A (RD29A) and C-repeat-binding factor 4 (CBF4) to improve drought resistance in Arabidopsis [6].

In this study, we treated both wild type (WT) and lcd (a mutant that has lower H2S production rate than WT) Arabidopsis seedlings with polyethylene glycol 8000 (PEG8000) as simulation of drought stress to study the effects of H2S on the expression of drought associated miRNAs and their target genes and on the changes of corresponding phenotypes.

Materials and Methods

Plant Growth and Treatments

Seeds of Arabidopsis ecotype Columbia (Col-0) were used in this study. Seeds of T-DNA insertion mutant of lcd (SALK_082099) were obtained from the Arabidopsis Biological Resource Center (ABRC, http://www.arabidopsis.org/abrc/) [5]. For each experiment, seeds were incubated for 4 days at 4°C, sterilized in 75% (v:v) ethanol solution for 30 sec and in 6% (v:v) sodium hypochlorite solution for 9 min, then placed in a growth chamber at 23±1°C on ½ MS (Murashige-Skoog) medium at about 160 µmol photons m−2 s−1 for 14 d with a 16/8 h (light/dark) photoperiod.

After 14 days, seedlings were carefully removed with their roots immersed in water or PEG8000 serial solution. WT seedlings were treated with the following four treatments: 50 µmol L−1 NaHS [6] for 0, 3, 6, 12 h; 0, 20, 50, 100 µmol L−1 NaHS for 12 h; 0.1 g ml−1 PEG8000 solution (based on the data in our lab previously) for 0, 1, 2, 4, 8 h; 0, 0.05, 0.1, 0.2, 0.4 g ml−1 PEG8000 solution for 2 h.

Reverse Transcription (RT)-PCR Analysis

Total RNAs were extracted from 14-d old seedlings in ½ MS medium. RT reactions were performed in 20 µl system using 3 µg RNA by M-MLV (NEB). RT-PCR conditions for elongation factor 1-α gene (EF1-α) amplification were as follows: 94°C for 1 min, 94°C for 1 min, 66°C for 30 sec, 72°C for 50 sec, 35 cycles, and 72°C for 10 min [24]. For target gene amplification, essentially the same conditions were used except the number of PCR cycles and annealing temperatures were varied (see Table S1).

The cDNAs above were used as templates to determine expression levels of miRNAs and target genes with quantitative real-time PCR (qRT-PCR). The primers used for qRT-PCR are listed in Table S1. Analyses were performed using the BioRad Real-Time System (CFX96TM C1000 Thermal Cycler, Singapore). In the relative quantification analysis, ACTIN was used as a reference gene to normalize expression values. All experiments were repeated three times along with three independent repetitions of the biological experiments and the results were analyzed using the delta-delta threshold cycle method [25].

Measurement of H2S Production Rate

H2S production rate was measured according to Jin et al. [6]. The extraction of total protein amount in 14-day-old plants was according to Pei et al. [24]. Protein content was determined according to Bradford [26].

Observation of Phenotype and Determination of Relevant Physiological Indexes

Measurement of roots and leaf growth and development was as follows. WT and lcd seedlings were cultured for 26 days under the same conditions as above. Then the length and the number of roots were measured and statistically analyzed; the growth and development of leaves were also observed.

SOD activities and malondialdehyde (MDA) content were measured according to Jiang et al. [27]. H2O2 content was measured according to Alexieva et al. [28].

Statistical Analysis

Analyses of variance were conducted to determine treatment differences using SPSS (version 17, IBM SPSS, Chicago, IL). We used the LSD multiple range tests to evaluate significant differences among the treatments (P<0.05).

