Abstract
microRNAs (miRNAs) are involved in regulating various plant developmental processes and mediating plant-adaptive responses to nutrient deprivation. In this study, the characterization of a wheat miRNA member TaMIR444a and the role of this miRNA in mediating plant tolerance to the N-starvation stress were investigated. Results indicated that the expression levels of TaMIR444a and NtMIR444a, the homologue of TaMIR444a in tobacco, were upregulated in roots and leaves under N deprivation, whereas the transcription of their target genes showed reverse expression patterns in above tissues. These results suggest that miR444a is conserved across plant species of dicots and monocots and can possibly establish the miRNA/target modules for mediating plant response to N deficiency. Overexpression of TaMIR444a in tobacco improved the plant growth feature, biomass, N content, photosynthetic parameters, and antioxidant enzymatic activities under N deprivation. Based on microarray analyses, a large number of genes were identified to be differentially expressed in the TaMIR444a-overexpressing plants; these differential genes are categorized into functional groups of signal perception and transduction, transcription regulation, primary and secondary metabolism, phytohormone response, cellular protection and defensive responsiveness, etc. qPCR analyses revealed that the nitrate transporter (NRT) genes NtNRT1.1-s, NtNET1.1-t, and NtNRT2.1 and the antioxidant enzyme genes (AEEs) NtCAT1;1, NtPOD1;3, and NtPOD4 were significantly upregulated by TaMIR444a, suggesting that the altered transcription of these NRT and AEE genes is associated with the improvement of the N acquisition and the cellular ROS detoxification in the N-deprived transgenic plants. Together, our findings demonstrate that miR444a acts as one critical regulator in mediating plant tolerance to the N-starvation stress through modulation of the regulatory networks associated with N acquisition, cellular ROS homeostasis, and carbon assimilation. Our findings have provided insights into the mechanisms of plant tolerance to N deficiency mediated by the distinct miRNA pathways.
Similar content being viewed by others
Avoid common mistakes on your manuscript.
Introduction
Nitrogen (N) is an essential macronutrient for plant growth and development and acts as one of the major factors in impacting crop productivity (Frink et al. 1999). Over the past several decades, N fertilizers applied in arable land have been dramatically increased worldwide aiming at acquiring high yields. However, the large input and the low use efficiency of the applied N fertilizers have been resulting in negative impacts on the environment except the increased cost (Ju et al. 2009). Improving N use efficiency (NUE) in crop production thus has been used as one of the important practices in sustainable agriculture (Hirel et al. 2007).
Plants have evolved multiple strategies to respond to the variation of N availability. At molecular level, based on genome-wide microarray analyses, a large quantity of genes functioning in diverse biological processes, including signal transduction, transcription regulation, primary and secondary metabolism, protein synthesis, stress response, cellular growth processes, and stress defense, have been identified to show altered transcripts under the N-limited conditions (Wang et al. 2003). Recently, a set of genes encoding the regulatory proteins and nitrate transporters (NRTs) has been demonstrated to be involved in plant responses to the varied external N conditions. For instance, Arabidopsis Nitrate Regulated 1 (ANR1) and nodule inception-like protein 7 (NLP7), two transcription factor (TF) genes in Arabidopsis, and ZmDOF1, a DOF-type TF gene in maize, act as critical signaling components in sensing and transducing the external N levels (Yanagisawa et al. 2004; Castaings et al. 2009). The Arabidopsis NRT genes AtNRT1.1 and AtNRT2.1 play an important role in mediating the N signaling transduction and act as critical regulators in improving N assimilation and acquisition (Ho et al. 2009; Ho and Tsay 2010). These findings suggest that plants cope with the varied external N levels through modifying a variety of biological processes, which are mediated by genes with diverse biological roles (Stitt et al. 2002; Vidal and Gutiérrez 2008; Wang et al. 2013; Cai et al. 2013; Jin et al. 2015).
Acting as important regulatory molecules, microRNAs (miRNAs) involve various plant developmental processes, including flowering, leaf and root growth, embryo development, and auxin signaling (Sunkar and Zhu 2004; Jones-Rhoades et al. 2006; Mica et al. 2006; Wong et al. 2011; Asha et al. 2013). In addition, recent studies have revealed that miRNAs also regulate the plant responses to various nutrient deprivations (Jones-Rhoades and Bartel 2004; Fujii et al. 2005; Gifford et al. 2008; Pant et al. 2009). For example, the Arabidopsis miR169 is significantly downregulated by N deprivation and it then transcriptionally regulates the target genes AtNRT1.1 and AtNRT2.1 (Zhao et al. 2011). miR167 in Arabidopsis mediates the lateral root initiation and the plant growth under the N-deficient conditions, through targeting a set of N deprivation-defensive genes (Gifford et al. 2008). Several miRNAs in wheat, such as TaMIR1118, TaMIR1129, and TaMIR1136, respond to N deficiency and can possibly establish distinct miRNA/target modules to mediate the plant response to N deprivation (Zhao et al. 2015). Additionally, some miRNA members are also associated with the plant adaption to other inorganic nutrients, of which Arabidopsis miR399 regulates plant phosphate homeostasis under Pi deprivation through posttranscriptional cleavage of transcripts of the ubiquitin-conjugating E2 enzyme (PHO2)-encoding gene (Fujii et al. 2005; Chiou et al. 2006; Bari et al. 2006). After response to external sulfide variations, miR395 transcriptionally regulates the ATP sulfurylase genes APS1, APS3, and APS4 and a low-affinity sulfur transporter gene AtST, establishing the miR395/target module to affect the plant sulfur assimilation (Jones-Rhoades and Bartel 2004). miR398 mediates the cellular copper homeostasis under copper deprivation via regulating a copper/zinc superoxide dismutase (SOD) gene (Yamasaki et al. 2007). These results collectively indicate that the miRNA/target pathways act as critical regulators for mediating the plant responses to external N and other inorganic nutrients.
