Project description:Cereal genomes have undergone repeated polyploidization and transposable element (TE) proliferation, collectively generating complex regulatory landscapes. The evolutionary trajectories and functional implications of these landscapes, however, remain largely unexplored. By employing chromatin-bound RNA sequencing across seven cereal species, we systematically mapped 45,952 regulatory element transcripts (RETs), including 32,867 distal RETs corresponding to enhancer RNAs (eRNAs). Our analysis reveals that 56% of lineage-specific eRNAs originate from TE expansions, suggesting TEs as significant reservoirs of species-specific regulatory innovation in cereals. Notably, we uncovered a remarkable similarity in defense-related function, root-specific expression, and TE-derived origin of eRNAs across ancient and recent evolutionary layers of Triticeae, suggesting recurrent recruitment of TE-derived root-associated regulatory elements during Triticeae evolution. Furthermore, we found that young eRNA pairs in hexaploid wheat with high sequence similarity, many originating from RLG_famc8.3 and DTC_famc4.3, exhibit pronounced root specificity and coordinated expression, suggesting a targeted amplification and refinement of the successful ancestral regulatory strategy established after Triticeae divergence. To facilitate community access, we developed Cereal-eRNAdb (http://bioinfo.cemps.ac.cn/Cereal-eRNAdb/), a comprehensive database integrating 69,426 eRNAs with functional annotations across 296 samples. Our work indicates that TE-mediated innovation of root-specific eRNAs as a candidate mechanism that may contribute to Triticeae adaptation and provides a foundational resource for exploiting regulatory variation in cereal crop breeding.

Project description:Cereal genomes have undergone repeated polyploidization and transposable element (TE) proliferation, collectively generating complex regulatory landscapes. The evolutionary trajectories and functional implications of these landscapes, however, remain largely unexplored. By employing chromatin-bound RNA sequencing across seven cereal species, we systematically mapped 45,952 regulatory element transcripts (RETs), including 32,867 distal RETs corresponding to enhancer RNAs (eRNAs). Our analysis reveals that 56% of lineage-specific eRNAs originate from TE expansions, suggesting TEs as significant reservoirs of species-specific regulatory innovation in cereals. Notably, we uncovered a remarkable similarity in defense-related function, root-specific expression, and TE-derived origin of eRNAs across ancient and recent evolutionary layers of Triticeae, suggesting recurrent recruitment of TE-derived root-associated regulatory elements during Triticeae evolution. Furthermore, we found that young eRNA pairs in hexaploid wheat with high sequence similarity, many originating from RLG_famc8.3 and DTC_famc4.3, exhibit pronounced root specificity and coordinated expression, suggesting a targeted amplification and refinement of the successful ancestral regulatory strategy established after Triticeae divergence. To facilitate community access, we developed Cereal-eRNAdb (http://bioinfo.cemps.ac.cn/Cereal-eRNAdb/), a comprehensive database integrating 69,426 eRNAs with functional annotations across 296 samples. Our work indicates that TE-mediated innovation of root-specific eRNAs as a candidate mechanism that may contribute to Triticeae adaptation and provides a foundational resource for exploiting regulatory variation in cereal crop breeding.

Project description:Cereal genomes have undergone repeated polyploidization and transposable element (TE) proliferation, collectively generating complex regulatory landscapes. The evolutionary trajectories and functional implications of these landscapes, however, remain largely unexplored. By employing chromatin-bound RNA sequencing across seven cereal species, we systematically mapped 45,952 regulatory element transcripts (RETs), including 32,867 distal RETs corresponding to enhancer RNAs (eRNAs). Our analysis reveals that 56% of lineage-specific eRNAs originate from TE expansions, suggesting TEs as significant reservoirs of species-specific regulatory innovation in cereals. Notably, we uncovered a remarkable similarity in defense-related function, root-specific expression, and TE-derived origin of eRNAs across ancient and recent evolutionary layers of Triticeae, suggesting recurrent recruitment of TE-derived root-associated regulatory elements during Triticeae evolution. Furthermore, we found that young eRNA pairs in hexaploid wheat with high sequence similarity, many originating from RLG_famc8.3 and DTC_famc4.3, exhibit pronounced root specificity and coordinated expression, suggesting a targeted amplification and refinement of the successful ancestral regulatory strategy established after Triticeae divergence. To facilitate community access, we developed Cereal-eRNAdb (http://bioinfo.cemps.ac.cn/Cereal-eRNAdb/), a comprehensive database integrating 69,426 eRNAs with functional annotations across 296 samples. Our work indicates that TE-mediated innovation of root-specific eRNAs as a candidate mechanism that may contribute to Triticeae adaptation and provides a foundational resource for exploiting regulatory variation in cereal crop breeding.

