Project description:Reproductive barriers perform a vital role during speciation1. Hybrid weakness, the poor development of hybrids compared to their parents, hinders gene exchange between different species at the postzygotic stage2,3. The molecular and evolutionary mechanisms of hybrid weakness are poorly understood2. Here, we report that two incompatible dominant loci (Hwi1 and Hwi2) involving three genes determine the high temperature-dependent expression of hybrid weakness in interspecific hybrids of rice. Hwi1 comprises two indispensable wild rice (Oryza rufipogon)-specific leucine-rich repeat receptor-like kinase (LRR-RLK) genes, 25L1 and 25L2, for inducing hybrid weakness, and the genes possibly undergo balancing selection. Hwi2, a rare allele that is predominantly distributed in indica rice (Oryza sativa), encodes a secreted putative subtilisin-like protease. Functional analysis indicated that pyramiding of Hwi1 and Hwi2 activates the autoimmune response in the basal nodes of hybrids, interrupting root formation and then impairing shoot growth, likely due to immune signal is transmitted from the basal nodes to the above-ground parts. Considering the nature of RLK activity of Hwi1 and the protease activity of Hwi2, we propose that a certain endogenous signaling molecule produced by Hwi2 is perceived by Hwi1 to activate autoimmunity through ligand-receptor signal transduction. These findings bring new insights into our understanding of reproductive isolation and may benefit rice breeding to maximally utilize invaluable genes from wild rice. We conducted microarray analysis to unravel the global changes in gene expression of a pair of NILs (nearly isogenic lines). Plants were cultivated at constant 20°C for 20 days and then shifted to constant 30°C conditions. The basal nodes of NIL(Hwi1) and NIL(hwi1) were harvested immediately before the temperature shift (set as the 0 point) or at 3, 7 or 15 days after the shift. Three biological replicates (each comprising basal nodes from 15–20 individuals) were used for each time point.

Project description:Hybrid weakness is an important post zygotic reproductive barrier between natural populations. Expression of hybrid weakness can lead to significant decrease in yield and even lethality and is thus an undesirable agronomic trait. We observed that F1 hybrids produced from crossing between any two of three Japonica varieties(CH7, CH8, CH9) exhibit hybrid weakness phenotype. Exploring the molecular mechanism underlying hybrid weakness in important crops like rice is worthy. We used microarrays to obtain a global picture of gene expression changes that occurred in the F1 hybrids with characteristic hybrid weakness phenotype.

Project description:Hybrid weakness is a type of reproductive barrier found in many plant species and is important to plant evolution. Compared with heterosis, hybrid weakness has received less attention in evolutionary genetics studies. In rice, the hybrid weakness of the F1 progenies between the Jamaica- and temperate Japonica-types has been intensively genetically surveyed, and it has been found to be controlled by two complementary genes, Hwc1 and Hwc2. The defective development of the hybrid F1 seedlings was found to be mainly due to abnormal root growth, resulting in non-continuous growth and the eventual lethality of the plants. Detailed genome-wide analyses using the hybrid F1 plant and parents showed that, in contrast to heterosis, in which photosynthesis- and starch metabolism-related genes are preferentially expressed, the abscisic acid (ABA)-response and abiotic-/biotic- and defense-related genes were significantly up-regulated in the roots of the hybrid F1, resulting in suppressed growth of the whole plant. This indicates that the mechanisms of heterosis and hybrid weakness differ and provides informative clues to facilitate the understanding of the mechanisms controlling the reproductive isolation and hybrid weakness.

Project description:Hybrid sterility is a major form of postzygotic reproductive isolation, which is a widespread phenomenon in plants. Hybrids between two subspecies of the Asian cultivated rice (Oryza sativa L.), indica and japonica, are usually highly sterile. A killer-protector system composed of three closely linked genes, ORF3, ORF4 and ORF5 at the S5 locus, has been unveiled to regulate hybrid female fertility. We performed transcriptomic analysis of wild type Balilla, sterile BalillaORF5+ (Balilla with a transformed ORF5+) and fertility-restored BalillaORF3+ORF5+ (Balilla with a transformed ORF3+ and a transformed ORF5+) at S1 (before meiosis), S2 (during meiosis) and S3 (after meiosis) respectively. By comparing the differentially expressed genes in different comparisons, we proposed a model for the mechanisms of the S5 mediated hybrid sterility.

