Project description:Self-incompatibility (SI) in flowering plants is a common mechanism that prevents self-fertilization and promotes outcrossing. In Brassicaceae, the locus controlling SI is highly diverse and dozens of distinct alleles are organized in a complex dominance hierarchy: the gene controlling SI specificity in pollen always shows monoallelic expression in heterozygote individuals, and this is achieved through the action of sRNA precursors that resemble miRNAs, although the mechanism behind this remains elusive. Here, we engineered Arabidopsis thaliana lines expressing components of the Arabidopsis halleri SI system and used a reverse genetics approach to pinpoint the pathways underlying the function of these sRNA precursors. We showed that they trigger a robust decrease in transcript abundance of the recessive pollen SI genes, but not through the canonical transcriptional or post transcriptional gene silencing pathways. Furthermore, we observed that single sRNA precursors are typically processed into hundreds of sRNA molecules, with distinct sizes, abundance levels and ARGONAUTE loading preferences. This heterogeneity closely resembles that of proto-miRNAs, the evolutionary ancestors of miRNAs. Our results suggest that these apparent arbitrary features, which are often associated with lack of effects in gene expression, are crucial in the context of the SI dominance hierarchy since they allow one sRNA precursor of a given allele to repress multiple other (more recessive) alleles. This study not only provides an in-depth characterization of the molecular features underlying complex dominance interactions, but also constitutes a unique example of how specific evolutionary constraints shape the progression of sRNA precursors within the proto-miRNA – miRNA evolutionary continuum.

Project description:Self-pollen rejection in the Brassicaceae is determined by the diploid genotype of the pollen-producing plant, and it has long been known that the alleles show a dominance hierarchy. How this hierarchy is controlled and evolves has been a classical puzzle since the pre-molecular days of genetics. Here, we uncover the system of at least 17 small RNA (sRNA) producing loci and their multiple target sites that collectively control the dominance hierarchy among alleles of a self-incompatible Arabidopsis species. Our results demonstrate that natural selection shapes a dynamic repertoire of sRNA/targets interactions by jointly acting on sRNA genes, their processing precision and their target sites. It is remarkable that a single gene can evolve such a complex system of regulation among its own alleles. Sequencing of small RNAs from A. halleri floral buds, with this single exception (Al14, from A. lyrata).

Project description:Self-pollen rejection in the Brassicaceae is determined by the diploid genotype of the pollen-producing plant, and it has long been known that the alleles show a dominance hierarchy. How this hierarchy is controlled and evolves has been a classical puzzle since the pre-molecular days of genetics. Here, we uncover the system of at least 17 small RNA (sRNA) producing loci and their multiple target sites that collectively control the dominance hierarchy among alleles of a self-incompatible Arabidopsis species. Our results demonstrate that natural selection shapes a dynamic repertoire of sRNA/targets interactions by jointly acting on sRNA genes, their processing precision and their target sites. It is remarkable that a single gene can evolve such a complex system of regulation among its own alleles.

Project description:Self-incompatibility (SI) is used by many angiosperms to prevent self-fertilization and inbreeding. In Papaver rhoeas interaction of cognate pollen and pistil S-determinants triggers programmed cell death (PCD) of incompatible pollen. We previously identified that reactive oxygen species (ROS) signals to SI-PCD. ROS induced oxidative post-translational modifications (oxPTMs) can regulate protein structure and function. Here we have identified and mapped oxPTMs triggered by SI in incompatible pollen. Notably, SI-induced pollen had numerous irreversible oxidative modifications; untreated pollen had virtually none. Our data provide the first analysis of the protein targets of ROS in the context of SI-induction and represent a milestone because currently there are few reports of irreversible oxPTMs in plants. Strikingly, cytoskeletal proteins and enzymes involved in energy metabolism are a prominent target. Oxidative modifications to a phosphomimic form of a pyrophosphatase result in a reduction of its activity. Therefore, our results demonstrate irreversible oxidation of pollen proteins during SI and show that this can affect protein function. We suggest that this reduction in cellular activity could lead to PCD.

Project description:Self-inhibition of pollen tubes plays a key role in SI, but the underlying mechanism in Camellia oleifera is poorly understood. Collection of secreted proteins from Camellia oleifera pollen tubes and ovaries for high-throughput sequencing.

Project description:We sequenced mRNA and small RNA (sRNA) profiles in the interaction between Brachypodium distachyon (Bd) and Serendipita indica (Si; syn. Piriformospora indica), at four (4) days post inoculation (DPI). sRNA sequencing reads of Si-colonized and non-colonized roots, as well as axenic fungal cultures were generated. Three biological samples of each were sequenced, with two technical replicates per sample (SE). Raw reads from sRNA sequencing were submitted to technical adapter trimming (Cutadapt) before upload.