Project description:The yield of wheat is highly impacted by environmental stresses. The combinatorial regulation of sequence-specific transcription factors(TFs) defines a regulatory network that underlies plant stress responses. Here we created a comprehensive catalog of genomic binding sites of 115 TFs underlying abiotic stress responses by leveraging DAP-seq in Triticum Urartu, along with epigenomic profiles. The majority of gene distant TF binding sites(TFBS) are embedded in transposable elements(TEs), whose functional relevance was supported by a signature of purifying selection and active epigenomic features. Furthermore, ~30% non-TE TFBS share high sequence similarity with TE-embeded TFBS, potentially derived from Triticeae-specific TEs and have almost no sequence homology in non-Triticeae species. The expansion of TE-derived TFBS in wheat linked to wheat-specific stress responsive genes, suggesting that TEs are an important driving force for regulatory innovation. Altogether, TEs have significantly and continuously shaped regulatory network in wheat adaptation.

Project description:The yield of wheat is highly impacted by environmental stresses. The combinatorial regulation of sequence-specific transcription factors(TFs) defines a regulatory network that underlies plant stress responses. Here we created a comprehensive catalog of genomic binding sites of 115 TFs underlying abiotic stress responses by leveraging DAP-seq in Triticum Urartu, along with epigenomic profiles. The majority of gene distant TF binding sites(TFBS) are embedded in transposable elements(TEs), whose functional relevance was supported by a signature of purifying selection and active epigenomic features. Furthermore, ~30% non-TE TFBS share high sequence similarity with TE-embeded TFBS, potentially derived from Triticeae-specific TEs and have almost no sequence homology in non-Triticeae species. The expansion of TE-derived TFBS in wheat linked to wheat-specific stress responsive genes, suggesting that TEs are an important driving force for regulatory innovation. Altogether, TEs have significantly and continuously shaped regulatory network in wheat adaptation.

Project description:The yield of wheat is highly impacted by environmental stresses. The combinatorial regulation of sequence-specific transcription factors(TFs) defines a regulatory network that underlies plant stress responses. Here we created a comprehensive catalog of genomic binding sites of 115 TFs underlying abiotic stress responses by leveraging DAP-seq in Triticum Urartu, along with epigenomic profiles. The majority of gene distant TF binding sites(TFBS) are embedded in transposable elements(TEs), whose functional relevance was supported by a signature of purifying selection and active epigenomic features. Furthermore, ~30% non-TE TFBS share high sequence similarity with TE-embeded TFBS, potentially derived from Triticeae-specific TEs and have almost no sequence homology in non-Triticeae species. The expansion of TE-derived TFBS in wheat linked to wheat-specific stress responsive genes, suggesting that TEs are an important driving force for regulatory innovation. Altogether, TEs have significantly and continuously shaped regulatory network in wheat adaptation.

Project description:Despite their importance, there remains to be few large scale expression-based studies of tissue-specific expression information in the species belonging to the Triticeae. We used the 55K Affymetrix GeneChip® Wheat Genome Array to generate a gene expression atlas of triticale tissues. The global transcriptional profiles of seed tissues (embryo, endosperm, crease, pericarp and epiderm) and vegetative tissues (root, coleoptile, stem and leaf) were analyzed and co-regulated as well as preferentially expressed genes were identified. Data analysis revealed both novel and conserved regulatory factors underlying Triticeae tissue development and function.

