- Research article
- Open Access
In Medicago truncatula, water deficit modulates the transcript accumulation of components of small RNA pathways
© Capitão et al; licensee BioMed Central Ltd. 2011
- Received: 3 December 2010
- Accepted: 10 May 2011
- Published: 10 May 2011
Small RNAs (sRNAs) are 20-24 nucleotide (nt) RNAs and are involved in plant development and response to abiotic stresses. Plants have several sRNA pathways implicated in the transcriptional and post-transcriptional silencing of gene expression. Two key enzyme families common to all pathways are the Dicer-like (DCL) proteins involved in sRNAs maturation and the Argonautes (AGOs) involved in the targeting and functional action of sRNAs. Post-transcriptional silencing mediated by AGOs may occur by cleavage or translational repression of target mRNA's, while transcriptional silencing may be controlled by DNA methylation and chromatin remodeling. Thus far, these gene families have not been characterized in legumes, nor has their involvement in adaptation to water deficit been studied.
A bioinformatic search in Medicago truncatula genome databases, using Arabidopsis thaliana AGO and DCL cDNA and protein sequences, identified three sequences encoding for putative Dicer-like genes and twelve sequences encoding for putative Argonaute genes. Under water deficit conditions and mainly in roots, MtDCL1 and MtAGO1, two enzymes probably involved in the processing and activation of microRNAs (miRNAs), increased their transcript levels. mir162 which target DCL1 mRNA and mir168 which target AGO1 mRNA reduced their expression in the roots of plants subjected to water deficit. Three putative genes, MtDCL3, MtAGO4b and MtAGO4c probably involved in DNA methylation mechanisms, increased their mRNA levels. However, the mRNA levels of MtAGO6 reduced, which probably encodes a protein with functions similar to MtAGO4. MtAGO7 mRNA levels increased and possibly encodes a protein involved in the production of trans-acting small interfering RNAs. The transcript abundance of MtAGO12a, MtAGO12b and MtAGO12c reduced under water deprivation. Plants recovered from water deprivation reacquire the mRNA levels of the controls.
Our work demonstrates that in M. truncatula the transcript accumulation of the components of small RNA pathways is being modulated under water deficit. This shows that the transcriptional and post-transcriptional control of gene expression mediated by sRNAs is probably involved in plant adaptation to abiotic environmental changes. In the future this will allow the manipulation of these pathways providing a more efficient response of legumes towards water shortage.
- Water Deficit
- Relative Water Content
- Water Deprivation
- Severe Water Deficit
- PIWI Domain
In plants, the transcriptional and post-transcriptional regulation of gene expression mediated by sRNAs  is involved in several biological processes, ranging from organ differentiation to biotic and abiotic stress responses [2–4]. Small RNAs are divided into two main classes based on their biogenesis: the small interfering RNAs (siRNAs) are processed from perfect and long double-stranded RNAs while miRNAs are processed from single-stranded RNA transcripts that fold back onto themselves producing an imperfectly double-stranded stem loop . The endogenous siRNAs are divided into trans-acting-siRNAs (ta-siRNAs) and heterochromatic siRNAs (hc-siRNAs) .
The pathways of gene silencing mediated by sRNAs share, in plants, four consensus biochemical steps : (1) the biosynthesis of a double strand RNA (dsRNA); (2) the cutting of the dsRNA by a Dicer-like protein (DCL) in 18-25 nt-long sRNAs; (3) the O-methylation of the sRNAs by Hua Enhancer (HEN1), to protect them from degradation through the Small RNA Degrading Nuclease (SDN) class of exonucleases ; and (4) the integration of the sRNAs into an Argonaute (AGO) that associates with other proteins to promote gene silencing by partially or fully complementation with target RNA or DNA.
Plants have at least four different DCL proteins and each generates predominantly a particular class of sRNAs: DCL1 cleaves the imperfect double-stranded stem loop generating the miRNAs with around 21-nt ; DCL2 produces viral siRNAs 22-nt long ; DCL3 generates hc-siRNAs with 24-nt ; and DCL4 generates ta-siRNAs 21-nt long .
Plant DCLs contain six domains: one PAZ, two RNaseIII, one DEAD-helicase box (DEXD/H-box), one DUF283, at least one double-stranded RNA-binding (dsRB) domain and one Helicase-C domain . The PAZ domain binds to double-stranded RNAs at the 3' end . The two RNaseIII domains form an intramolecular dimer and the active site of each domain cleaves the dsRNA . The DExD/H-box domain might have an auto-inhibitory function, because removal of this domain increases the cleavage rate of the human dicer . The DUF283 domain displays affinity to bind the double-stranded RNA-binding domains of the A. thaliana dsRNA binding proteins (DRBs)  suggesting a functional role in the selection of the small RNA processing pathway.
The A. thaliana and Oryza sativa genomes have been completely sequenced and annotated [16, 17]. These plant species encode ten and eighteen AGOs, respectively [16, 17]. Both species share common phylogenetic related AGOs that are divided in three clades . In A. thaliana some AGOs are well studied, for example AGO1 binds the miRNAs to mediate the cleavage of targets mRNAs and together with AGO10 both promote the translational repression of the targets but with different selectivity for the miRNAs [19, 20]. AGO4, AGO6 and AGO9 fall in another clade and they are associated with hc-siRNAs to control DNA methylation . AGO7 in the last clade is implicated in the production of the ta-siRNAs .
The AGO proteins generally contain one variable N-terminal region and one conserved C-terminal region constituted by the PAZ, middle (MID) and PIWI domains . The PAZ domain binds to the 3' end of the guide strand of the sRNAs. The PIWI domain is responsible for the Argonaute slicer activity. The cleavage activity is carried out by the active site on the PIWI domain usually presenting an Asp-Asp-His (DDH) motif [19, 24]. The slicer activity of Argonaute requires a perfect complementarity around the cleavage site of the guide-target duplex . The 5' phosphate group of the sRNA guide strand is buried in a deep pocket at interface between the MID domain and PIWI domain .
In A. thaliana, the sRNAs association with the Argonaute proteins is based on the recognition of the 5' end nucleotide. This specificity is mediated by the MID domain . For example AGO1 binds mainly to RNAs with a uridine at their 5' end, whereas AGO2, AGO4, AGO6 and AGO9 recruit RNAs with a 5' end adenosine and the AGO5 predominantly binds to sRNAs with a cytosine [21, 26].