Up to date, although a subset of N deprivation-responsive miRNAs has been characterized in plants, the mechanisms underlying the plant adaptation to N deprivation mediated by the miRNA/target modules are still largely to be determined. In this study, we reported the characterization of TaMIR444a and its function in mediating plant adaptation to the N-starvation stress. TaMIR444a was drastically upregulated by N deprivation and demonstrated to play critical roles in mediating plant tolerance to N deficiency through regulating diverse physiological and biochemical processes associated with N acquisition, carbon assimilation, and reactive oxygen species (ROS) detoxification.
Materials and Methods
Expression Analysis of TaMIR444a and Its Tobacco Homologue as well as Their Target Genes
Seedlings of wheat (cv. Shixin 828) and tobacco (cv. Wisconsin 38) were cultured hydroponically with MS solution as described by Sun et al. (2012). At the three-leaf expansion stage, the wheat and tobacco seedlings were subjected to the N-starvation treatments by transferring the seedlings into a modified MS solution with reduced N (20 μmol/L N) from the normal N condition (MS, 6 mmol/L N). Roots and leaves of the wheat and tobacco were sampled at the time points of 0 h (before treatment), 12, 24, and 48 h, and 3, 7, and 14 d after the N-deficient treatment to evaluate the responsiveness of the miRNAs to the N-starvation stress. In addition, to address the issue of how these miRNA members respond to the N recovery treatment, an aliquot of wheat and tobacco seedling treated by 48 h of N deprivation was retransferred into MS solution for the N recovery treatments. Roots and leaves of the seedlings were sampled at 12, 24, and 48 h after recovery to assess the expression patterns of the miRNAs under the restored N condition. Total RNA in samples was extracted using TRIzol reagent (Invitrogen) and used to synthesize cDNAs using M-MLV transcriptase (TaKaRa) according to the manufacturer’s instructions. The expression levels of TaMIR444a and NtMIR444a were detected based on semiquantitative RT-PCR and qPCR analyses performed as described by Liu et al. (2013), using the specific primers of TaMIR444a (Table S1). Tatubulin and Nttubulin, two constitutive genes in wheat and tobacco, respectively, were used as internal references in the RT-PCR and qPCR analyses with specific primers (Table S1). Expression levels of these miRNAs in qPCR were quantified according to the 2-ΔΔCT method (Guo et al. 2013).
The target genes of TaMIR444a and NtMIR444a were predicted by an online tool referred to as psRNATarget (http://plantgrn.noble.org/psRNATarget/). The expression levels of the target genes in roots and leaves under various external N conditions were assessed based on qPCR with specific primers (Table S1) performed as aforementioned for detection of the miRNA expression.
Generation and Molecular Characterization Analysis of the Transgenic Plants
The TaMIR444a precursor sequence was amplified by RT-PCR and integrated into the binary vector pCAMBIA3301 at a position downstream of the CaMV35S promoter. Given that the genetic transformation of wheat is difficult currently, we transformed the expression cassette into tobacco (cv. Wisconsin 38) based on an Agrobacterium-mediated approach as described by Sun et al. (2012). To validate the insertion of TaMIR444a in the transgenic lines, PCR analysis was performed to amplify the transcripts of bar, a selection gene in expression cassette conferring resistance to phosphinothricin (PPT), with specific primers (Table S1). A small RNA blot analysis was performed to evaluate the expression levels of TaMIR444a in the transgenic T3 lines as described by Zhao et al. (2015), using the roots treated by 48 h of N deprivation as samples. The tobacco U6 RNA was used as an internal standard for normalization of the TaMIR444a transcripts. Southern blot analysis was performed to characterize the genome insertion pattern of TaMIR444a in transgenic lines of lines 3 and 5 following the procedure described by Li et al. (2011)), using the bar gene labeled with alkaline phosphatase as probe.
Analyses of the Growth Feature, Dry Mass, and N Concentration of the Transgenic Plants Under the N-Sufficient and N-Deficient Conditions
Lines 3 and 5, two T3 lines with stronger expression of TaMIR444a together with wild type (WT), were selected to determine the function of TaMIR444a in mediating the plant growth under N-sufficient and N-deficient conditions. The filter paper-based and the hydroponic culture approaches were used to asses the growth features of the transgenic lines and WT. To this end, the transgenic and WT seedlings were cultured onto filter papers soaked with MS solution (6 mmol/L N) and the modified MS solution with reduced N (60 μmol/L) for 2 weeks or cultured in the above MS solutions for 5 weeks. After treatments, the growth features of the transgenic lines and WT were recorded by a digital camera. The dry mass of the samples was obtained after drying for 48 h at 85 °C. The N concentration in roots and aboveground tissues was assayed as described by Guo et al. (2011). The N content in above tissues was calculated by multiplying the dry mass with N concentration.
Measurement of Photosynthetic Parameters and Antioxidant Enzymatic Activities of the Transgenic Plants Under N-Sufficient and N-Deficient Conditions
The hydroponically cultured transgenic and WT plants treated by sufficient and deficient N were further subjected to measurement of the photosynthetic and ROS-associated parameters. The photosynthetic parameters assayed included photosynthetic rate (P n), PSII efficiency (ΦPSII), and nonphotochemical quenching (NPQ), which were measured as described by Guo et al. (2013). The ROS-associated parameters evaluated included activities of SOD, catalase (CAT), and peroxidase (POD) and contents of malondialdehyde (MDA), H2O2, and superoxide anion, which were determined as described by Liang et al. (2003).