Results

Effects of PEG8000 on Expression Levels of H2S-generating Enzymes and Production Rate of H2S in WT Seedlings

Expression levels of H2S-generating enzymes (LCD, DCD1, NFS1, NFS2 and DES1) were determined by RT-PCR. The accumulation of gene transcripts mentioned above increased as time progressed and as PEG8000 concentration was elevated (Figure 1A and 1B). LCD was an anomaly as its transcripts reached a peak when treated with 0.2 g ml−1 PEG8000 (Figure 1B). In addition, measurement of H2S product rate in WT treated with 0.2 g ml−1 PEG8000 showed that the decomposing rate of l- and d-Cys into H2S significantly increased within 2 h upon the initiation of treatment (Figure 1C). These results established a significant correlation between drought stress and the production of both H2S transcripts and H2S emission.

thumbnail
Figure 1. Effects of PEG8000 on the expression of genes controlling H2S generation and on H2S production rate in WT seedlings.

(A) Expression detection of H2S generating critical enzymes coding genes in WT seedlings treated with 0.1 g ml−1 PEG8000 for 0, 1, 2, 4, 8 h; (B) Expression detection of H2S generating critical enzymes coding genes in WT seedlings treated 2 h with 0, 0.05, 0.1, 0.2, 0.4 g ml−1 PEG8000. EF1-α was used as an internal control of RT-PCR; (C) Endogenous H2S production rate of WT seedlings treated with 0.2 g ml−1 PEG8000 for 2 h. Results are shown as mean ± SE (n = 3 independent experiments). Letter numbers indicate significant differences between treatments and substracts (P<0.05).

https://doi.org/10.1371/journal.pone.0077047.g001

Effect of PEG8000 on the Expression of Drought Associated miRNAs in WT Seedling

Khraiwesh et al. reported that miRNAs play a role in plant responses to drought stress [17]. Therefore we treated WT Arabidopsis with PEG8000 to simulate drought stress in order to determine expression-level changes of drought associated miRNAs by RT-PCR. The results showed an accumulation of MIR167a, MIR167c, MIR167d, MIR393a and MIR396a transcripts as time progressed until they reached a maximum at 2 h into the treatment, after which they started decreasing (Figure 2A). Thus a PEG8000 treatment for 2 h was selected for later experiments. We then treated WT seedlings with different concentrations of PEG8000 (0, 0.05, 0.1, 0.2, 0.4 g ml−1) and found that higher expression of the miRNAs was induced by increased PEG8000 concentration. However the expression levels reached a plateau when treated with 0.2 g ml−1 solution (Figure 2B). The 0.2 g ml−1 PEG8000 treatment was therefore selected for ensuing experiments. MIR398a and MIR398c transcripts decreased as time progressed, While MIR398b transcripts increased as time progressed, until they reached a maximum at 2 h into the treatment, after which started decreasing (Figure 2A); transcripts first increased and then decreased as PEG8000 concentration increased (Figure 2B). These results collectively indicated that the expression levels of specific miRNAs corresponded to drought stress caused by PEG8000.

thumbnail
Figure 2. RT-PCR detection of miRNAs transcription in WT seedlings under PEG8000 stress.

(A) miRNAs transcription detection in WT seedlings treated with 0, 1, 2, 4, 8 h using 0.01 g ml−1 PEG8000 treatment; (B) miRNAs transcription detection in WT seedlings after 2 h using different PEG8000 concentration treatments at 0, 0.05, 0.1, 0.2, 0.4 g ml−1 PEG8000. EF1-α was used as an internal control of RT-PCR.

https://doi.org/10.1371/journal.pone.0077047.g002

Effect of H2S on the Drought Associated miRNAs Expression in WT Seedling

To further validate the above conclusions, we treated WT seedlings with 50 µmol L−1 NaHS for 0, 3, 6, 12 h. The results showed that exogenous H2S induced a common pattern of transcript accumulation of MIR167a, MIR167c, MIR167d, MIR393a and MIR396a as time progressed (Figure 3A). NaHS for 12 h was thereby selected in the following experiments. In comparison, MIR398a and MIR398b were first downregulated and then upregulated; MIR398c was downregulated during the 12 h period. When the seedlings were treated with 0, 20, 50 µmol L−1 NaHS for 12 h, all miRNAs above were upregulated in a dose-dependent manner except for MIR398b and MIR398c (Figure 3B). When treated with 100 µmol L−1 NaHS, expression of these miRNAs except for MIR398b and MIR398c showed no significant increase and therefore we chose 50 µmol L−1 for the following experiments. MIR398b and MIR398c set themselves apart by exhibiting an up-down-up regulatory pattern of their transcripts (Figure 3B). These results indicated that the expression of the related miRNAs was affected by exogenous H2S treatment.

thumbnail
Figure 3. NaHS effects on miRNAs expression in WT seedlings.