The biogenesis of miRNAs is under feedback regulation such that two key players are themselves regulated by miRNAs. DCL1 mRNA has a complementary sequence for miR162, which leads to the cleavage of DCL1 mRNA . Likewise, AGO1 mRNA contains a complementary sequence for miR168 which leads to AGO1-mediated cleavage of AGO1 mRNA .
Medicago truncatula is a model legume , and its genome is almost completely sequenced (accessed 2 April 2010) . However, almost nothing is known about the identification and function of AGO and DCL genes in legumes species. In M. truncatula several sRNAs were found to be differentially expressed in different organs and abiotic stress conditions [2, 3, 31, 32]. Recently we described the up-regulation of miR398a/b and miR408 under water deficit and the corresponding down regulation of their respective targets, COX5b and plantacyanin . However, no studies have been reported implicating the modulation of small RNA pathways in response to either water deficit or any other abiotic stress in legumes.
In the present study we identify three putative DCL and twelve putative AGO genes in the M. truncatula genome. We also established their phylogenetic relationship with the A. thaliana DCLs (AtDCLs) and AGOs (AtAGOs) and performed their domain characterization. The mRNA levels of these genes were quantified by quantitative real time PCR (qPCR) in vegetative growing plants under water deficit conditions. Our results show that the mRNA levels of the identified AGO and DCL genes are modulated when M. truncatula is subjected to water deprivation.
Plant material, growth and treatment conditions
Medicago truncatula Gaertn. cv. Jemalong seeds were scarified and sterilized in concentrated anhydrous sulfuric acid for 15 minutes according to Araújo et al . After thoroughly washing with sterile water, seeds were placed on soaked filter paper in Petri dishes in the dark at 24°C. Three days later the seeds were transferred to a growth chamber (thermoperiod of 25/18°C, photoperiod of 16/8 h day/night, relative humidity of 40% and a Photosynthetic Photon Flux Density (PPFD) of 500μmol m−2 s−1). One week old seedlings were transferred to vermiculite for 2 weeks and then individually transferred to 0.5 L pots with standard commercial non-sterile soil ("terra de Montemor", Horto do Campo Grande, Lisboa, Portugal). No nutrients were added to avoid any interference with the nodulation. The water status and physiological conditions of the different experimental groups were described in Nunes et al (2008) . Briefly, eight-weeks-old plants were divided into four groups. The Control group (Ct, with a relative water content (RWC) = 80%) was constituted by plants maintained fully irrigated (maximum soil water capacity) (Additional file 1). The second and third groups were constituted by plants subjected to water deprivation for five (Moderate Water Deficit, MWD, RWC = 50%) and eight days (Severe Water Deficit, SWD, RWC = 30%). This severe time point was selected because above this point plants were unable to recover and quickly died. The fourth group consisted of the SWD plants that were re-watered for three days following water deficit, and so regained their original water status (Rec, RWC = 80%). All plants were nodulated when water uphold was started. The control plants always showed healthy nodules. At the severe water deficit condition most of the nodules senesced, but after 3 days of re-watering the nodules restart to develop.
Identification of putative Dicer-like and Argonaute genes in M. truncatula
The mRNA and protein sequences of A. thaliana DCL and AGO genes were downloaded from the National Center for Biotechnology Information (NCBI) database  (Additional file 2). The algorithms BLASTn and tBLASTn were used to search the nucleotide sequence of the genes of interest, using a cut-off E-value of e-20, in the NCBI database , in the DFCI M. truncatula Gene index version 9.0 (MtGI9.0) and in the M. truncatula genome release version 3.0 (Mt3.0), using CViT-Blast and IMGAG-Blast .
Characterization of the M. truncatulaDicer-like and Argonaute genes
The protein and nucleotide sequences of M. truncatula DCLs and AGOs were downloaded from MTGI9.0 and Mt3.0 databases. For MtAGO11 and MtAGO12b the annotation given by the Fgenesh algorithm was chosen. Fgenesh (Medicago matrix) is one of the gene prediction algorithms used in M. truncatula genome annotation by IMGAG (International Medicago Genome Annotation Group) [38, 39]. In cases where the protein sequence was not available, the translation of the nucleotide sequence was done with the Translate software from Expert Protein Analysis System (ExPASy) . The end of protein translation was considered when the first stop codon appeared. The longest amino acid sequence from the 6 possible reading frames was selected. The newly identified genes in this study were named based on the nomenclature used in A. thaliana and on their family phylogenetic relationships. Protein isoelectric point (Pi) was determined with the Protein Isoelectric Point software and calculation of protein molecular weight (MW) was performed using the Protein Molecular Weight software, both software are from the Sequence Manipulation Suite (SMS) package (version 2.0) [41, 42].
Protein domain search
Domain search was performed in the NCBI Conserved Domain Database (NCBI-CDD) [43–45]. The catalytic amino acids characteristic of the AGO proteins were identified aligning the PIWI domain sequences of M. truncatula and the known amino acid positions of A. thaliana AGO1 protein. The identification of the amino acid that separates the MID domain from the PIWI domain of MtAGOs protein sequences was obtained from the alignment of Thermus thermophilus AGO (gi:46255097)(PIWI start - 544), Pyrococcus furiosus AGO (gi:18976909)(PIWI start - 544), Aquifex aeolicus AGO (gi:15606619) (PIWI start - 487), human PIWI (gi:24431985) (PIWI start - 731), human AGO1 (gi:6912352)(PIWI start - 575) and human AGO2 (gi: 29171734)(PIWI start - 577) , with the AtAGOs and MtAGOs.
Protein sequence alignment and phylogenetic tree building
The complete protein sequence of each putative AGO or DCL gene was used for the construction of the phylogenetic tree. Protein alignment was done using T-Coffee software [46–48]. The phylogenetic tree was generated with MEGA4.0 software  using the distance model for amino acid substitution of Jones-Taylor-Thornton (JTT) matrix, the Neighbor-joining algorithm for clustering and 1000 replications for the bootstrap analysis.
RNA Extraction and quantitative Real Time PCR (qPCR)
Extraction of total RNA from the shoots and roots of four plants per treatment was done as previously described . The RNA samples were treated with the TURBO DNA-free Kit (Ambion, Austin, Texas, USA) to eliminate DNA contaminations. Total RNA pools from shoots and roots and per treatment were made. The RNA quantification was performed using the NanoDrop 1000 Spectrophotometer (Thermo Scientific, Waltham, Massachusetts, USA). After DNAse digestion, the absorbance ratios of the RNA samples at 260/280 nm and 260/230 nm were between1.9-2.0. One μg of RNA from each pool was reverse transcribed using the Promega-ImProm-II™ Reverse Transcription System (Promega, Madison, Wisconsin, USA) according to the manufacturer's instructions, using the poly-T oligonucleotide primer. Three independent reverse-transcription reactions (RT) were performed using the RNA pools and each one was diluted 5-fold before each quantitative Real Time Polymerase Chain Reaction (qPCR) reaction.