Transcriptome Analysis of the Transgenic and WT Plants Under N Deprivation
Total RNA in root tips of the transgenic (lines 3 and 5) and WT seedlings after 48 h of the N-deficient treatment was extracted using TRIzol Reagent (Invitrogen) then cleaned and concentrated with RNeasy MinElute Cleanup Kit (Qiagen, Valencia, CA). Seven hundred nanograms of cleaned total RNA was then used to synthesize the Cy3-labeled cDNAs (Agilent’s RNA Spike-in Kit) and then subjected to hybridization analysis using an Agilent’s 4×44K tobacco chip following manufacturer’s suggestions. After hybridization, the chips were washed using the ready-made solutions and treated with Agilent’s Stabilization and Drying solutions (product number 5190-0423). The signals on chips were scanned (Agilent Technologies Scanner, model G2565CA) and generated the numeric data using the software (Agilent Feature Extraction software, version 10.5.1.1). The tool of R Project for Statistical Computing was used to analyze the raw numerical data set. Three biological replicates were conducted for each sample to yield reproducible results. An associative analysis approach was used to define the differential genes as described by Dozmorov and Centola (2003)), in which a false discovery rate (FDR) cutoff of 0.01 was used in defining the differential genes, whose transcripts showed absolute values over 2.0 on fold change between the transgenic and WT plants. Gene biological functions were specified according to roles in GO biological processes of their homologs in Arabidopsis.
Expression Analysis of the Randomly Selected Differential Genes in the Microarray Analysis
Twenty-two of differential genes identified in the microarray analyses, including 12 upregulated and 10 downregulated, were subjected to expression analysis based on qPCR to verify the microarray results. The qPCR was performed as aforementioned using the cDNAs in microarray analysis as templates and specific primer (Table S2).
Expression Analysis of AEE and NRT Genes of the Transgenic and WT Plants
Five, 6, and 11 genes encoding SOD, CAT, and POD, respectively, together with 6 genes encoding NRTs in tobacco, were subjected to detection of transcripts to determine whether any of them are involved in improving the antioxidant enzymatic activities and the N acquisition mediated by TaMIR444a. The SOD genes analyzed included NtMnSOD1 (X14482), NtSOD1 (KJ874395), NtFeSOD (KF724056), NtSOD2 (EU123521), and NtMnSOD2 (AB093097); the CAT genes examined included NtCAT (EF532799), NtCAT1 (NTU07627), NtCAT1;1 (NTU93244), NtCAT1;2 (HF564632), NtCAT1;3 (HF564631), and NtCAT3 (HF564633); and the POD genes evaluated included NtPOD1;1 (L02124), NtPOD1;2 (AB044154), NtPOD1;3 (AB044153), NtPOD1;4 (D11396), NtPOD1;5 (AB178953), NtPOD1;6 (AB027753), NtPOD1;7 (AB027752), NtPOD2;1 (AB178954), NtPOD2;2 (KF701483), NtPOD4 (AY032675), and NtPOD9 (AY032674). The NRT genes examined included NtNRT1.1-s (AB102805), NtNRT1.1-t (AB102806), NtNRT1.2-s (AB102807), NtNRT1.2-t (AB102808), NtNRT2.1 (AJ557583), and NtNRT2.2 (AJ557584). qPCR analyses were performed as mentioned above to assess the transcripts of these genes in transgenic (lines 3 and 5) and WT seedlings treated by 48 h of N deprivation, with specific primers (Table S3).
Statistical analysis
Averages of gene expression levels in qPCR analysis, plant dry mass, concentrations and contents of N, photosynthetic parameters, antioxidant enzymatic activities, and MDA contents were derived from the results of four replicates. Standard errors of the averages and the significant differences among averages were analyzed by using the Statistical Analysis System software (SAS Corporation, Cory, NC, USA).
Results
TaMIR444a and NtMIR444a Are Induced Whereas the Target Genes Are Downregulated by N Deprivation
TaMIR444a and NtMIR444a share an identical precursor sequence based on PCR analysis, although the latter has not been released in the miRNA database (Release 21, www.mirbase.org). The precursor sequences of TaMIR444a and NtMIR444a are shown in Fig. S1. This finding indicates that miR444a acts as a conserved miRNA member across plant species of dicots and monocots.
TaMIR444a and NtMIR444a showed similar expression patterns under various external N conditions. Under N sufficiency, they exhibited low expression levels in roots and leaves. Upon exposure to the N-starvation stress, the transcripts of these miRNAs were significantly induced in roots and leaves, showing a pattern to be gradually increased over a 48-h treatment (Fig. 1a, b; Fig. S2). Once treated by a N recovery treatment, the transcripts of the miRNAs in roots and leaves were swiftly downregulated and restored gradually to the prestimulus level after a 48-h treatment (Fig. 1a, b; Fig. S2). In addition, the miRNA members kept high expression levels under longer N starvation conditions (3, 7, and 14 d), which were comparable to those treated by 48 h of N deprivation (Fig. S3). This finding suggests that miR444a is transcriptionally upregulated by N deprivation with an expression pattern of typical concentration- and temporal-dependent manner.
TaMI444a was predicted to target eight genes including those encoding MIKC-type MADS-box TF WM32B (TaWM32, TC368997), maturase K (TaMK, TC410100), MGC80202 protein (TaMGC, CV775588), expressed protein (unknown gene 1, TC450645), MIKC-type MADS-box TF WM30 (TaWM30, TC370370), one encoding unannotated protein (unknown gene 2, CA648881), MIKC-type MADS-box TF (TaMADS, TC424265), and GRAS family TF (TaGRAS, CA624957); NtMIR444a was shown to target four genes that encode DSK2 (NtDSK2, TC133521), elongation factor 1 (NtEF1, AM833250), pyridoxal kinase (NtPK, AM819983), and olfactory receptor (NtOR, BP131636), respectively (Table 1). A subset of target genes of the miRNAs encodes TFs categorized into MIKC-types and GRAS-type, kinase, and receptor, suggesting the involvement of miR444a in mediating biological processes via modulation of the target genes encoding signaling components. The expression patterns of the target genes exhibited to be contrasting to the miRNAs; namely, they were downregulated by N deprivation, and the reduced expression of them under the N-starvation stress was restored by the N recovery treatment (Fig. 2a–d). Therefore, the responses of these target genes to external N levels are mediated by miR444a possibly through the mechanism of posttranscriptional cleavage. As an exception, a gene encoding an unknown protein (TC450645) targeted by TaMIR444a and a gene encoding an elongation factor (NtEF1, AM833250) targeted by NtMIR444a kept stable transcripts under various N treatments, suggesting that these two targets are regulated by miR444a possibly via the mechanism of translation repression.