Project description:To study a hybrid weakness of rice, we have employed microarray expression profiling as a discovery platform to identify genes increased or decreased their expression specifically in the hybrid. Expression profiles of ‘Nipponbare’, ‘Jamaica’, and F1 hybrid were analyzed with ‘Rice oligo microarray kit’ of Agilent Technologies.

Project description:This research reports genome-wide measurements of genetic and epigenetic patterns of inheritance through an integrative analysis of BS-seq, RNA-seq, and siRNA-seq data in two inbred parents of the Nipponbare (NPB) and Indica (93-11) variety of rice and their hybrid offspring. We generated integrative maps of whole genome cytosine methylation profiles (BS-Seq), transcriptional profiles (RNA-seq), and small RNA profiles (sRNA-seq) to characterize two rice subspecies, Oryza sativa spp japonica (Nipponbare) and Oryza sativa spp indica (93-11) and their two reciprocal hybrid offspring using Illumina's sequencing-by-synthesis (SBS) platform .

Project description:Asian cultivated rice (Oryza sativa L.) consists of two major subspecies, indica and japonica. Inter-subspecific hybrids between indica and japonica, usually accompanying hybrid sterility, exhibit much more vigorous heterosis than intra-subspecific hybrids. f5 locus, also called S24 or Sb, confers significant effects on hybrid male sterility and segregation distortion. BC14F2 plants with f5-i/i, f5-j/j and f5-i/j genotype respectively, were used to dissect the underlying pathway of f5-caused hybrid male sterility via comparative transcriptome analysis. 350, 421, and 480 differentially expressed genes (DEGs) were identified from f5-i/j vs. f5-j/j, f5-j/j vs. f5-i/i, and f5-i/j vs. f5-i/i respectively. 145 DEGs demonstrated simultaneously differential expression in both f5-i/j vs. f5-j/j and f5-i/j vs. f5-i/i. Enrichment analysis with MapMan and AgriGO indicated that protein and DNA metabolism, and cell control related processes were enriched in the 145 DEGs. Stress and cell control related processes were enriched in the DEGs of f5-i/j vs. f5-j/j and f5-i/j vs. f5-i/i, whereas, these two processes were not enriched in the DEGs of f5-j/j vs. f5-i/i. Biotic and abiotic stress resistance genes were suppressed, which may result in pollen cell more sensitive to various stresses. The down regulation of ascorbate peroxidase (APX) may break the dynamic homeostasis of ROS (reactive oxygen species) and cause oxidative stress, which can damage cellular components. The expression of most of the heat shock protein (HSP) genes, which can protect proteins and cells from been destroyed, were also decreased. Based on these results, a model was proposed to summarize the underlying process for f5-caused rice hybrid male sterility. These results provide significant clues to further dissecting the molecular mechanism of f5-caused intersubspecific reproductive barrier.

Project description:Heterosis is a phenomenon that hybrids exhibit superior performance relative to the parental phenotypes. However, most studies focused on aboveground agronomic traits. Thus, systematic investigation on root heterosis, particularly at reproductive stage in rice is needed to be carried out. The recent advent of RNA sequencing technology (RNA-Seq) provides an opportunity to conduct in-depth transcript profiling for heterosis study.Using the Illumina HiSeq 2000 platform, the root transcriptome of a super-hybrid rice Xieyou9308 and its parents were analyzed at tillering and heading stages. Totally, 829 and 4186 differentially expressed genes between the hybrid and its parents (DGHP) were detected at tillering stage and heading stage, respectively. In this study, the DGHP were significantly enriched in pathways such as carbohydrate metabolism and plant hormones signal transduction at heading stage, and most of the key genes involved in the two pathways were up-regulated in the hybrid. Several significant DGHP that could be mapped to QTLs for yield and root traits were also involved in carbohydrate metabolism and plant hormones signal transduction pathways. The candidate transcripts may underlie the heterosis and significantly contribute to root development and yield production. Root mRNA profiles of a super-hybrid rice Xieyou 9308 and its parents at tillering and heading stages were generated by deep sequencing, in duplicate, on Illumina Hiseq 2000 platform.

Project description:Hybrids and allopolyploids typically exhibit radically altered gene expression patterns relative to their parents, a phenomenon termed “transcriptomic shock.” To distinguish the effects of hybridization from polyploidization on coregulation of divergent alleles, we analyzed expression of parental copies (homoeologs) of 11,608 genes using RNA-seq-based transcriptome profiling in reciprocal hybrids and tetraploids constructed from subspecies japonica and indica of Asian rice (Oryza sativa L.)

Project description:Expression data from rice plants showing hybrid weakness syndrome