(A) miRNAs expression in WT seedlings treated with 50 µmol L−1 NaHS for 0, 3, 6, 12 h; (B) miRNAs expression in WT seedlings treated with 0, 20, 50, 100 µmol L−1 NaHS for 12 h. EF1-α was used as an internal control.

https://doi.org/10.1371/journal.pone.0077047.g003

H2S Responds to Drought Stress by Regulating miRNAs in Arabidopsis

As suggested by results from the above experiments, we made the assumption that the H2S signal was intensified by drought stress in Arabidopsis WT seedlings and that H2S further regulated plant responses to drought through the miRNA pathway. To validate this, we introduced lcd mutants and treated them with 50 µmol L−1 NaHS and 0.2 g ml−1 PEG8000 separately. lcd mutants are lack of the critical H2S generating enzyme LCD and their H2S production rate is determined to be 40% of the WT. Results from qRT-PCR showed elevated expression levels of MIR167a, MIR167c, MIR167d, MIR393a and MIR396a (Figure 4A) and decreased expression levels of MIR398a, MIR398b and MIR398c (Figure 4B) in both lcd and WT under PEG8000 treatment compared with non-treated plants. When PEG8000 treated lcd mutants were compared with PEG8000 treated WT, lcd showed a lower expression level of MIR167a, MIR167c, MIR167d, MIR398a, MIR398b and MIR398c and a higher expression level of MIR393a and MIR396a. We conclude that miRNA expression in general is lower in PEG8000 treated lcd than PEG8000 treated WT. However when deficient endogenous H2S production was rescued by NaHS supply, we again observed an accumulation of relevant miRNA transcripts (Figure 4), which confirmed H2S regulates miRNAs to improve tolerance to drought stress in Arabidopsis.

thumbnail
Figure 4. PEG8000 and NaHS effects on miRNAs in WT and lcd plants.

(A) MIR167a, MIR167c, MIR167d, MIR393a and MIR396a expressions in WT and lcd treated with 50 µmol L−1 NaHS and 0.2 g ml−1 PEG8000. lcd was pre-treated with 50 µmol L−1 NaHS for 12 h and 0.2 g ml−1 PEG8000 for 2 h; (B) MIR398a, MIR398b and MIR398c expression in WT and lcd treated with 50 µmol L−1 NaHS and 0.2 g ml−1 PEG8000. The same treatments were applied as in (A). ACTIN was used as an internal control in qRT-PCR. Results are shown as mean ± SE (n = 3 independent experiments). Letter numbers indicate significant differences between treatments within one gene (P<0.05).

https://doi.org/10.1371/journal.pone.0077047.g004

Expression Changes of Drought Associated miRNAs Target Genes under PEG8000 Stress and NaHS Treatment in Arabidopsis

We selected ARF8 (target gene of miR167); TIR1, AFB2 and AFB3 (target genes of miR393); GRF1, GRF2 and GRF3 (target genes of miR396); CSD1 and CSD2 (target genes of miR398) to determine possible transcriptional changes of drought-associated miRNA target genes. Results from qRT-PCR showed significant lower expression of ARF8, TIR1, AFB2, AFB3, GRF1, GRF2 and GRF3 (Figure 5A), and significant higher expression of CSD1and CSD2 (Figure 5B) in lcd and WT, under PEG8000 treatment compared that without PEG8000. When lcd is compared to WT with PEG8000, CSD1and CSD2 both had higher expression levels while other target genes showed no obvious difference. When lcd plants treated with NaHS and PEG8000 were compared to lcd plants treated with only PEG8000, CSD1and CSD2 both had lower expression levels while other target genes (AFB3, GRF3, CSD1 and CSD2) had higher abundance, which possibly offset the deficiency effects caused by lack of LCD. We may thereby conclude that H2S affects the expression of those downstream target genes by regulating miRNAs.

thumbnail
Figure 5. Target gene expressions in WT and lcd plants treated with PEG8000 and NaHS.