Overexpression of TaMIR444a in Tobacco Improves Plant Growth and Dry Mass Production Under N Deprivation
An expression cassette harboring the TaMIR444a precursor sequence was constructed, whose schematic diagram is shown in Fig. 3a. Seven independent transgenic tobacco lines (lines 1 to 7) were generated. The TaMIR444a insertion was detected in the transgenic T3 lines by PCR analysis. Results showed that the selection gene bar was detected in all of the transgenic lines rather than in WT (Fig. 3b), indicating the integration of TaMIR444a into genome of the transgenic lines. Small RNA blot analysis revealed that TaMIR444a expressed in most of transgenic lines (Fig. S4a).
Lines 3 and 5, two transgenic lines with stronger expression of TaMIR444a and different insertion pattern in genome (Fig. S4a and S4b), and WT were subjected to evaluation of the growth feature and dry mass under N sufficiency (6 mM/L N) and N deficiency (60 μmol/L). Under the N-sufficient condition, the transgenic lines showed similar phenotype and dry mass to WT. Under the N-deficient condition, however, the transgenic lines exhibited improved growth feature and dry mass compared with WT (Figs. 4a–d). These results indicate that TaMIR444a acts as a critical regulator in mediating the adaptation to the N-starvation stress.
Overexpression of TaMIR444a Increases Plant N Concentration, N Content, and Photosynthetic and ROS-associated Parameters Under N Deprivation
Similar to the behaviors of phenotype and dry mass, lines 3 and 5 exhibited similar N concentration and N content in roots and aboveground tissues to WT under the N-sufficient condition (Fig. 5a, b); they displayed higher N concentration and more N content in above tissues than WT under the N-deficient condition (Fig. 5a, b). The increased N concentration and N content in transgenic plants under N deprivation indicated that these traits contribute to the TaMIR444a-improved plant growth and dry mass production through improvement of the N acquisition process.
The photosynthetic parameters such as P n, ΦPSII, and NPQ impact largely on plant dry mass accumulation via regulating carbon assimilation capacity, in which ΦPSII reflects the actual potential efficiency of the excitation energy captured by PSII centers and is calculated by (F′ m − F s ) / F′ m (F′ m and F s define the maximum fluorescence in light and actual fluorescence level, respectively); NPQ shows the level of fluorescence quenching due to the slowly relaxing high-energy status of the thylakoids, i.e., directly proportional to the rate constant for the energy dissipation, and is defined by (F m − F′ m ) − 1 (F m means the maximum chlorophyll fluorescence). In this study, investigation on the photosynthetic parameters revealed that the transgenic plants also showed comparable photosynthetic parameters, such as P n, ΦPSII, and NPQ (Fig. 5c–e), antioxidant enzymatic activities of SOD, CAT, and POD (Fig. 6a–c), content of MDA, and amount of H2O2 and superoxide anion, with WT plants under the N-sufficient condition (Fig. 6d–f). Under the N-deficient condition, the transgenic plants exhibited higher P n and ΦPSII and lower NPQ than WT (Fig. 5c–e), higher activities of SOD, CAT, and POD (Fig. 6a–c), lower content of MDA, and less amount of H2O2 and superoxide anion than WT plants (Fig. 6d–f). These results suggested that the TaMIR444a-mediated tolerance to N deprivation is closely associated with the improvement of cellular ROS detoxification that further impacts on N acquisition, photosynthesis behavior, growth feature, and dry mass production of the plants under the N-starvation stress.
Overexpression of TaMIR444a Modifies Largely the Transcriptome of Plants Under N Deprivation
Based on microarray analyses, totally 1733 genes were identified to be differential in the TaMIR444a-overexpressing plants treated by N deprivation, in which 921 were upregulated and 812 were downregulated (Fig. 7a, Tables S4 and S5). qPCR analysis revealed that 22 of the randomly selected differential genes, including 12 upregulated and 10 downregulated, showed comparable expression patterns to those evaluated by microarray analyses (Fig. S5). These results indicate that the differential genes identified in microarray analyses are reproducible. A large number of differential genes were identified in transgenic plants, suggesting that TaMIR444a regulates the transcription of the target genes, whose altered expression can further transcriptionally regulate the downstream genes underlying the TaMIR444a/target modules.
A small number of the differential genes identified in the microarray analyses, including 124 of upregulated and 119 of downregulated, have been annotated to biological roles (Tables S6 and S7). A large quantity of the differential genes is functionally unknown, which is possibly ascribed to the relatively slow progress on tobacco genome sequencing and the gene annotation programs. Based on the biological roles, the upregulated differential genes were grouped into the following categories: signaling perception (with numbers of 2), signal transduction (18), transcription (12), protein metabolism (8), chromosome remodeling (3), primary metabolism (21), secondary metabolism (11), transport (5), oxidative stress defensiveness (6), phytohormone response (1), abiotic stress response (7), biotic stress response (7), cellular structure (8), cell cycling (4), development (2), and miscellaneous (8) (Fig. 7b); the downregulated genes were grouped into the following categories: signaling transduction (with numbers of 16), transcription (11), protein metabolism (4), chromosome remodeling (2), primary metabolism (27), secondary metabolism (16), transport (6), oxidative stress defense (2), phytohormone response (4), abiotic stress response (7), biotic stress response (9), cellular structure (5), cell cycling (1), development (1), and miscellaneous (7) (Fig. 7c). The upregulated and downregulated functional genes, the corresponding group category, probe set in tobacco chip, and expression variation fold under contrasting N levels are listed in Tables S6 and S7.
Together, our investigation indicates that TaMIR444a drastically modifies the transcriptome. The differentially expressed genes mediated by TaMIR444a are possibly associated with the improved adaptation to N deprivation by regulating various biological processes involving N acquisition and internal translocation, ROS homeostasis, carbon assimilation, and dry mass production.