Project description:Background: RNA interference (RNAi) is an indispensable regulatory mechanism governing developmental processes and stress responses via sequence-specific control of target RNAs mediated by the action of small, 20–24-nt-long, non-coding regulatory (s)RNAs such as micro (mi) and small interfering (si) RNAs. Biogenesis and sorting of miRNAs into ARGONAUTE (AGO) proteins are intensively investigated, however very few information is available about the presence and distribution of distinct sRNA pools in plant cells. Results: High-throughput sequencing of size-separated sRNA pools of plant crude extracts revealed that the majority of the canonical miRNAs were associated with high molecular weight RNA-induced silencing complexes co-migrating with AGO1 (HMW RISC). In contrast, the majority of 24-nt-long siRNAs were found in association with low molecular weight complexes co-migrating with AGO4 (LMW RISC). Intriguingly, we identified a large set of sRNAs in the cytoplasm, including mature miRNA sequences, in the low molecular size range corresponding to protein-unbound sRNAs. By comparing the RISC-loaded and protein-unbound pools of miRNAs, we identified miRNAs with highly different loading efficiencies. Investigation of some selected miRNAs in a transient expression system validated this finding. We also showed that the availability of RISCs is a limiting factor determining the loading efficiency of miRNAs. Conclusion: Our data reveal the existence of a regulatory checkpoint, likely controlled by information carried by the diverse miRNA precursors, determining the RISC-loading efficiencies of various miRNAs by sorting only a subset of the produced miRNAs into the biologically active RISCs.

Project description:Background: Tomato (Solanum lycopersicum) self-compatibility (SC) is defined as self-pollen tubes that can penetrate their own stigma, elongate in the style and fertilize their own ovules. Self-incompatibility (SI) is defined as self-pollen tubes that are prevented from developing in the style. To determine the influence of gene expression on style self-pollination, a transcriptome-wide comparative analysis of SC and SI tomato unpollinated/pollinated styles was performed using RNA-sequencing (RNA-seq) data. Results: Transcriptome profiles of 24-h unpollination (UP) and self-pollination (P) styles from SC and SI tomato species were generated using high-throughput next generation sequencing. From the comparison of SC self-pollinated and unpollinated styles, 1341 differentially expressed genes (DEGs) were identified, of which 753 were downregulated and 588 were upregulated. From the comparison of SI self-pollinated and unpollinated styles, 804 DEGs were identified, of which 215 were downregulated and 589 were upregulated. Nine gene ontology (GO) terms were enriched significantly in SC and 78 GO terms were enriched significantly in SI. A total of 105 enriched Kyoto Encyclopedia of Genes and Genomes (KEGG) pathways were identified in SC and 80 enriched KEGG pathways were identified in SI, among which “Cysteine and methionine metabolism pathway” and “Plant hormone signal transduction pathway” were significantly enriched in SI. Conclusions: This study is the first global transcriptome-wide comparative analysis of SC and SI tomato unpollinated/pollinated styles. Advanced bioinformatic analysis of DEGs uncovered the pathways of “Cysteine and methionine metabolism” and “Plant hormone signal transduction”, which are likely to play important roles in the control of pollen tubes growth in SI species.

Project description:Dominance hierarchies of rainbow trout Trout form linear dominance hierarchies where there is a dominant, subdominant and subordinate. The dominant is the most aggressive, followed by the subdominant and the subordinate is the least dominant. Fish were scored on their aggressive performance to calculate position within the hierarchy, and once formed the hierarchies are very stable. Hypothesis: Gene expression is different in the brains of individuals with different dominance status. Six hierarchies containing a dominant, subdominant and subordinate were assessed behaviourally then killed and the brain removed. These were run in a reference based design. Hypothesis: On removal of the dominant the subdominant fish will become dominant and its transcript profile will become similar to the established dominant. The second experiment involved removing the dominant from an established hierarchy and then examining gene expression at 2hr, 48hr and 1 week in the new dominant.

Project description:MicroRNAs (miRNAs) are processed from longer precursors with fold-back structures. While animal MIRNA precursors have homogenous structures, plant precursors comprise a collection of fold-backs with variable size and shape. Here, we design an approach (SPARE) to systematically analyze miRNA processing intermediates and characterize the biogenesis of most of the evolutionary conserved miRNAs present in Arabidopsis thaliana. We found that plant MIRNAs are processed by four mechanisms, depending on the sequential direction of the processing machinery and the number of cuts required to release the miRNA. Classification of the precursors according to their processing mechanism revealed specific structural determinants for each group. We found that the complexity of the miRNA processing pathways occurs in both ancient and evolutionary young sequences, and that members of the same family can be processed in different ways. We observed that different structural determinants compete for the processing machinery and that alternative miRNAs can be generated from a single precursor. The results provide a mechanistic explanation for the structural diversity of MIRNA precursors in plants and new insights towards the understanding of the biogenesis of small RNAs. Approach to systematically analyze miRNA processing intermediates and characterize the biogenesis of conserved and young miRNAs present in Arabidopsis thaliana. MiRNA processing intermediates profiles of Wild type and Fiery mutants Arabidopsis plants were analyzed, using Illumina GAIIx.