(A) ARF8, TIR1, AFB2, AFB3, GRF1, GRF2 and GRF3 expression in WT and lcd treated with 50 µmol L−1 NaHS and 0.2 g ml−1 PEG8000; (B) CSD1 and CSD2 expression in WT and lcd treated with 50 µmol L−1 NaHS and 0.2 g ml−1 PEG8000. The same treatments were applied as in Figure 4. ACTIN was used as an internal control in qRT-PCR. Results are shown as mean ± SE (n = 3 independent experiments). Letter numbers indicate significant differences between treatments within one gene (P<0.05).

https://doi.org/10.1371/journal.pone.0077047.g005

Phenotype Observation Corresponding to the Target Genes of Drought Associated miRNAs

We observed the phenotypes corresponding to the drought associated miRNA target genes to further validate that H2S affects the expression of those downstream target genes by regulating miRNAs. According to previous research, TIR1, AFB1, AFB2 and AFB3 (targets of miR393) affect the growth of the main root and hypocotyl and the number of lateral roots [21]. The length and the number of roots decreased 28% and 32% in dehydrated WT, respectively (Figure 6B and 6C); in dehydrated lcd they decreased to a greater extent: 40% in the length and 52% in the number of roots (Figure 6). GRF1, GRF2, GRF3, GRF4, GRF7, GRF8 and GRF9 (targets of miR396) function primarily in leaf development and when overexpressed plants have lower densities of stomata [22]. The size of leaves decreased in both WT and lcd under PEG8000 but in lcd it decreased to a greater extent (Figure 7). CSD1and CSD2 (targets of miR398) play an important role in scavenging activity of ROS (results shown in Figure 8) [23]; SOD enzyme activity increased in both WT and lcd under PEG8000 (Figure 8A); Similarly, H2O2 and MDA contents increased in both WT and lcd under PEG8000 and it is notable that MDA content increased to a greater extent in lcd compared with WT (Figure 8B and 8C).

thumbnail
Figure 6. Root number and length in WT and lcd plants treated with PEG8000.

(A) WT and lcd seedlings cultured in ½ MS and ½ MS containing PEG8000 for 26 day. (B) Length of roots. (C) Number of roots. Results are shown as mean ± SE (n = 3 independent experiments). Letter numbers indicate significant differences (P<0.05).

https://doi.org/10.1371/journal.pone.0077047.g006

thumbnail
Figure 7. Leaf growth and development of WT and lcd plants treated with PEG8000.

WT and lcd seedlings cultured in ½ MS and ½ MS containing PEG8000 for 26 day. Experiments are repeated three times.

https://doi.org/10.1371/journal.pone.0077047.g007

thumbnail
Figure 8. SOD activity, H2O2 content and MDA content in WT and lcd plants treated with PEG8000.

(A) SOD activity was measured in WT and lcd plants treated with 0.2 g ml−1 PEG8000 for 2 h. One SOD unit was the amount of enzyme required to inhibit photoreduction of nitro blue tetrazolium chIoride by 50% at 25°C. SOD activity was expressed as U mg−1 (protein) min−1. (B) H2O2 content was measured in WT and lcd plants treated with 0.2 g ml−1 PEG8000 for 2 h. (C) MDA content was measured in WT and lcd plants treated with 0.2 g ml−1 PEG8000 for 2 h. Results are shown as mean ± SE (n = 3 independent experiments). Letter numbers indicate significant differences between treatmeats (P<0.05).

https://doi.org/10.1371/journal.pone.0077047.g008

In summary, lcd in comparison with WT under PEG8000 showed decreased root lengths, fewer roots, significantly smaller leaf sizes and increased antioxidant enzyme activities. These results confirmed our initial speculation that H2S affects the expression of those downstream target genes that respond to drought by regulating their corresponding miRNAs.