A Set of AEE and NRT Genes Shows Varied Expressions in Transgenic Plants Under N Deprivation
The expression levels of antioxidant enzyme-encoding (AEE) genes and NRT genes were investigated in the N-deprived transgenic and WT plants. Compared with WT, most of the AEE and NRT genes exhibited unchanged expression in the transgenic lines. However, NtCAT1;1, NtPOD4, and NtPOD1;3 that encode antioxidant enzymes and NtNRT1.1-s, NtNRT1.1-t, and NtNRT2.1 that encode NRTs displayed higher expression levels in the transgenic plants than in WT plants (Fig. 8a–c; Fig. 9), suggesting that these AEE and NRT genes are regulated by TaMIR444a and possibly contribute to the increased antioxidant enzymatic activities and N acquisition in the TaMIR444a-overexpressing plants under the N-deficient conditions.
Discussion
Through the mechanisms of posttranscriptional cleavage and translation repression, miRNAs in plant species are involved in the regulation of diverse plant biological processes, such as the development and phytohormone response (Jones-Rhoades et al. 2006) as well as the stress adaptations (Fujii et al. 2005; Jones-Rhoades et al. 2004, 2006; Sunkar et al. 2006; Zhao et al. 2013; Zhao et al. 2014; Zhao et al. 2015). In this study, characterization analysis of TaMIR444a and NtMIR444a, the homologue of TaMIR444a in tobacco, revealed that they sensitively respond to the external N levels, whose transcript abundance was upregulated by N deprivation, and the induced expression levels under the N-starvation stress can be restored to a low level after N recovery treatments. In contrast to the miRNAs, most of the target genes exhibited an opposite expression pattern in responding to the external N conditions. These findings indicate that miR444a can establish the miRNA/target module for mediating plant responses to the N-starvation stress.
Several studies have reported that an array of plant miRNAs involves plant response to N deprivation. In Arabidopsis, miR169 mediates plant N acquisition under N deprivation through targeting two NRT genes, AtNRT1.1 and AtNRT2.1 (Zhao et al. 2011). miR167 regulates plant adaptation to N deficiency by modifying the lateral root initiation (Gifford et al. 2008). Several of wheat miRNAs respond to N deficiency and possibly establish distinct miRNA/target networks to mediate plant tolerance to the N-starvation stress (Zhao et al. 2015). In this study, overexpression of TaMIR444a in tobacco drastically improved a set of growth traits, including growth feature, dry mass production, N concentration and content, photosynthetic parameters, and antioxidant enzymatic activities under the N-deficient conditions. Therefore, TaMIR444a acts as one critical regulator in mediating plant tolerance to the N-starvation stress.
N taken up and internal translocation in plants are associated closely with NRTs (Crawford and Glass 1998). Two nitrate uptake systems evolved in plants, namely, the low-affinity transport and the high-affinity transport, function effectively in mediating plant NO3 − acquisition from soil and internal N translocation under various N conditions (Wang et al. 1998; Liu et al. 1999; Orsel et al. 2002; Li et al. 2007; Kiba et al. 2012). In this study, NtNRT1.1;1, NtNRT1.1;2, and NtNRT2.1, three tobacco NRT genes, were upregulated in the N-deprived plants overexpressing TaMIR444a. These results suggest that the NRT genes are possibly involved in improving the N acquisition in the transgenic plants through mediating N taken up. Previously, miR169a was shown to comprise a module with AtNRT1.1 and AtNRT2.1, two NRT genes in Arabidopsis and involved in mediating the long-distance N signaling transduction under N deprivation (Zhao et al. 2011). The issue of how miR444a regulates the transcription of these differential NRT genes is needed to be further addressed.
In this study, the improved growth feature and dry mass production of the transgenic plants were closely consistent with the increased photosynthetic parameters, such as P n and ΦPSII. Based on microarray analyses, a subset of differential genes associated with photosynthesis metabolism, such as those encoding FtsZ-like chloroplast protein (AJ133453), chloroplast pigment-binding protein CP29 (DQ676843), glucose-6-phosphate 1-dehydrogenase (DW003514), photosystem I psaH protein (X61665), sucrose-phosphate synthase isoform B (DQ213015), chloroplast oxygen-evolving protein 16-kDa subunit (TC126580), and chloroplast carbonic anhydrase (M94135), was identified (Tables S6 and S7). These findings provide a link between the TaMIR444a-mediated carbon assimilation and these differential photosynthesis-associated genes. Further investigation of these genes can shed light on the putative pathway covering miR444a, a carbon assimilation gene, and the photosynthesis behavior in plants under N deprivation.
Cellular ROS are induced under stress conditions including nutrient deficiency (Miller et al. 2008). High levels of antioxidant enzymatic activities can endow plants with improved resistance to the oxidative stress initiated by stress conditions and alleviate the ROS toxicity to plants (Shalata et al. 2001). In this study, overexpression of TaMIR444a endowed plants with enhanced activities of SOD, CAT, and POD and reduced amount of MDA, H2O2, and superoxide anion under N deprivation. These findings indicate that the TaMIR444a-mediated improvement of cellular ROS homeostasis possibly acts as a central regulator in regulating growth feature, photosynthetic parameters, and N acquisition of plants through detoxification of the induced ROS by N deprivation. Three AEE genes NtCAT1;1, NtPOD4, and NtPOD1;3 are possibly involved in improving the antioxidant activities of the TaMIR444a-overexpressing plants through upregulated transcription. Functional analysis of the AEE genes can be helpful to elucidate the mechanism underlying the TaMIR444a-mediated antioxidant activities and these upregulated AEE genes.