PCR primers (Additional file 3) were designed using the Beacon Designer software (version 7.0) (Premier Biosoft International, Palo Alto, California, USA). Primers were designed to have a size between 18-24 bp, GC content of 40-60% and melting temperature (Tm) of 58-62°C. The MtAGO1 and MtDCL1 primer pairs were designed to amplify a region containing the cleavage site of miR168 and miR162 respectively. Other criteria, such as primer self-annealing, were also taken into account. Predicted fragment size ranged between 80 and 180 bp. Oligonucleotides were synthesized by Stabvida (Stabvida, Caparica, Portugal).
qPCR reactions were performed in an iQ™5 Real-Time PCR Detection System (Bio-Rad Laboratories, München, Germany), by adding 10μl of iQ™ SYBR Green Supermix (Bio-Rad Laboratories), 4μL of diluted cDNA, 0.5 pmol of each primer, and water to a final volume of 20μL. After one initial incubation step at 95°C for 3 min, amplifications were performed for 40 cycles with the following cycle profile: a denaturing step at 95°C for 15 s followed by an annealing step at 60°C for 10 s, and an extension step of 72°C for 10 s. Fluorescence data were collected during the 72°C step, and the specificity of qPCR products was confirmed by performing a melting temperature analysis at temperatures ranging from 55°C to 95°C in intervals of 0.5°C. PCR products were run in a 2.5% agarose gel to confirm the existence of a unique band with the expected size.
Reference genes were selected based on a previous study where the accumulation of HDA3, L2, APRT, ELF-1α, ACT7 and ACT11 (Additional file 3) was quantified on cDNAs from the plants with different water status and plant organs (shoots and roots) using the geNorm  and NormFinder  in Genex software (version 4.3.8) (MultiD, Göteborg, Sweden). L2 was found to be the best reference gene for the experimental conditions (Ct, MWD, SWD and Rec) and plant organs (shoots and roots) used in this work.
For all the genes studied, three independent cDNA samples of the RNA pools from each experimental condition were amplified in technical duplicates, giving a total of 6 replicates for each treatment. The raw, background-subtracted, fluorescence data provided by the iQ5 software (version 2.0) was analyzed by the real-time PCR Miner software (version 2.2) [52, 53]. The resulting PCR efficiency and cycle number quantification were used for transcript quantification. The efficiency for each gene was calculated using the arithmetic mean of all efficiencies given by PCR Miner.
The Pfaffl method  was used for the relative quantification of the transcript accumulation of the genes of interest using L2 as reference gene. For each gene the results were normalized against the shoot control treatment. The One Way ANOVA Test of significance was used to compare the four conditions in each organ followed by the Tukey Test (SigmaStat version 3.5, Systat Software Inc., San Jose, California).
miR162 and miR168 northern blot analysis
Total RNA (15μg per lane) was blotted to a Hybond-NX membrane (GE Healthcare, Piscataway, NJ, USA) and hybridized according to Trindade et al . Small nuclear RNA U6 was used as a loading control. The Locked Nucleic Acid (LNA)-modified oligonucleotides (Exiqon, Vedbaek, Denmark) complementary to miR168 and miR162 and the molecular weight probes were labeled with γP32-ATP (PerkinElmer, Waltham, Massachusetts, USA) according to Trindade et al . Membranes were striped with boiling 0.1% SDS and hybridized with the small nuclear RNA U6 loading control probe.
Molecular characterization of MtDCLs and MtAGOs
Characteristics of Dicer-like and Argonaute coding sequences and proteins identified in M. truncatula.
IMGAG Gene Loci
M. truncatulaDCL and AGO protein domains
The protein domains searches using the CDD software from NCBI revealed the presence of DExD, Helicase-c, DUF283, PAZ, RNaseIIIa/b and dsRBa/b in the predicted DCL protein sequences analyzed (Figure 3, B). MtDCL2 has only one dsRB domain, similar to the A. thaliana, Oryza sativa and P. trichocarpa DCL2 proteins .
Crystal structure of a full-length Argonaute protein, from the archaea species Pyrococcus furious, showed that the sequence motif originally defined as PIWI domain by Cerutti et al  consists of two structural domains, termed MID and PIWI . Wang et al,  identified the amino acid that separates the MID domain from the PWI domain in Thermus thermophilus (Tt), Pyrococcus furiosus (Pf), Aquifex aeolicus (Aa) and human (Hs) AGO protein sequences . The CDD software can only find the PIWI domain defined by Cerutti et al  and does not separates the MID and PIWI domains. We aligned these protein sequences together with MtAGOs and AtAGOs, to find the domains separation amino acid (Additional file 7).
Almost all predicted MtAGO proteins presented the domains DUF1785, PAZ, MID and PIWI (Figure 1, B). An exception to this is MtAGO12b where the DUF1785 and the PAZ domain are missing. There are several N entries upstream of the start codon, indicating that the sequence quality at that site is not good. MtAGO12c contains one incomplete MID domain and lacks the PIWI domain, but this fact is unexplainable.
Several structural studies have shown that the PIWI domain folds similar to RNaseH proteins . Consistent with this observation, some plant and animal Argonaute proteins are known to cleave the target mRNAs that have sequence complementary to the small RNAs [19, 59]. The catalytic center of these proteins are known to possess three conserved metal chelating amino acid residues in the PIWI domain i.e. aspartate, aspartate and histidine (DDH) that function as a catalytic triad. In A. thaliana AGO1 the histidine at position 800 (H800) was also shown to be critical for this endonuclease activity .
To interrogate which of the predicted MtAGOs included the conserved catalytic residues and could potentially act as the slicer component of the silencing effectors complexes, we aligned the PIWI domains of all the predicted MtAGOs and AtAGOs using T-Coffee (Additional file 7). Two predicted protein sequences, MtAGO1 and MtAGO7 were found to have the conserved domain DDH/H (Figure 1, C). In other MtAGOs like MtAGO12b the motif was missing or the residue H800 substituted by A, S or P, or in MtAGO2 the H (in the DDH motif) is substituted by one D (shifting to a DDD motif), characteristic of AGO2 and AGO3 proteins in A. thaliana and O. sativa .
qPCR of the MtDCLs and MtAGOs
Shoots of plants subjected to water deprivation showed a decrease in the transcript abundance of MtAGO12a, MtAGO12b and MtAGO12c (Figure 4). However a different picture was seen in roots: the mRNA of MtAGO12a was not detected; MtAGO12b maintained its mRNA level under water deficit; and the level of MtAGO12c transcripts decreased significantly following the same pattern found in shoots.