Discussion

In our experiments a 50 µmol L−1 concentration of NaHS was selected based on the known physiological concentration range of H2S of 1 to 100 µmol detected in animals and plants [6]. To confirm 50 µmol L−1 as the proper H2S physiological concentration in Arabidopsis, we measured the MDA content in WT and lcd treated with NaHS and our results showed that the MDA contents in WT and lcd were not significantly different from corresponding controls (Figure S1). Therefore, 50 µmol L−1 of NaHS was an appropriate choice for this research.

After we found that H2S product rate in WT plant under drought stress was accelerated, we also measured the same index in lcd and detected a higher generation rate under drought stress than that without PEG8000 as well (Figure 9). We surmise that this is due to a complementary effect of other H2S generating enzymes such as DCD1, DCD2, DES1, NFS1 and NFS2. It is therefore highly probable that drought stress induces the expression of other H2S generating enzymes as well as LCD.

thumbnail
Figure 9. H2S generation rate in lcd plants treated with PEG8000.

Endogenous H2S generation rate in lcd seedlings treated with 0.2 g ml−1 PEG8000 for 2 h. Results are shown as mean ± SE (n = 3 independent experiments). Letter numbers indicate significant differences between treatmeats and substracts (P<0.05).

https://doi.org/10.1371/journal.pone.0077047.g009

According to Goetz et al. [19], ARF8 (target of miR167) prompts the elongation of hypocotyl and stamens during development, and regulates light signal transduction pathways. However we found that the length of the hypocotyl decreased in both WT and lcd under PEG8000 (date not shown), which complies with the observable decreased hypocotyl length of alfalfa [29] and Pinus sylvestris var. mongolica seeds [30] under drought conditions. This is possible since there are a number of factors regulating the growth of the hypocotyl when plants lack water. While miR167 is responsible for hypocotyl growth, other factors such as the activation of α- and β-amylases [29], [31], and Arabidopsis AP2/DREB-type transcription factor [32] may suppress growth and cause an overall effect of decreased hypocotyl length.

In this paper we have shown that the expression of MIR398a and MIR398c/MIR398b first increased as PEG8000 concentration went up from 0 to 0.05 g ml−1/0.2 g ml−1 and then decreased (Figure 2B). This is consistent with the results from Trindade et al. [33] and Frazier et al. [34], however deviating from a commonly discovered negative correlation between miRNA transcripts and PEG8000 concentration [35], [36]. Therefore different miRNA species may have different sensitivity to PEG8000 concentrations. miR398 target genes that code for the free radical scavenger SOD and these genes have been shown to be down-regulated during times of oxidative stress [36]. Therefore decreased miR398 expression of plants exposed to higher PEG8000 concentrations might suggest that severe drought induced stress was created by an oxidative environment inside the Arabidopsis cells. However the exact mechanism of action remains unclear.”

Expression of MIR167a, MIR167c, MIR167d, MIR398a, MIR398b and MIR398c transcripts in lcd are significantly lower than WT under PEG8000 treatment while that of MIR393a and MIR396a are higher (Figure 4), which did not match the expression pattern of the miRNA target genes. However, eukaryotic organisms are complex and a certain signal transduction pathway for some intermediates can at the same time be involved in other physiological and biochemical reactions or other metabolic pathways in the cell. The overall effect could lead to unexpected results such as in our example, where the expression of some target genes did not match that of their miRNAs.

In order to detect any possible changes of antioxidant enzymes under drought conditions, we measured activity of two commonly known antioxidant enzymes, peroxidase (POD) and catalase (CAT), and found that both activities were significantly raised in both WT and lcd after treatment, which parallels the SOD activity we obtained (Figure S2). Using H2S against drought-induced oxidative stress might be a common process in various plant species [37].

