Genome-Wide Identification of Reverse Complementary microRNA Genes in Plants

MicroRNAs (miRNAs) are ∼21-nucleotide small RNAs (sRNAs) with essential regulatory roles in plants. They are generated from stem-loop-structured precursors through two sequential Dicer-like 1 (DCL1)-mediated cleavages. To date, hundreds of plant miRNAs have been uncovered. However, the question, whether the sequences reverse complementary (RC) to the miRNA precursors could form hairpin-like structures and produce sRNA duplexes similar to the miRNA/miRNA* pairs has not been solved yet. Here, we interrogated this possibility in 16 plant species based on sRNA high-throughput sequencing data and secondary structure prediction. A total of 59 RC sequences with great potential to form stem-loop structures and generate miRNA/miRNA*-like duplexes were identified in ten plants, which were named as RC-miRNA precursors. Unlike the canonical miRNAs, only a few cleavage targets of the RC-miRNAs were identified in Arabidopsis (Arabidopsis thaliana) and rice (Oryza sativa), and none in Soybean (Glycine max) based on degradome data. Surprisingly, the genomic regions surrounding some of the RC-miRNA target recognition sites were observed to be specifically methylated in both Arabidopsis and rice. Taken together, we reported a new class of miRNAs, called RC-miRNAs, which were generated from the antisense strands of the miRNA precursors. Based on the results, we speculated that the mature RC-miRNAs might have subtle regulatory activity through target cleavages, but might possess short interfering RNA-like activity by guiding sequence-specific DNA methylation.     

Identification of novel stress-regulated microRNAs from Oryza sativa L.

MicroRNAs (miRNAs) are a type of small non-coding RNA found in eukaryotes. They play a key role in gene expression by down-regulating gene expression and are involved in the environment stress response in plants. Although a large number of miRNAs have been identified from Arabidopsis, few studies have focused on Oryza sativa miRNAs, especially on stress-related miRNAs. Five cDNA libraries of small RNAs from rice seedlings treated with cold, dehydration, salinity, and abscisic acid (ABA), as well as wild-type seedlings, were constructed. Seven rice novel miRNAs were identified by Northern analysis, and their expression patterns under different stress treatments were determined. Results showed that the expression of several novel miRNAs was regulated by one or more stress treatments. Our identification of novel stress-related miRNAs in rice suggests that these miRNAs might be involved in rice stress response pathways.     

Heavy metal-regulated new microRNAs from rice

MicroRNAs (miRNAs) are a novel class of short, endogenous non-coding small RNAs that have the ability to base pair with their target mRNAs to repress their translation or induce their degradation in both plants and animals. To identify heavy metal stress-regulated novel miRNAs, we constructed a library of small RNAs from rice seedlings that were exposed to toxic levels of cadmium (Cd²⁺). Sequencing of the library and subsequent analysis revealed 19 new miRNAs representing six families. These cloned new rice miRNAs have sequence conservation neither in Arabidopsis nor in any other species. Most of the new rice miRNAs were up- or down-regulated in response to the metal exposure. On the base of sequence complementarity, a total of 34 miRNA targets were predicted, of which 23 targets are functionally annotated and the other 11 records belong to unknown proteins. Some predicted targets of miRNAs are associated with the regulation of the response to heavy metal-induced stresses. In addition to the new miRNAs, we detected nine previously reported miRNAs and 56 other novel endogenous small RNAs in rice. These findings suggest that the number of new miRNAs in rice is unsaturated and some of them may play critical roles in plant responses to environmental stresses.     

A genome-wide survey of microRNA truncation and 3′ nucleotide addition events in larch (Larix leptolepis)

MicroRNAs (miRNAs) play essential roles in numerous developmental and metabolic processes in animals and plants. Although the framework of miRNA biogenesis and function is established, the mechanism of miRNA degradation or modification remains to be investigated in plants. Mature miRNAs may be truncated or added nucleotides to generate variants. A detailed analysis of small RNA deep sequencing data sets resulted in the cloning of a large number of variants derived from larch miRNAs. Many 5′- and/or 3′-end truncated versions of miRNAs suggested that larch miRNAs might be degraded through either 5′–3′ or 3′–5′. The relative abundance of variants truncated from 3′-end was higher than that of 5′-end for most miRNAs. The addition of adenine, uridine, and cytidine to the 3′-end of miRNAs was globally present, and the subtle variability in isomiR abundance might be regulated and biologically meaningful. It is the first report for cytidine addition in plant, and our examination of published small RNA deep sequencing data sets of Arabidopsis, rice, and moss suggests that cytidine addition to miRNA 3′-end exists broadly in plants. In addition, the nucleotide addition might be associated with 3′–5′ miRNA degradation. Our results provide valuable information for a genome-wide survey of miRNA truncation and modification in larch or plants.     

OsmiR396/growth regulating factor modulate rice grain size through direct regulation of embryo-specific miR408

microRNAs (miRNAs) are promising targets for crop improvement of complex agricultural traits. Coordinated activity between/among different miRNAs may fine-tune specific developmental processes in diverse organisms. Grain size is a main factor determining rice (Oryza sativa L.) crop yield, but the network of miRNAs influencing this trait remains uncharacterized. Here we show that sequestering OsmiR396 through target mimicry (MIM396) can substantially increase grain size in several japonica and indica rice subspecies and in plants with excessive tillers and a high panicle density. Thus, OsmiR396 has a major role related to the regulation of rice grain size. The grain shape of Growth Regulating Factor8 (OsGRF8)-overexpressing transgenic plants was most similar to that of MIM396 plants, suggesting OsGRF8 is a major mediator of OsmiR396 in grain size regulation. A miRNA microarray analysis revealed changes to the expression of many miRNAs, including OsmiR408, in the MIM396 plants. Analyses of gene expression patterns and functions indicated OsmiR408 is an embryo-specific miRNA that positively regulates grain size. Silencing OsmiR408 expression (miR408KO) using CRISPR technology resulted in small grains. Moreover, we revealed the direct regulatory effects of OsGRF8 on OsMIR408 expression. A genetic analysis further showed that the large-grain phenotype of MIM396 plants could be complemented by miR408KO. Also, several hormone signaling pathways might be involved in the OsmiR396/GRF-meditated grain size regulation. Our findings suggest that genetic regulatory networks comprising various miRNAs, such as OsmiR396 and OsmiR408, may be crucial for controlling rice grain size. Furthermore, the OsmiR396/GRF module may be important for breeding new high-yielding rice varieties.

The OsmiR396/Growth Regulating Factor module plays a pivotal role in rice grain size regulation and genetically regulates OsmiR408, which acts as an embryo-specific grain size regulator.     

Enlightenment on the aequorin-based platform for screening Arabidopsis stress sensory channels related to calcium signaling

ProspectLacking an efficient method to isolate mutants in Ca²⁺ signal generation process may limit Ca²⁺ signaling research in rice. Typical forward genetic screening is always useful to find genes involved in Ca²⁺ signaling. Looking back at existing research in rice, rice calcium signal research has only just begun. Following the Arabidopsis mature research methods and techniques, especially the mutant screening system, we expect to find several important Ca²⁺ related calcium sensors which have important agronomic traits in the near future. We are looking forward to great advances in rice calcium signaling research.