AtDCL3 cleaves endogenous dsRNA producing 24-nt sRNAs and AtAGO4, AtAGO6 and AtAGO9 use these sRNAs to direct transcriptional gene silencing (TGS), which perform chromatin remodeling . MtAGO6 was down regulated under water deficit in shoots and roots (Figure 4 andAdditional file 8). MtDCL3, MtAGO4b and MtAGO4c increased their transcript abundance in similar way under water deficit in both shoots and roots. The mRNA levels of MtAGO11 (a protein similar to AtAGO6 - Figure 1, A) could not be quantified.
AtAGO7 is involved in the biogenesis of trans-acting small RNAs (ta-siRNAs) derived from TAS3 RNA . Both shoots and roots presented an increase in transcript levels of MtAGO7 under water deficit with a very high variation in severe water deficit in the roots (Figure 4 andAdditional file 8).
In Arabidopsis DCL2 cleaves double-stranded virus RNA producing 22nt small RNAs . A small but significant variation was found for the accumulation of MtDCL2 transcripts in shoots under MWD condition. In the roots no significant variation was found along the water deficit treatments and recovery (Figure 4).
The function of AtAGO2 is not clear but has a distinct characteristic from other AGOs, it is highly specific for small RNAs with a 5' terminal adenosine . Under water deficit MtAGO2a transcripts levels increased while MtAGO2b remained almost stable in both shoots and roots (Figure 4).
Expression of miR162 and miR168a/b and their targets during water deficit
The expression of both miR168 and miR162 did not seem to change in the shoots of plants subjected to water deficit and in the recovered plants when compared with the controls (Figure 5). On the other hand both miRNAs decrease their accumulation in roots subjected to water deficit and their expression did not returned to the control levels when plants were re-watered. It seems that only in the roots and especially for the MtDCL1 a post transcriptional control mediated by miRNAs is taking place (Figure 4 and 5).
In the present work we have identified 3 putative DCL and 12 putative AGO genes in the genome of M. truncatula from which only the transcript levels of MtAGO11 could not be detected. Thus far the identification and characterization of these important gene families was mostly limited to A. thaliana and O. sativa.
The catalytic center of MtAGOs
The slicing activity has been demonstrated for A. thaliana AGO1, AGO2, AGO4 and AGO7 [19, 22, 61, 62] and almost all of them have a catalytic center carrying a DDH motif also found in animal AGOs . The exception is AtAGO2, which has a DDD motif (Figure 1, C) . In Homo sapiens the AGO3 protein has a DDH motif but without a slicing activity [59, 63]. On the other hand, the Drosophila melanogaster PIWI domain has one DDK motif and has catalytic activity . In conclusion, the existence or absence of a DDH motif does not necessarily imply a slicing activity. Baumberger and Baulcombe  showed that the histidine residue in position 800 is essential for the slicing activity of AtAGO1. However AtAGO4 has a serine residue instead of a histidine in position 800 but still has slicing activity. Therefore the existence of this residue in Argonautes may not be an obligatory determinant for their cleavage activity. The DDH/H or DDD/H motifs are present in MtAGO1, MtAGO2a and MtAGO7 (Figure 1, C) and are homologous to AtAGO1, AtAGO2 and AtAGO7, indicating that they probably have slicing activity in M. truncatula. It is also possible that MtAGO4s, MtAGO6, MtAGO11, MtAGO12a and MtAGO12 presenting a DDH/(A/S/P) motif and MtAGO11 and MtAGO2b presenting a DDD/S motif may have as well a slicing activity.
MtDCL1 mRNA levels increased in M. truncatula under water deficit (Figure 4), which may imply the increase of mature miRNAs. DCL1 is subjected to negative feedback regulation by miR162 . In our case, miR162 is less accumulated in the roots under water deficit, having the lowest accumulation in SWD (Figure 5). The correlation of this with the increase of MtDCL1 transcript levels, most notorious in roots under water deficit (Figure 4), probably indicates that the regulation of MtDCL1 by miR162 is relaxed in response to water deprivation, increasing the possibility of a higher DCL1 activity in plants subjected to this stress condition. Since DCL1 is involved in synthesis of miRNAs, this suggests that these sRNAs may play an important role in plant responses or adaptation to water deficit.
AGO1 is the main protein mediating miRNA post-transcriptional directed regulation and ago1 mutants show several developmental defects . The AGO1 homeostasis is maintained by the post-transcriptional regulation of AGO1 by miR168 and the stabilization of miR168 levels by AGO1 . Another way of regulating AGO1 is through AGO1-derived short interfering RNAs (siRNAs). However, for this type of regulation to happen it is required that these siRNAs were produced by DCL2 and DCL4 . Three enzymes, RNA-dependent RNA polymerase (RDR6), Suppressor of gene silencing 3 (SGS3) and Silencing Defective 5 (SDE5) are involved in double strand RNA (dsRNA) production from the cleaved mRNA of AGO1. In addition Mallory et al.  demonstrated that AGO10 is a negative regulator of AGO1 levels and Brodersen et al  showed that AGO10 together with AGO1 mediate the translational repression of miRNAs targets in a miRNA-dependent manner.
In our case we observe that the transcript levels of MtAGO1 increased in M. truncatula under water deficit (Figure 4). However we could not correlate this with the variation of miR168 accumulation (Figure 5). Vaucheret et al.  verified that the over-accumulation of AGO1 causes developmental defects in Arabidopsis which means that the homeostasis of AGO1 is important to stabilize the functioning of the miRNA pathway. More evidence is needed to understand the MtAGO1 transcript increase in water deprived M. truncatula plants although this indicates an implement of the activity of miRNAs.
MtAGO12a, MtAGO12b and MtAGO12c
MtAGO12a, MtAGO12b and MtAGO12c are similar to AtAGO10 as shown by BLASTn and BLASTp (Table 1) and have the highest homology with AtAGO10 (Figure 1, A). In A. thaliana, AGO10 promote the translation repression of some miRNAs targets . Giving these homologies MtAGO12 enzymes probably share the same functionalities with AtAGO10. In M. truncatula shoots MtAGO12b and MtAGO12c transcript levels decreased in response to water deficit, suggesting that the mechanism of translation repression mediated by MtAGO12s is probably being shut down. In the roots these genes are differentially expressed, suggesting that they could have the same function but have evolved to respond differentially to water deficit, in a similar way to what was observed with the rice OsAGO1a-d under different stress conditions .