We propose a model based on the results described in this study and previous research [5], [6] in our lab, demonstrating the H2S regulating pathway in response to drought stress (Figure 10). Drought upregulates the expression levels of LCD, DCD1, NFS1, NFS2 and DES1 in order to produce more H2S which then interacts with ABA. On one hand, H2S directly regulates the expression of a series of drought responsive genes including DREB2A, DREB2B, RD29A and CBF4. On the other hand, H2S is involved in regulating the expression of drought associated miRNAs such as miR167, miR393, miR396 and miR398 and can therefore affect their target gene expressions and so to improve the tolerance of Arabidopsis to drought.

thumbnail
Figure 10. Summary of H2S regulating miRNAs in response to drought stress.

Solid lines: direct effects; dotted lines: intermediates remain elusive; arrows: enhanced expression; hyphen: suppressed expression.

https://doi.org/10.1371/journal.pone.0077047.g010

Supporting Information

Figure S1.

The effect of NaHS on the content of MDA in WT and lcd plants. The MDA content of WT and lcd seedlings were determined after being treated with 50 µmol L−1 NaHS for 12 h. Results shown are mean ± SE (n = 3 independent experiments). Letter numbers indicate significant differences between treatments (P<0.05).

https://doi.org/10.1371/journal.pone.0077047.s001

(TIF)

Figure S2.

CAT activity and POD activity in WT and lcd plants treated with PEG8000. (A) CAT activity was measured in WT and lcd plants treated with 0.2 g ml−1 PEG8000 for 2 h. One CAT unit was the amount of enzyme required to decompose 1 µmol of H2O2 min−1 at 25°C (pH 7.0). Consumption of H2O2 was measured as the decrease in absorbance at 240 nm. (B) POD activity was measured in WT and lcd plants treated with 0.2 g ml−1 PEG8000 for 2 h. One POD unit was the amount of enzyme required to decompose 1 µmol of H2O2 min−1 at 25°C (pH 7.0). Consumption of H2O2 was measured as the decrease in absorbance at 470 nm. Results shown are mean ± SE (n = 3 independent experiments). Letter numbers indicate significant differences between treatmeats (P<0.05).

https://doi.org/10.1371/journal.pone.0077047.s002

(TIF)

Table S1.

List of all genes in the manuscript.

https://doi.org/10.1371/journal.pone.0077047.s003

(DOC)

Acknowledgments

We give sincere appreciation to Dr. Howard Neufeld from the Department of Biology at Appalachian State University for his generous help with the English and for the reviewing work.

Author Contributions

Conceived and designed the experiments: YXP JJS. Performed the experiments: JJS TJX HHY. Analyzed the data: YXP JJS TJX ZQL ZPJ LPZ. Contributed reagents/materials/analysis tools: ZQL ZPJ LPZ. Wrote the paper: YXP JJS TJX ZQL.

