Previous work on gene expression showed that in the early devel opment phase grain metabolic pathways tend to involve embryo differentiation and cell enlarge ment. sellectchem This pattern changes at the soft dough stage and during the late filling phase when grains begin to lose moisture and metabolism switches to senescence and dormancy, processes that might be associated with down regulated patterns of some miRNAs. A complex regulatory network in rice grain development Our results showed that differentially expressed miRNAs seem to regulate large numbers of genes, including many transcription factor genes. In previous microarray ana lyses, a group of transcription factor genes identified to be involved in the transcriptional control of grain filling included a ZIP type transcription factor that was highly expressed in aleurone and endosperm, and certain MYB genes that may be important in regulating gene expres sion in developing rice grains.
On the other hand, NAC domain protein genes regulated by miR164 were implicated in regulating metal mobilization from leaves to seed, as well as grain senescence and nu trient remobilization, while MADS box transcript genes, the targets of miR444, were considered necessary for fruit ripening in tomato and embryo development in Arabidopsis. In addition, hormonal accu mulation and other changes in seeds were shown to affect nitrogen supply and drought tolerance during grain filling, for example, miR160 targets ARFs that can bind auxin response elements to regulate expression of other genes. Novel miRNAs are often expressed at low levels and match their targets with imperfect pairing.
We propose that novel miRNAs may be involved in rice grain development by targeting starch synthesis genes that control the accumulation of starch. Although we were unable to identify the exact cleavage sites on the targets, these novel miRNAs probably regu late their targets by translational inhibition. In light of their important functions in the regulatory network of grain development, future work on these miRNAs and their targets is required. Conclusions This work provides the first small RNA expression ana lysis throughout the entire grain filling phase in an indica rice cultivar. Our small RNA sequencing and chip analysis enlarged the rice miRNA repertoire and con firmed the existence of most conserved, and nearly half of the non conserved, rice miRNAs in developing grains.
Comparison between the three phases of grain filling revealed that these miRNAs and their targets may be involved in diverse pathways, which may also be con served in other cereal plants. Methods Plant materials and Batimastat construction of a small RNA library Baifeng B was grown under normal field conditions. Immature grains were col lected at different developmental stages, milk ripe, soft dough and hard dough. Total RNAs were extracted and equally mixed to construct a library.