Argonaute 7 specifically associates with miR390 and directs the cleavage at the 3' end of its non-coding target TAS3 RNA [22, 68]. The TAS3 cleavage products are stabilized by Suppressor of Gene Silencing 3 (SGS3), and one of the two TAS3 cleavage products is converted to dsRNA by RNA dependent RNA Polymerase 6 (RDR6). Finally this dsRNA is diced by DCL4 into 21-nt trans-acting siRNAs (ta-siRNAs) a process assisted by a dsRNA binding protein 4 (DRB4). The bioinformatic search for DCLs in M. truncatula, could not find a homolog sequence to A. thaliana DCL4, possibly because the M. truncatula genome is not yet fully sequenced. Nevertheless, three annotated genes homologous to the Auxin Response Factor 3 (ARF3) of A. thaliana were identified in the M. truncatula genome by Jagadeeswaran et al.  as targets of two TAS3-derived ta-siRNAs.
A. thaliana AGO7 mutants accelerate the juvenile to adult transition but not the onset of reproductive competence or flowering time . ARF3 over-expression resulted in further acceleration of phase change and severe morphological and patterning defects of leaves and floral organs . In our study we observed that MtAGO7 mRNA levels increased under water deficit in both shoots and roots (Figure 4). Several previous works correlated the role of TAS3 derived ta-siRNAs with plant development processes, but our results indirectly suggest that ARF3 can have a role in plant reaction to water deficit, maybe by repressing the development processes in the plants that are under stress conditions. This correlates with the observed reduction in growth and development of M. truncatula plants subjected to water deprivation when compared with the controls. The expression levels of the TAS3, the three ARF3 genes and TAS3 derived ta-siRNAs from M truncatula should be analyzed under water deficit to test this hypothesis.
Water deficit response in M. truncatulaand chromatin rearrangements
In plants, chromatin gene silencing involves the coordinated action of: (1) a DNA dependent RNA polymerase IV (Pol IVa and Pol IVb) that transcribes genomic regions with transposons and highly repeated sequences [71, 72]; (2) a RNA dependent RNA polymerase 2 (RDR2), that produces a dsRNA sequence from the regions transcribed by RNA Pol IV ; (3) a Dicer-like 3 (DCL3), that cleaves the dsRNA in 24-nt sRNAs [10, 61, 73]; (4) the Argonaute 4 and 6, that are important for the accumulation of specific heterochromatin-related siRNAs, and for DNA methylation and subsequent transcriptional gene silencing [73–75].
We showed that the M. truncatula MtDCL3, MtAGO4b and MtAGO4c transcript levels increased under water deficit situations (Figure 4). However MtAGO4a had no clear response to water deprivation while MtAGO6 mRNA levels decreased. These results might suggest that the chromatin rearrangements may have a role in the plant responses to water deficit. A possible explanation for the differences in the transcript abundance patterns of the MtAGO4s (Figure 4) is that MtAGO4b and MtAGO4c are phylogenetically more related to each other than with MtAGO4a (Figure 1).
Havecker et al.  verified that in Arabidopsis AGO6 is only expressed in the shoot and root growing tips and AGO4 is expressed predominantly in leaves of adult plants and in all flower and embryo developmental stages. Both Argonautes bind to 5' adenosine 24-nt small RNAs meaning that these characteristics do not distinguish their functional diversification. The functional divergence between AGO4 and AGO6 is related with their expression in different tissues and the epigenetic modifications are influenced by interactions between the AGO protein and the different target loci . We identified 3 genes as AGO4 and one as AGO6 in M. truncatula (Figure 1). These genes are possibly expressed in different tissues and have different degrees of interaction for the same loci as well. The increased MtDCL3, MtAGO4b and MtAGO4c mRNA levels under water deficit are very similar in both shoots and roots (Figure 4). Thus it is possible that the spatial production of small RNAs by MtDCL3 coincides with the spatial expression of MtAGO4b and MtAGO4c since they are related with the same mechanism of silencing.
We identified and characterized three DCLs and twelve AGOs genes in the genome of M. truncatula. These genes probably encode enzymes that integrate different sRNA pathways and their transcript levels are modulated in response to water deficit. This modulation is more evident in roots. The processing and activation of miRNAs are up regulated as well as the sRNAs mediated DNA methylation mechanisms and the production of trans-acting small interfering RNAs. Our observations opened an opportunity to study the impact of sRNA metabolism in the response of legumes toward water deficit.
This work was supported by Fundacão para a Ciência e Tecnologia (FCT) through the ERA-NET Plant Genomics initiative ERA-PG/0001/2006. Dulce Santos was supported by a FCT post-doctoral fellowship (SFRH/BPD/33348/2008). We acknowledge Inês Trindade (ITQB) for her technical advice in northern blots and Helena Garcêz for her patient English revision.