Project description:Common wheat (T. aestivum) converged three subgenomes adapted to different environments. The combinatorial interaction between transcription factors (TFs) and regulatory elements (REs) defines a regulatory circuit that underlies subgenome convergence and divergence. Compared to the relatively conserved gene composition across subgenomes, the intergenic regions with abundant REs is drastically diversified by almost complete TE turnovers, raising major questions regarding how subgenome convergent and divergent regulation is encoded in the highly diversified intergenic regions, and the impact of TE evolution on regulatory conservation and innovation. In the present study, we created genome-wide TF binding catalog to assemble an extensive wheat regulatory network comprising connections among 182 TFs. The different effects of ancient and recent TE insertions on regulatory specificity were observed. Subgenome asymmetric TE expansion is an important source of subgenome divergent TFBS, which help explain the vast occupancy difference across subgenomes. Interestingly, the ancient expansion of RLC_famc1.4-derived TFBS occurred in more than 25% triads promoters. A significant fraction of these TE-derived TFBS subjected to region-specific evolutionary selections, resulting in subgenome-balanced TF binding but unbalanced degeneration of flanking TE sequences. These TE-derived subgenome convergent and divergent regulation linked to subgenome conserved and diversified pathways, suggesting that TEs are an important regulatory driving force contributed to polyploid evolution. Overall, this study demonstrated the impact of TEs on shaping the plasticity and adaptation of common wheat, enriched the theories of TE-promoted transcriptional innovation from the evolutionary aspects of polyploid regulation since first reported by McClintock.

Project description:Despite their importance, there remains to be few large scale expression-based studies of tissue-specific expression information in the species belonging to the Triticeae. We used the 55K Affymetrix GeneChip® Wheat Genome Array to generate a gene expression atlas of triticale tissues. The global transcriptional profiles of seed tissues (embryo, endosperm, crease, pericarp and epiderm) and vegetative tissues (root, coleoptile, stem and leaf) were analyzed and co-regulated as well as preferentially expressed genes were identified. Data analysis revealed both novel and conserved regulatory factors underlying Triticeae tissue development and function. Triticale seed (embryo, endosperm, crease, pericarp and epiderm) and vegetative tissues (root, coleoptile, leaf and stem) were collected and analyzed using the 55K Affymetrix Wheat Genome array. All seed tissues were collected at the soft dough stage of seed development. Vegetative tissues were collected at multiple stages of development. Root and coleoptile tissues were collected at early development (Zadoks' stage 7), and leaf tissue was collected at five successive stages ranging from seedling to late senescence and stem tissue was collected at four successive stages stages ranging from initial tillering to early senescence. Between two to five biological replicates for each tissue were analyzed.

Project description:Kiwifruit bacterial canker, caused by Pseudomonas syringae pv. actinidiae (Psa), is an emerging global concern in kiwifruit production. Successful Psa infection in kiwifruit relies on the type III secretion system (T3SS), which is governed by the HrpR/S-HrpL regulatory pathway. However, the mechanisms by which certain transcriptional factors regulate this pathway remain poorly understood. In this study, we identified the TetR/AcrR family transcription factors C_22735 (tetR1) and C_04700 (hybrid histidine kinase; retS) in the P. syringae pv. actinidiae (biovar 3) strain S26 using transposon libraries and a DNA pull-down strategy. Both the mutant strains tetR1 and retS exhibited significantly reduced pathogenicity in kiwifruit leaf discs and a diminished ability to induce hrpRS, hrpL, and hrpA expression in vitro and showed a reduced hypersensitive response in Nicotiana benthamiana. Moreover, transcriptomic studies showed a considerable overlap in down-regulated genes between the tetR1 and two-component system (TCS) retS mutant, highlighting the intertwined regulatory roles of both genes. This overlap suggests a tightly coordinated regulatory system, where tetR1 serves as the response regulator of the hybrid histidine kinase retS to regulate T3SS and virulence. The electrophoretic mobility shift assays, and luciferase-based promoter activity detection further revealed that TetR1 positively regulates the T3SS by directly binding to the promoter regions of hrpR/S and hrpL. This study identifies the tetR1 gene as the first TetR-family transcription factor directly linking the hybrid TCS retS to HrpR/S-HrpL -mediated T3SS regulatory pathway activation in Psa for regulation.