Multiple rice microRNAs are involved in immunity against the blast fungus Magnaporthe oryzae.

MicroRNAs (miRNAs) are indispensable regulators for development and defense in eukaryotes. However, the miRNA species have not been explored for rice (Oryza sativa) immunity against the blast fungus Magnaporthe oryzae, the most devastating fungal pathogen in rice production worldwide. Here, by deep sequencing small RNA libraries from susceptible and resistant lines in normal conditions and upon M. oryzae infection, we identified a group of known rice miRNAs that were differentially expressed upon M. oryzae infection. They were further classified into three classes based on their expression patterns in the susceptible japonica line Lijiangxin Tuan Hegu and in the resistant line International Rice Blast Line Pyricularia-Kanto51-m-Tsuyuake that contains a single resistance gene locus, Pyricularia-Kanto 51-m (Pikm), within the Lijiangxin Tuan Hegu background. RNA-blot assay of nine of them confirmed sequencing results. Real-time reverse transcription-polymerase chain reaction assay showed that the expression of some target genes was negatively correlated with the expression of miRNAs. Moreover, transgenic rice plants overexpressing miR160a and miR398b displayed enhanced resistance to M. oryzae, as demonstrated by decreased fungal growth, increased hydrogen peroxide accumulation at the infection site, and up-regulated expression of defense-related genes. Taken together, our data indicate that miRNAs are involved in rice immunity against M. oryzae and that overexpression of miR160a or miR398b can enhance rice resistance to the disease.

Identification of rice blast resistance genes in the elite hybrid rice restorer line Yahui2115.

Rice blast, caused by the ascomycete fungus Magnaporthe oryzae, is one of the most serious rice diseases worldwide. We previously developed an elite hybrid rice restorer line with high resistance to rice blast, Yahui2115 (YH2115). To identify the blast resistance genes in YH2115, we first performed expression profiling on previously reported blast resistance genes and disease assay on monogenic lines, and we found that Pi2, Pi9, and Pikm were the most likely resistance candidates in YH2115. Furthermore, RNA interference and linkage analysis demonstrated that silencing of Pi2 reduced the blast resistance of YH2115 and a Pi2 linkage marker was closely associated with blast resistance in an F2 population generated from YH2115. These data suggest that the broad-spectrum blast resistance gene Pi2 contributes greatly to the blast resistance of YH2115. Thus, YH2115 could be used as a new germplasm to facilitate rice blast resistance breeding in hybrid rice breeding programs.

Identification of two novel waxy alleles and development of their molecular markers in sorghum.

High amylopectin grains of waxy sorghum have a high economic value in the food and bioenergy industries because of their increased starch digestibility and higher ethanol conversion rate compared with wild-type sorghum grains. Mutation in the granule-bound starch synthase (GBSS) gene contributes to the waxy phenotype. Two classes of waxy alleles, wx(a) and wx(b), have been characterized previously. In the present work, we identified two novel types of waxy mutations in the sorghum GBSS gene, designated as wx(c) and wx(d). The wx(c) allele has a G deletion at the 5' splicing site of the ninth intron, causing a shift of the 5' cleavage site; in turn, a reading frame shift occurred and resulted in an early translation termination. The wx(d) allele contained a mutation at the 3' splicing site of the 10th intron, which led to a splicing site shift and resulted in the deletion of five amino acids (GTGKK) in the predicted translation product. Furthermore, cleaved amplified polymorphic sequence (CAPS) markers were developed to detect the wx(c) and wx(d) alleles. With these markers, classification of waxy alleles was performed in nearly 100 sorghum accessions from our breeding program. Most waxy sorghum cultivars in China were either wx(a) or wx(c), implying that these two mutations are preferentially maintained during domestic selection in glutinous sorghum production.