- Finnegan EJ, Matzke MA: The small RNA world. Journal of cell science. 2003, 116: 4689-4693. 10.1242/jcs.00838.PubMedView ArticleGoogle Scholar
- Szittya G, Moxon S, Santos DM, Jing R, Fevereiro MP, Moulton V, Dalmay T: High-throughput sequencing of Medicago truncatula short RNAs identifies eight new miRNA families. BMC genomics. 2008, 9: 593-10.1186/1471-2164-9-593.PubMedPubMed CentralView ArticleGoogle Scholar
- Jagadeeswaran G, Zheng Y, Li YF, Shukla LI, Matts J, Hoyt P, Macmil SL, Wiley GB, Roe BA, Zhang W, Sunkar R: Cloning and characterization of small RNAs from Medicago truncatula reveals four novel legume-specific microRNA families. The New phytologist. 2009, 184: 85-98. 10.1111/j.1469-8137.2009.02915.x.PubMedView ArticleGoogle Scholar
- Trindade I, Capitão C, Dalmay T, Fevereiro MP, Santos DMD: miR398 and miR408 are up-regulated in response to water deficit in Medicago truncatula. Planta. 2010, 231: 705-716. 10.1007/s00425-009-1078-0.PubMedView ArticleGoogle Scholar
- Eamens A, Wang MB, Smith NA, Waterhouse PM: RNA silencing in plants: yesterday, today, and tomorrow. Plant physiology. 2008, 147: 456-468. 10.1104/pp.108.117275.PubMedPubMed CentralView ArticleGoogle Scholar
- Farazi TA, Juranek SA, Tuschl T: The growing catalog of small RNAs and their association with distinct Argonaute/Piwi family members. Development. 2008, 135: 1201-1214. 10.1242/dev.005629.PubMedView ArticleGoogle Scholar
- Voinnet O: Origin, biogenesis, and activity of plant microRNAs. Cell. 2009, 136: 669-687. 10.1016/j.cell.2009.01.046.PubMedView ArticleGoogle Scholar
- Ramachandran V, Chen X: Degradation of microRNAs by a family of exoribonucleases in Arabidopsis. Science. 2008, 321: 1490-1492. 10.1126/science.1163728.PubMedPubMed CentralView ArticleGoogle Scholar
- Kurihara Y, Watanabe Y: Arabidopsis micro-RNA biogenesis through Dicer-like 1 protein functions. Proceedings of the National Academy of Sciences. 2004, 101: 12753-12758. 10.1073/pnas.0403115101.View ArticleGoogle Scholar
- Xie Z, Johansen LK, Gustafson AM, Kasschau KD, Lellis AD, Zilberman D, Jacobsen SE, Carrington JC: Genetic and functional diversification of small RNA pathways in plants. PLoS biology. 2004, 2: E104-10.1371/journal.pbio.0020104.PubMedPubMed CentralView ArticleGoogle Scholar
- Yoshikawa M, Peragine A, Park MY, Poethig RS: A pathway for the biogenesis of trans-acting siRNAs in Arabidopsis. Genes & development. 2005, 19: 2164-2175. 10.1101/gad.1352605.View ArticleGoogle Scholar
- Margis R, Fusaro AF, Smith NA, Curtin SJ, Watson JM, Finnegan EJ, Waterhouse PM: The evolution and diversification of Dicers in plants. FEBS letters. 2006, 580: 2442-2450. 10.1016/j.febslet.2006.03.072.PubMedView ArticleGoogle Scholar
- Olmedo G, Guzman P: Processing precursors with RNase III in plants. Plant Science. 2008, 175: 741-746. 10.1016/j.plantsci.2008.07.001.View ArticleGoogle Scholar
- Macrae IJ, Zhou K, Li F, Repic A, Brooks AN, Cande WZ, Adams PD, Doudna JA: Structural basis for double-stranded RNA processing by Dicer. Science. 2006, 311: 195-198. 10.1126/science.1121638.PubMedView ArticleGoogle Scholar
- Qin H, Chen F, Huan X, Machida S, Song J, Yuan YA: Structure of the Arabidopsis thaliana DCL4 DUF283 domain reveals a noncanonical double-stranded RNA-binding fold for protein-protein interaction. RNA. 2010, 16: 474-481. 10.1261/rna.1965310.PubMedPubMed CentralView ArticleGoogle Scholar
- Morel JB, Godon C, Mourrain P, Béclin C, Boutet S, Feuerbach F, Proux F, Vaucheret H: Fertile Hypomorphic ARGONAUTE (ago1) Mutants Impaired in Post-Transcriptional Gene Silencing and Virus Resistance. The Plant Cell. 2002, 14: 629-639. 10.1105/tpc.010358.PubMedPubMed CentralView ArticleGoogle Scholar
- Nonomura K, Morohoshi A, Nakano M, Eiguchi M, Miyao A, Hirochika H, Kurata N: A germ cell specific gene of the ARGONAUTE family is essential for the progression of premeiotic mitosis and meiosis during sporogenesis in rice. The Plant cell. 2007, 19: 2583-2594. 10.1105/tpc.107.053199.PubMedPubMed CentralView ArticleGoogle Scholar
- Kapoor M, Arora R, Lama T, Nijhawan A, Khurana JP, Tyagi AK, Kapoor S: Genome-wide identification, organization and phylogenetic analysis of Dicer-like, Argonaute and RNA-dependent RNA Polymerase gene families and their expression analysis during reproductive development and stress in rice. BMC genomics. 2008, 9: 451-10.1186/1471-2164-9-451.PubMedPubMed CentralView ArticleGoogle Scholar
- Baumberger N, Baulcombe DC: Arabidopsis ARGONAUTE1 is an RNA Slicer that selectively recruits microRNAs and short interfering RNAs. Proceedings of the National Academy of Sciences. 2005, 102: 11928-11933. 10.1073/pnas.0505461102.View ArticleGoogle Scholar
- Brodersen P, Sakvarelidze-Achard L, Bruun-Rasmussen M, Dunoyer P, Yamamoto YY, Sieburth L, Voinnet O: Widespread translational inhibition by plant miRNAs and siRNAs. Science. 2008, 320: 1185-1190. 10.1126/science.1159151.PubMedView ArticleGoogle Scholar
- Havecker ER, Wallbridge LM, Hardcastle TJ, Bush MS, Kelly KA, Dunn RM, Schwach F, Doonan JH, Baulcombe DC: The Arabidopsis RNA-directed DNA methylation argonautes functionally diverge based on their expression and interaction with target loci. The Plant cell. 2010, 22: 321-334. 10.1105/tpc.109.072199.PubMedPubMed CentralView ArticleGoogle Scholar
- Montgomery TA, Howell MD, Cuperus JT, Li D, Hansen JE, Alexander AL, Chapman EJ, Fahlgren N, Allen E, Carrington JC: Specificity of ARGONAUTE7-miR390 interaction and dual functionality in TAS3 trans-acting siRNA formation. Cell. 2008, 133: 128-141. 10.1016/j.cell.2008.02.033.PubMedView ArticleGoogle Scholar