Genechip analysis has been widely used in the investigation of the plant transcriptome in responding to internal and external cues (Wang et al. 2000, 2003). Based on a microarray analysis, totally 3008 genes were identified to be regulated by OsmiR156, a conserved miRNA member in rice (Xie et al. 2012). Overexpression of OsmiR156b in swithchgrass significantly modified the expression of 2346 genes in plants, in which 1020 were upregulated and 1326 were downregulated (Fu et al. 2012). These findings indicate that distinct plant miRNA can dramatically modify the plant transcriptome, albeit that the miRNA member targets limited genes (Zhao et al. 2013, 2015). In this study, based on microarray analyses, we identified 1733 genes to show differential expression in the TaMIR444a-overexpressing plants, including 921 upregulated and 812 downregulated (Tables S4 and S5). These results indicate that miR444a can transcriptionally regulate a large number of genes, through it directly regulates the target genes as well as indirectly modulates the genes downstream of the miR444a/target pathways. Functional characterization of the key differential genes through gene overexpression or gene knockout technologies can provide new insights into the miR444a-mediated plant response to the N-starvation stress.
miRNA-mediated plant development and response to stress stimuli are closely associated with the target genes encoding TFs (Zhang and Forde 1998; Williams et al. 2005; Singh et al. 2002). miR159/319, miR160, miR167, and miR396 regulate plant development mainly by posttranscriptional regulation of the target genes encoding TF families of MYBs/TCPs, ARFs, and GRF (Reyes and Chua 2007; Mallory et al. 2005; Liu et al. 2007; Wu et al. 2006). In this study, based on microarray analyses, we identified 22 differential genes in the transgenic plants that encode TFs of MYB, bZIP, WRKY, and ZFP-type members, with 12 upregulated and 10 downregulated. Previously, an Arabidopsis MADS-box gene ANR1 was identified to regulate plant response to the N availability through modulating lateral root development (Gan et al. 2005; Remans et al. 2006). The putative modules comprising miR444a and these differential TF genes are needed to be further defined.
In conclusion, stress-responsive miRNAs mediate plant response to abiotic stresses through reprograming intricate physiological processes and biochemical metabolisms. In this study, we revealed that miR444a is N deprivation-responsive and acts as one critical regulator in mediating plant tolerance to the N-starvation stress. The microarray analyses revealed that TaMIR444a transcriptionally regulates a large number of genes, which are grouped into various functional categories, such as signaling perception and transduction, transcription regulation, protein metabolism, chromosome remodeling, primary and secondary metabolism, transport, oxidative stress defense, phytohormone response, abiotic and biotic stress responses, cellular structure and cycling, development, miscellaneous, etc. Our findings indicate that the TaMIR444a-mediated plant tolerance to N deprivation involves complicated gene networks that modify various physiological and biochemical processes associated with N acquisition, ROS detoxification, carbon assimilation, and plant dry mass accumulation. Further establishment of the regulatory networks covering miR444a and differential genes can provide novel sights into understanding the molecular mechanisms underlying plant response to the external N signaling mediated by miRNA/target pathways.
References
Asha S, Nisha J, Soniya EV (2013) In silico characterization and phylogenetic analysis of two evolutionarily conserved miRNAs (miR166 and miR171) from black pepper (Piper nigrum L.). Plant Mol Biol Rep 31, DOI 10.1007/s11105-012-0532-5
Bari R, Datt PB, Stitt M, Scheible WR (2006) PHO2, microRNA399, and PHR1 define a phosphate-signaling pathway in plants. Plant Physiol 141:988–999
Cai H, Xie W, Lian X (2013) Comparative analysis of differentially expressed genes in rice under nitrogen and phosphorus starvation stress conditions. Plant Mol Biol Rep 31:160–173
Castaings L, Camargo A, Pocholle D, Gaudon V, Texier Y, Boutet-Mercey S, Taconnat L, Renou JP, Daniel-Vedele F, Fernandez E et al (2009) The nodule inception-like protein 7 modulates nitrate sensing and metabolism in Arabidopsis. Plant J 57:426–435
Chiou TJ, Aung K, Lin SI, Wu CC, Chiang SF, Su CL (2006) Regulation of phosphate homeostasis by microRNA in Arabidopsis. Plant Cell 18:412–421
Crawford NM, Glass ADM (1998) Molecular and physiological aspects of nitrate uptake in plants. Trends Plant Sci 3:389–395
Dozmorov I, Centola M (2003) An associative analysis of gene expression array data. Bioinform 19:204–211
Frink CR, Waggoner PE, Ausubel JH (1999) Nitrogen fertilizer: retrospect and prospect. Proc Natl Acad Sci USA 96:1175–1180
Fu C, Sunkar R, Zhou C, Shen H, Zhang JY, Matts J, Wolf J, Mann DGJ, Stewart JCN, Tang Y, Wang ZY (2012) Overexpression of miR156 in switchgrass (Panicum virgatum L.) results in various morphological alterations and leads to improved biomass production. Plant Biotechn J 10:443–452
Fujii H, Chiou TJ, Lin SI, Aung K, Zhu JK (2005) A miRNA involved in phosphate-starvation response in Arabidopsis. Curr Biol 15:2038–2043
Gan Y, Filleur S, Rahman A (2005) Nutritional regulation of ANR1 and other root-expressed MADS-box genes in Arabidopsis thaliana. Planta 222:730–742