References

  1. 1. Xu J, Yin HX, Li YL, Liu XJ (2010) Nitric oxide is associated with long-term zinc tolerance in Solanum nigrum. Plant Physiol 154: 1319–1334.
  2. 2. Xu MJ, Dong JF, Zhang XB (2008) Signal interaction between nitric oxide and hydrogen peroxide in heat shock-induced hypericin production of Hypericum perforatum suspension cells. Sci China Ser C-Life Sci 51(8): 676–686.
  3. 3. Wang R (2012) Physiological implications of hydrogen sulfide: a whiff exploration that blossomed. Physiol Rev 92: 791–896.
  4. 4. Wang R (2010) Hydrogen sulfide: the third gasotransmitter in biology and medicine. Antioxid Redox Signal 12: 1061–1064.
  5. 5. Jin ZP, Xue SW, Luo YN, Tian BH, Fang HH, et al. (2013) Hydrogen sulfide interacting with abscisic acid in stomatal regulation responses to drought stress in Arabidopsis. Plant Physiol Biochem 62: 41–46.
  6. 6. Jin ZP, Shen JJ, Qiao ZJ, Yang GD, Wang R, et al. (2011) Hydrogen sulfide improves drought resistance in Arabidopsis thaliana. Biochem Bioph Res Co 414: 481–486.
  7. 7. Zhang H, Hu SL, Zhang ZJ, Hu LY, Jiang CX, et al. (2011) Hydrogen sulfide acts as a regulator of flower senescence in plants. Postharvest Biol Technol 60: 251–257.
  8. 8. Wang BL, Sin L, Li YX, Zhang WH (2010) Boron toxicity is alleviated by hydrogen sulfide in cucumber (Cucumis sativus L.) seedlings. Planta 231: 1301–1309.
  9. 9. Li L, Wang YQ, Shen WB (2012) Roles of hydrogen sulfide and nitric oxide in the alleviation of cadmium-induced oxidative damage in alfalfa seedling roots. Biometals 25: 617–631.
  10. 10. Shen JJ, Qiao ZJ, Xing TJ, Zhang LP, Liang YL, et al. (2012) Cadmium toxicity is alleviated by AtLCD and AtDCD in Escherichia coli. J Appl Microbiol 113: 1130–1138.
  11. 11. Li ZG, Gong M, Xie H, Yang L, Li J (2012) Hydrogen sulfide donor sodium hydrosulfide-induced heat tolerance in tobacco (Nicotiana tabacum L) suspension cultured cells and involvement of Ca2+ and calmodulin. Plant Sci 185–186: 185–189.
  12. 12. Wang YQ, Li L, Cui WT, Xu S, Shen WB, et al. (2012) Hydrogen sulfide enhances alfalfa (Medicago sativa) tolerance against salinity during seed germination by nitric oxide pathway. Plant Soil 351: 107–119.
  13. 13. Papenbrock J, Riemenschneider A, Kamp A, Schulz-Vogt HN, Schmidt A (2007) Characterization of cysteine-degrading and H2S-releasing enzymes of higher plants-from the field to the test tube and back. Plant Biol 9: 582–588.
  14. 14. Riemenschneider A, Wegele R, Schmidt A, Papenbrock J (2005) Isolation and characterization of a d-cysteine desulfhydrase protein from Arabidopsis thaliana. FEBS J 272: 1291–1304.
  15. 15. Álvarez C, Calo, L Romero LC, García I, Gotor C (2010) An O-acetylserine (thiol) lyase homolog with l-cysteine desulfhydrase activity regulates cysteine homeostasis in Arabidopsis. Plant Physiol 152: 656–669.
  16. 16. Du JF, Wu YJ, Zhang YX, Wu L, Wang XL, et al. (2009) Large-scale information entropy analysis of important sites in mature and precursor miRNA sequences. Sci China Ser C-Life Sci 52(8): 771–779.
  17. 17. Khraiwesh B, Zhu JK, Zhu JH (2012) Role of miRNAs and siRNAs in biotic and abiotic stress responses of plants. BBA-Gene Regul Mech 1819: 137–148.
  18. 18. Jay F, Wang Y, Yu A, Taconnat L, Pelletier S, et al. (2011) Misregulation of auxin response factor 8 underlies the developmental abnormalities caused by three distinct viral silencing suppressors in Arabidopsis. Plos Pathog 7(5): e1002035.
  19. 19. Goetz M, Hooper LC, Johnson SD, Rodrigues JCM, Vivian-Smith A, et al. (2007) Expression of aberrant forms of auxin response factor 8 stimulates parthenocarpy in Arabidopsis and tomato. Plant Physiol 145: 351–366.