- Jinek M, Doudna JA: A three-dimensional view of the molecular machinery of RNA interference. Nature. 2009, 457: 405-412. 10.1038/nature07755.PubMedView ArticleGoogle Scholar
- Rivas FV, Tolia NH, Song JJ, Aragon JP, Liu J, Hannon GJ, Joshua-Tor L: Purified Argonaute2 and an siRNA form recombinant human RISC. Nature structural & molecular biology. 2005, 12: 340-349. 10.1038/nsmb918.View ArticleGoogle Scholar
- Wang Y, Sheng G, Juranek S, Tuschl T, Patel DJ: Structure of the guide-strand-containing argonaute silencing complex. Nature. 2008, 456: 209-213. 10.1038/nature07315.PubMedPubMed CentralView ArticleGoogle Scholar
- Mi S, Cai T, Hu Y, Chen Y, Hodges E, Ni F, Wu L, Li S, Zhou H, Long C, Chen S, Hannon GJ, Qi Y: Sorting of small RNAs into Arabidopsis argonaute complexes is directed by the 5' terminal nucleotide. Cell. 2008, 133: 116-127. 10.1016/j.cell.2008.02.034.PubMedPubMed CentralView ArticleGoogle Scholar
- Xie Z, Kasschau KD, Carrington JC: Negative Feedback Regulation of Dicer-Like1 in Arabidopsis by microRNA-Guided mRNA Degradation. Current Biology. 2003, 13: 784-789. 10.1016/S0960-9822(03)00281-1.PubMedView ArticleGoogle Scholar
- Vaucheret H, Vazquez F, Crété P, Bartel DP: The action of ARGONAUTE1 in the miRNA pathway and its regulation by the miRNA pathway are crucial for plant development. Genes & development. 2004, 18: 1187-1197. 10.1101/gad.1201404.View ArticleGoogle Scholar
- Rose RJ: Medicago truncatula as a model for understanding plant interactions with other organisms, plant development and stress biology: past, present and future. The Plant Cell. 2008, 253-264.Google Scholar
- Medicago truncatula Sequencing Resources. [http://www.medicago.org/genome]
- Zhou ZS, Huang SQ, Yang ZM: Bioinformatic identification and expression analysis of new microRNAs from Medicago truncatula. Biochemical and biophysical research communications. 2008, 374: 538-542. 10.1016/j.bbrc.2008.07.083.PubMedView ArticleGoogle Scholar
- Lelandais-Brière C, Naya L, Sallet E, Calenge F, Frugier F, Hartmann C, Gouzy J, Crespi M: Genome-wide Medicago truncatula small RNA analysis revealed novel microRNAs and isoforms differentially regulated in roots and nodules. The Plant cell. 2009, 21: 2780-2796. 10.1105/tpc.109.068130.PubMedPubMed CentralView ArticleGoogle Scholar
- Araújo SDS, Duque As, Dulce Maria Santos DM, Fevereiro MP: An efficient transformation method to regenerate a high number of transgenic plants using a new embryogenic line of Medicago truncatula cv. Jemalong. Plant cell, tissue and organ culture. 2004, 78: 123-131.View ArticleGoogle Scholar
- Nunes C, Araújo SDS, Silva JM, Fevereiro MPS, Silva AB: Physiological responses of the legume model Medicago truncatula cv. Jemalong to water deficit. Environmental and Experimental Botany. 2008, 63: 289-296. 10.1016/j.envexpbot.2007.11.004.View ArticleGoogle Scholar
- National Center for Biotechnology Information. [http://www.ncbi.nlm.nih.gov]
- Basic Local Alignment Search Tool. [http://blast.ncbi.nlm.nih.gov/Blast.cgi]
- Medicago truncatula Sequencing Resources - blast and search. [http://www.medicago.org/genome/blast.php]
- Salamov AA, Solovyev VV: Ab initio gene finding in Drosophila genomic DNA. Genome Research. 2000, 10: 516-522. 10.1101/gr.10.4.516.PubMedPubMed CentralView ArticleGoogle Scholar
- Medicago GBrowse. [http://gbrowse.jcvi.org/cgi-bin/gbrowse/medicago_imgag/]
- ExPASy Proteomics Server. [http://www.expasy.ch]
- Sequence Manipulation Suite: Version 2. [http://www.bioinformatics.org/sms2]
- Marchler-Bauer A, Bryant SH: CD-Search: protein domain annotations on the fly. Nucleic acids research. 2004, 32: W327-W331. 10.1093/nar/gkh454.PubMedPubMed CentralView ArticleGoogle Scholar
- Marchler-Bauer A, Anderson JB, Chitsaz F, Derbyshire MK, DeWeese-Scott C, Fong JH, Geer LY, Geer RC, Gonzales NR, Gwadz M, He S, Hurwitz DI, Jackson JD, Ke Z, Lanczycki CJ, Liebert CA, Liu C, Lu F, Lu S, Marchler GH, Mullokandov M, Song JS, Tasneem A, Thanki N, Yamashita RA, Zhang D, Zhang N, Bryant SH: CDD: specific functional annotation with the Conserved Domain Database. Nucleic acids research. 2009, 37: D205-D210. 10.1093/nar/gkn845.PubMedPubMed CentralView ArticleGoogle Scholar
- Search for Conserved Domains within a protein sequence. [http://0-www.ncbi.nlm.nih.gov.brum.beds.ac.uk/Structure/cdd/wrpsb.cgi]
- Notredame C, Higgins DG, Heringa J: T-Coffee: A novel method for fast and accurate multiple sequence alignment. Journal of molecular biology. 2000, 302: 205-217. 10.1006/jmbi.2000.4042.PubMedView ArticleGoogle Scholar
- Poirot O: Tcoffee@igs: a web server for computing, evaluating and combining multiple sequence alignments. Nucleic Acids Research. 2003, 31: 3503-3506. 10.1093/nar/gkg522.PubMedPubMed CentralView ArticleGoogle Scholar
- T-Coffee. [http://www.ebi.ac.uk/Tools/t-coffee]
- Tamura K, Dudley J, Nei M, Kumar S: MEGA4: Molecular Evolutionary Genetics Analysis (MEGA) software version 4.0. Molecular biology and evolution. 2007, 24: 1596-1599. 10.1093/molbev/msm092.PubMedView ArticleGoogle Scholar
- Vandesompele J, De Preter K, Pattyn F, Poppe B, Van Roy N, De Paepe A, Speleman F: Accurate normalization of real-time quantitative RT-PCR data by geometric averaging of multiple internal control genes. Genome biology. 2002, 3: RESEARCH0034-PubMedPubMed CentralView ArticleGoogle Scholar
- Andersen CL, Jensen JL, Ørntoft TF: Normalization of real-time quantitative reverse transcription-PCR data: a model-based variance estimation approach to identify genes suited for normalization, applied to bladder and colon cancer data sets. Cancer research. 2004, 64: 5245-5250. 10.1158/0008-5472.CAN-04-0496.PubMedView ArticleGoogle Scholar