Gifford ML, Dean A, Gutierrez RA, Coruzzi GM, Birnbaum KD (2008) Cell-specific nitrogen responses mediate developmental plasticity. Proc Natl Acad Sci USA 105:803–808
Guo C, Li J, Chang W, Zhang L, Cui X, Xiao K (2011) Effects of chromosome substitution on the utilization efficiency of nitrogen, phosphorus, and potassium in wheat. Front Agric China 5(3):253–261
Guo C, Zhao X, Liu X, Zhang L, Gu J, Li X, Lu W, Xiao K (2013) Function of wheat phosphate transporter gene TaPHT2;1 in Pi translocation and plant growth regulation under replete and limited Pi supply conditions. Planta 237:1163–1178
Hirel B, LeGouis J, Ney B, Gallais A (2007) The challenge of imp roving nitrogen use efficiency in crop plants: towards a more central role for genetic variability and quantitative genetics within integrated approaches. J Exp Bot 58:2369–2387
Ho CH, Tsay YF (2010) Nitrate, ammonium, and potassium sensing and signaling. Curr Opin Plant Biol 13:604–610
Ho CH, Lin SH, Hu HC, Tsay YF (2009) CHL1 function as a nitrate sensor in plants. Cell 138:1184–1194
Jin X, Li W, Hu D, Shi X, Zhang X, Zhang F, Fu Z, Ding D, Liu Z, Tang J (2015) Biological responses and proteomic changes in maize seedlings under ntrogen deficiency. Plant Mol Biol Rep 33:490–504
Jones-Rhoades MW, Bartel DP (2004) Computational identification of plant microRNAs and their targets, including a stress induced miRNA. Mol Cell 14:787–799
Jones-Rhoades MW, Bartel DP, Bartel B (2006) MicroRNAs and their regulatory roles in plants. Ann Rev Plant Biol 57:19–53
Ju XT, Xing GX, Chen XP, Zhang SL, Zhang LJ, Liu XJ, Cui ZL, Yin B, Christie P, Zhu ZL et al (2009) Reducing environmental risk by improving N management in intensive Chinese agricultural systems. Proc Natl Acad Sci USA 106:3041–3046
Kiba T, Feria-Bourrellier AB, Lafouge F, Lezhneva L, Boutet-Mercey S, Orsel M, Bréhaut V, Miller A, Daniel-Vedele F, Sakakibara H et al (2012) The Arabidopsis nitrate transporter NR T2.4 plays a double role in roots and shoots of nitrogen-starved plants. Plant Cell 24:245–258
Li W, Wang Y, Okamoto M, Crawford NM, Siddiqi MY, Glass ADM (2007) Dissection of the AtNRT2.1: AtNRT2.2 inducible high-affinity nitrate transporter gene cluster. Plant Physiol 143:425–433
Li B, Qin Y, Duan H, Yin W, Xia X (2011) Genome-wide characterization of new and drought stress responsive microRNAs in Populus euphratica. J Exp Bot 62:3765–3779
Liang YC, Chen Q, Liu Q, Zhang W, Ding R (2003) Exogenous silicon (Si) increases antioxidant enzyme activity and reduces lipid peroxidation in roots of salt-stressed barley (Hordeum vulgare L.). J Plant Physiol 160:1157–1164
Liu KH, Huang CY, Tsay YF (1999) CHL1 is a dual-affinity nitrate transporter of Arabidopsis involved in multiple phases of nitrate uptake. Plant Cell 11:865–874
Liu PP, Montgomery TA, Fahlgren N, Kasschau KD, Nonogaki H, Carrington JC (2007) Repression of AUXIN RESPONSE FACTOR10 by microRNA160 is critical for seed germination and post-germination stages. Plant J 52:133–146
Liu X, Zhao X, Zhang L, Lu W, Li X, Xiao K (2013) TaPht1c4, a high-affinity phosphate transporter gene in wheat (Triticum aestivum L.), plays an important role in plant phosphate acquisition under phosphorus deprivation. Funct Plant Biol 40:329–341
Mallory AC, Bartel DP, Bartel B (2005) MicroRNA-directed regulation ofArabidopsis AUXIN RESPONSE FACTOR17 is essential for proper development and modulates expression of early auxin response genes. Plant Cell 17:1360–1375
Mica E, Gianfranceschi L, Enrico P`M (2006) Characterization of five microRNA families in maize. J Exp Bot 57:2601–2612
Miller G, Shulaev V, Mittler R (2008) Reactive oxygen signaling and abiotic stress. Physiol Plant 133:481–489
Orsel M, Krapp A, Daniel-Vedele F (2002) Analysis of the NRT2 nitrate transporter family in Arabidopsis: structure and gene expression. Plant Physiol 129:886–896
Pant BD, Musialak-Lange M, Nuc P, May P, Buhtz A, Kehr J, Walther D, Scheible WR (2009) Identification of nutrient-responsive Arabidopsis and rapeseed microRNAs by comprehensive real-time polymerase chain reaction profiling and small RNA sequencing. Plant Physiol 150:1541–1555
Remans T, Nacry P, Pervent M (2006) The Arabidopsis NRT1.1 transporter participates in the signaling pathway triggering root colonization of nitrate-rich patches. Proc Natl Acad Sci USA 103:19206–19211
Reyes JL, Chua NH (2007) ABA induction of miR159 controls transcript levels of two MYB factors during Arabidopsis seed germination. Plant J 49:592–606
Shalata A, Mittova V, Volokita M, Guy M, Tal M (2001) Response of the cultivated tomato and its wild salt-tolerant relative Lycopersicon pennellii to salt-dependent oxidative stress: the root antioxidative system. Physiol Plant 112:487–494
Singh KB, Foley RC, Oñate-Sánchez L (2002) Transcription factors in plant defense and stress responses. Curr Opin Plant Biol 5:430–436
Stitt M, Muller C, Matt P, Gibon Y, Carillo P, Morcuende R, Scheible WR, Krapp A (2002) Steps towards an integrated view of nitrogen metabolism. J Exp Bot 53:959–970
Sun Z, Ding C, Li X, Xiao K (2012) Molecular characterization and expression analysis of TaZFP15, a C2H2- type zinc finger transcription factor gene in wheat (Triticum aestivum L.). J Integr Agric 11:31–42
Sunkar R, Zhu JK (2004) Novel and stress-regulated microRNAs and other small RNAs from Arabidopsis. Plant Cell 16:2001–2019
Sunkar R, Kapoor A, Zhu JK (2006) Posttranscriptional induction of two Cu/Zn superoxide dismutase genes in Arabidopsis is mediated by downregulation of miR398 and important for oxidative stress tolerance. Plant Cell 18:2051–2065
