ined rapidly from G2 to G3. Some of these expression patterns were consistent with results from northern blot assays. It seems that con served miRNAs were mostly down regulated whereas rice or grass specific miRNAs were up regulated during the course of grain filling. As our website shown in Figure 2B, miR1862, miR1874 and miR1850 were significantly up regulated, whereas miR171, miR160, miR444 and miR530 were down regulated. Inhibitors,Modulators,Libraries The expression of miR2055 could not be confirmed probably because its expression level was too low. MiRNA mediated target mRNA cleavage and target expression patterns during grain filling To further study the potential effects of differentially expressed miRNAs during grain filling, we computationally predicted their targets using the miRU program.
Rapid amplification of 5 cDNA ends was used to validate the cleavage events. As shown in Additional file 7A, most targets of conserved rice miRNAs, such as targets of miR160, miR166, miR171, Inhibitors,Modulators,Libraries miR444 and miR530, were annotated to be similar to those from other studies. However, Inhibitors,Modulators,Libraries the miR1435 target Os04g44354, Inhibitors,Modulators,Libraries a UDP glucuronosyl transferase protein, was not previously reported. Cleavage of Os04g44354 and Os03g43930 oc curred with higher frequencies at the 9th and 12th posi tions of miR1435 and miR166, respectively, in all 12 sequenced clones. This is in contrast to the commonly observed 10th or 11th position of miRNAs, such as the cleavage sites of miR444b. 2 on Os04g38780, and miR160 on Os04g43910 and Os04g59430.
We also observed a putative target, Os10g30150, for the novel miRNA candi Drug_discovery date Can miR 06, where only three of 10 sequenced clones had cleavage sites at the sixth position, the other degraded fragments were not located on the targeted se quence at all. Finally, quantitative real time PCR was used to examine the correlation of the expression pat terns of miRNAs and their targets. Most of the miRNAs were negatively associated with their targets. As shown in Table 3, a large number of targets rice grains from the milky to hard dough stages. The analysis revealed dynamic features of the regulatory network mediated by miRNAs during rice grain development. Small RNA population and novel miRNAs involved in developing grains We obtained nearly 2 million high quality small RNAs from grain samples collected from 6 to 20 DAF. A sig nificant proportion of the small RNAs were 21 nt to 24 nt in length.
In plants, 21 nt miRNAs and trans acting siRNAs have roles in post transcriptional gene silencing by directing mRNA degradation or translational repres sion, whereas 24 nt siRNAs tend to be involved selleck products in DNA and histone modifications that lead to transcrip tional gene silencing. Recently, 24 nt miRNAs were also found to direct DNA methylation. In our sequencing data, the reads of 24 nt small RNAs were nearly 7 fold more frequent than reads for 21 nt small RNAs. The presence of a large popu lation of small RNAs in developing rice grains suggests of differentially expressed miRNAs during grain filling were