- Zhao S, Fernald RD: Comprehensive algorithm for quantitative real-time polymerase chain reaction. Journal of computational biology. 2005, 12: 1047-1064. 10.1089/cmb.2005.12.1047.PubMedPubMed CentralView ArticleGoogle Scholar
- Real-time PCR Miner. [http://www.ewindup.info/miner/version2]
- Pfaffl MW: A new mathematical model for relative quantification in real-time RT-PCR. Nucleic acids research. 2001, 29: 2002-2007.View ArticleGoogle Scholar
- Bustin SA, Benes V, Garson JA, Hellemans J, Huggett J, Kubista M, Mueller R, Nolan T, Pfaffl MW, Shipley GL, Vandesompele J, Wittwer CT: The MIQE guidelines: minimum information for publication of quantitative real-time PCR experiments. Clinical Chemistry. 2009, 55: 611-622. 10.1373/clinchem.2008.112797.PubMedView ArticleGoogle Scholar
- Vaucheret H: Plant ARGONAUTES. Trends in plant science. 2008, 13: 350-358. 10.1016/j.tplants.2008.04.007.PubMedView ArticleGoogle Scholar
- Cerutti L, Mian N, Bateman A: Domains in gene silencing and cell differentiation proteins: the novel PAZ domain and redefinition of the Piwi domain. Trends in Biochemical Sciences. 2000, 10: 481-482.View ArticleGoogle Scholar
- Song J-J, Smith SK, Hannon GJ, Joshua-Tor L: Crystal structure of Argonaute and its implications for RISC slicer activity. Science. 2004, 305: 1434-1437. 10.1126/science.1102514.PubMedView ArticleGoogle Scholar
- Liu J, Carmell MA, Rivas FV, Marsden CG, Thomson JM, Song JJ, Hammond SM, Joshua-Tor L, Hannon GJ: Argonaute2 is the catalytic engine of mammalian RNAi. Science. 2004, 305: 1437-1441. 10.1126/science.1102513.PubMedView ArticleGoogle Scholar
- Vazquez F, Blevins T, Ailhas J, Boller T, Meins F: Evolution of Arabidopsis MIR genes generates novel microRNA classes. Nucleic acids research. 2008, 36: 6429-6438. 10.1093/nar/gkn670.PubMedPubMed CentralView ArticleGoogle Scholar
- Qi Y, Denli AM, Hannon GJ: Biochemical specialization within Arabidopsis RNA silencing pathways. Molecular cell. 2005, 19: 421-428. 10.1016/j.molcel.2005.06.014.PubMedView ArticleGoogle Scholar
- Qi Y, He X, Wang XJ, Kohany O, Jurka J, Hannon GJ: Distinct catalytic and non-catalytic roles of ARGONAUTE4 in RNA-directed DNA methylation. Nature. 2006, 443: 1008-1012. 10.1038/nature05198.PubMedView ArticleGoogle Scholar
- Meister G, Landthaler M, Patkaniowska A, Dorsett Y, Teng G, Tuschl T: Human Argonaute2 mediates RNA cleavage targeted by miRNAs and siRNAs. Molecular cell. 2004, 15: 185-197. 10.1016/j.molcel.2004.07.007.PubMedView ArticleGoogle Scholar
- Saito K, Nishida KM, Mori T, Kawamura Y, Miyoshi K, Nagami T, Siomi H, Siomi MC: Specific association of Piwi with rasiRNAs derived from retrotransposon and heterochromatic regions in the Drosophila genome. Genes & development. 2006, 20: 2214-2222. 10.1101/gad.1454806.View ArticleGoogle Scholar
- Vaucheret H, Mallory AC, Bartel DP: AGO1 homeostasis entails coexpression of MIR168 and AGO1 and preferential stabilization of miR168 by AGO1. Molecular cell. 2006, 22: 129-136. 10.1016/j.molcel.2006.03.011.PubMedPubMed CentralView ArticleGoogle Scholar
- Mallory AC, Vaucheret H: ARGONAUTE 1 homeostasis invokes the coordinate action of the microRNA and siRNA pathways. EMBO reports. 2009, 10: 521-526. 10.1038/embor.2009.32.PubMedPubMed CentralView ArticleGoogle Scholar
- Mallory AC, Hinze A, Tucker MR, Bouché N, Gasciolli V, Elmayan T, Lauressergues D, Jauvion V, Vaucheret H, Laux T: Redundant and specific roles of the ARGONAUTE proteins AGO1 and ZLL in development and small RNA-directed gene silencing. PLoS genetics. 2009, 5: e1000646-10.1371/journal.pgen.1000646.PubMedPubMed CentralView ArticleGoogle Scholar
- Allen E, Xie Z, Gustafson AM, Carrington JC: microRNA-Directed Phasing during Trans-Acting siRNA Biogenesis in Plants. Cell. 2005, 121: 207-221. 10.1016/j.cell.2005.04.004.PubMedView ArticleGoogle Scholar
- Hunter C, Sun H, Poethig RS: The Arabidopsis heterochronic gene ZIPPY is an ARGONAUTE family member. Current Biology. 2003, 13: 1734-1739. 10.1016/j.cub.2003.09.004.PubMedView ArticleGoogle Scholar
- Fahlgren N, Montgomery TA, Howell MD, Allen E, Dvorak SK, Alexander AL, Carrington JC: Regulation of AUXIN RESPONSE FACTOR3 by TAS3 ta-siRNA affects developmental timing and patterning in Arabidopsis. Current biology. 2006, 16: 939-944. 10.1016/j.cub.2006.03.065.PubMedView ArticleGoogle Scholar
- Herra J, Jensen MB, Dalmay T, Baulcombe DC: RNA polymerase IV directs silencing of endogenous DNA. Science. 2005, 308: 118-120. 10.1126/science.1106910.View ArticleGoogle Scholar
- Pontier D, Yahubyan G, Vega D, Bulski A, Saez-Vasquez J, Hakimi MA, Lerbs-Mache S, Colot V, Lagrange T: Reinforcement of silencing at transposons and highly repeated sequences requires the concerted action of two distinct RNA polymerases IV in Arabidopsis. Genes & development. 2005, 19: 2030-2040. 10.1101/gad.348405.View ArticleGoogle Scholar
- Chan SW, Zilberman D, Xie Z, Johansen LK, Carrington JC, Jacobsen SE: RNA silencing genes control de novo DNA methylation. Science. 2004, 303: 1336-10.1126/science.1095989.PubMedView ArticleGoogle Scholar
- Zilberman D: ARGONAUTE4 Control of Locus-Specific siRNA Accumulation and DNA and Histone Methylation. Science. 2009, 716-719.Google Scholar
- Zheng X, Zhu J, Kapoor A, Zhu J-kang: Role of Arabidopsis AGO6 in siRNA accumulation, DNA methylation and transcriptional gene silencing. EMBO Journal. 2007, 26: 1691-1701. 10.1038/sj.emboj.7601603.PubMedPubMed CentralView ArticleGoogle Scholar
This article is published under license to BioMed Central Ltd. This is an Open Access article distributed under the terms of the Creative Commons Attribution License (http://creativecommons.org/licenses/by/2.0), which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.