Vidal E, Gutiérrez RA (2008) A systems view of nitrogen nutrient and metabolite responses in Arabidopsis. Curr Opin Plant Biol 11:521–529
Wang R, Liu D, Crawford NM (1998) The Arabidopsis CHL1 protein plays a major role in high-affinity nitrate uptake. Proc Natl Acad Sci USA 95:15134–15139
Wang R, Guegler K, LaBrie ST, Crawford NM (2000) Genomic analysis of a nutrient response in Arabidopsis reveals diverse expres-sion patterns and novel metabolic and potential regulatory genes induced by nitrate. Plant Cell 12:1491–1509
Wang RC, Okamoto M, Xing XJ, Crawford NM (2003) Microarray analysis of the nitrate response in Arabidopsis roots and shoots reveals over 1,000 rapidly responding genes and new linkages to glucose, trehalose-6-phosphate, iron, and sulfate metabolism. Plant Physiol 132:556–567
Wang Y, Fu B, Pan L, Chen L, Fu X, Li K (2013) Overexpression of Arabidopsis Dof1, GS1, and GS2 enhanced nitrogen assimilation in transgenic tobacco grown under low-nitrogen conditions. Plant Mol Biol Rep 31:886–900
Williams L, Grigg SP, Xie M, Christensen S, Fletcher JC (2005) Regulation of Arabidopsis shoot apical meristem and lateral organ formation by microRNA miR166g and its AtHD-ZIP target genes. Dev 132:3657–3668
Wong C, Zhao YT, Wang XJ, Croft L, Wang ZH, Haerizadeh F, Mattick JS, Singh MB, Carroll BJ, Bhalla PL (2011) MicroRNAs in the shoot apical meristem of soybean. J Exp Bot 62:2495–2506
Wu MF, Tian Q, Reed JW (2006) Arabidopsis microRNA167 controls patterns of ARF6 and ARF8 expression, and regulates both female and male reproduction. Dev 133:4211–4218
Xie K, Shen J, Hou X, Yao J, Li X, Xiao J, Xiong L (2012) Gradual increase of miR156 regulates temporal expression changes of numerous genes during leaf development in rice. Plant Physiol 158:1382–1394
Yamasaki H, Abdel-Ghany SE, Cohu CM, Kobayashi Y, Shikanai T, Pilon M (2007) Regulation of copper homeostasis by micro-RNA in Arabidopsis. J Biol Chem 282:16369–16378
Yanagisawa S, Akiyama A, Kisaka H, Uchimiya H, Miwa T (2004) Metabolic engineering with Dof1 transcription factor in plants: improved nitrogen assimilation and growth under low-nitrogen conditions. Proc Natl Acad Sci USA 101:7833–7838
Zhang H, Forde BG (1998) An Arabidopsis MADS box gene that controls nutrient-induced changes in root architecture. Science 279:407–409
Zhao M, Zhu JK, Zhang F, Li WX (2011) Involvement of miR169 in the nitrogen-starvation responses in Arabidopsis. New Phytol 190:906–915
Zhao X, Liu X, Guo C, Gu J, Xiao K (2013) Identification and characterization of microRNAs from wheat (Triticum aestivum L.) under phosphorus deprivation. J Plant Biochem Biotechn 22:113–123
Zhao C, Xia H, Cao T, Yang Y, Zhao S, Hou L, Zhang Y, Li C, Zhang X, Wang X (2014) Small RNA and degradome deep sequencing reveals peanut microRNA roles in response to pathogen infection. Plant Mol Biol Rep 32, DOI 10.1007/s11105-014-0806-1
Zhao Y, Guo C, Li X, Duan W, Ma C, Guo L, Wen Y, Lu W, Xiao K (2015) Characterization and expression pattern analysis of microRNAs in wheat (Triticum aestivum L.) under drought stress. Biol Plant 59:37–46
Author information
Authors and Affiliations
Corresponding author
Ethics declarations
Conflict of Interest
The authors declare that they have no conflict of interest.
Funding
This study was funded by the National Natural Science Foundation of China (nos. 31371618 and 31571664), the National Transgenic Major Program of China (no. 2011ZX08008), and the Key Laboratory of Crop Growth Regulation of Hebei Province.
Additional information
Si Gao and Chengjin Guo contributed equally to this work.
Electronic supplementary material
Below is the link to the electronic supplementary material.
Fig. S1
Alignment of precursor sequences of TaMIR444a and its tobacco homologue NtMIR444a (DOC 120 kb)
Fig. S2
Expression patterns of TaMIR444 and NtMIR444a in roots and leaves of wheat and tobacco under the N-sufficient and -deficient conditions detected by semiquantitative RT-PCR (DOC 225 kb)
Fig. S3
Expression patterns of TaMIR444a and NtMIR444a in response to longer N deprivation treatment (DOC 28 kb)
Fig. S4
Molecular characterization of the transgenic tobacco plants (DOC 146 kb)
Fig. S5
Expression patterns of the randomly selected upregulated and downregulated genes detected by microarray analyses (DOC 880 kb)
Table S1
Primers used for gene expression analysis of TaMIR444a and NtMIR444a, their interacting target genes, the internal standard tubulin genes as well as for the selection gene bar (DOC 37 kb)
Table S2
Primers used for gene expression analysis of the randomly selected differential genes in the microarray analysis (DOC 44 kb)
Table S3
Primers used for expression analyses of the tobacco NRT, SOD, CAT, and POD genes (DOC 48 kb)
Table S4
The differentially upregulated genes by TaMIR444a (XLS 286 kb)
Table S5
The differentially downregulated genes by TaMIR444a (XLS 291 kb)
Table S6
Functional groups of the differentially upregulated genes by TaMIR444a (XLS 58 kb)
Table S7
Functional groups of the differentially downregulated genes by TaMIR444a (XLS 58 kb)
Rights and permissions
About this article
Cite this article
Gao, S., Guo, C., Zhang, Y. et al. Wheat microRNA Member TaMIR444a Is Nitrogen Deprivation-Responsive and Involves Plant Adaptation to the Nitrogen-Starvation Stress. Plant Mol Biol Rep 34, 931–946 (2016). https://doi.org/10.1007/s11105-016-0973-3
Published:
Issue Date:
DOI: https://doi.org/10.1007/s11105-016-0973-3