  20. 20. Navarro L, Dunoyer P, Jay F, Arnold B, Dharmasiri N, et al. (2006) A plant miRNA contributes to antibacterial resistance by repressing auxin signaling. Science 312: 436–439.
  21. 21. Chen ZH, Bao ML, Sun YZ, Yang YJ, Xu XH, et al. (2011) Regulation of auxin response by miR393-targeted transport inhibitor response protein 1 is involved in normal development in Arabidopsis. Plant Mol Biol 77: 619–629.
  22. 22. Liu DM, Song Y, Chen ZX, Yu DQ (2009) Ectopic expression of miR396 suppresses GRF target gene expression and alters leaf growth in Arabidopsis. Physiol Plantarum 136: 223–236.
  23. 23. Dugas DV, Bartel B (2008) Sucrose induction of Arabidopsis miR398 represses two Cu/Zn superoxide dismutases. Plant Mol Biol 67: 403–417.
  24. 24. Pei YX, Niu LF, Lu FL, Liu CY, Zhai JX, et al. (2007) Mutations in the type II protein arginine methyltransferase AtPRMT5 result in pleiotropic developmental defects in Arabidopsis. Plant Physiol 144: 1913–1923.
  25. 25. Liu ZQ, Yan L, Wu Z, Mei C, Lu K, et al. (2012) Cooperation of three WRKY-domain transcription factors WRKY18, WRKY40 and WRKY60 in repressing two ABA-responsive genes ABI4 and ABI5 in Arabidopsis. J Exp Bot 63(18): 6371–6392.
  26. 26. Bradford MM (1976) A rapid and sensitive method for the quantitation of microgram quantities of protein utilizing the principle of protein-dye binding. Anal Biochem 72: 248–254.
  27. 27. Jiang MY, Zhang JH (2002) Water stress-induced abscisic acid accumulation triggers the increased generation of reactive oxygen species and up-regulates the activities of antioxidant enzymes in maize leaves. J Exp Bot 53(379): 2401–2410.
  28. 28. Alexieva V, Sergiev I, Mapelli S, Karanov E (2001) The effect of drought and ultraviolet radiation on growth and stress markers in pea and wheat. Plant Cell Environ 24: 1337–1344.
  29. 29. Zeid IM, Shedeed ZA (2006) Response of alfalfa to putrescine treatment under drought stress. Biologia Plantarum 50(4): 635–640.
  30. 30. Zhu JJ, Kang HZ, Tan H, Xu ML (2006) Effects of drought stresses induced by polyethylene glycol on germination of Pinus sylvestris var. mongolica seeds from natural and plantation forests on sandy land. J For Res 11: 319–328.
  31. 31. Scaramagli S, Franceschetti M, Torrigiani P (1999) Spermidine and spermine interfere with in vitro BAPNA-mediated proteolytic activity in organogenic tobacco thin layers. J Plant Physiol 155(1): 122–125.
  32. 32. Lin RC, Park HJ, Wang HY (2008) Role of Arabidopsis RAP2.4 in regulating light-and ethylene-mediated developmental processes and drought stress tolerance. Molecular Plant 1(1): 42–57.
  33. 33. Trindade I, Capitão C, Dalmay T, Fevereiro MP, Santos DMD (2010) miR398 and miR408 are up-regulated in response to water deficit in Medicago truncatula. Planta 231: 705–716.
  34. 34. Frazier TP, Sun G, Burklew CE, Zhang BH (2011) Salt and drought stresses induce the aberrant expression of microRNA genes in tobacco. Mol Biotechnol 49: 159–165.
  35. 35. Wang TZ, Chen L, Zhao MG, Tian QY, Zhang WH (2011) Identification of drought-responsive microRNAs in Medicago truncatula by genome-wide high-throughput sequencing. BMC Genomics 12(367): 1471–2164.
  36. 36. Shukla LI, Chinnusamy V, Sunkar R (2008) The role of microRNAs and other endogenous small RNAs in plant stress responses. BBA-Gene Regul Mech 1779: 743–748.
  37. 37. Zhang H, Jiao H, Jiang CX, Wang SH, Wei ZJ, et al. (2011) Hydrogen sulfide protects soybean seedlings against drought-induced oxidative stress. Acta Physiol Plant 32: 849–857.