Project description:Illumina mRNA-Seq is comparable to microarray analysis for transcript quantification but has increased sensitivity and, importantly, the potential to distinguish between homoeologous genes in polyploids. Using a novel curing process, we adapted a reference sequence that was a consensus derived from ESTs from both Brassica A and C genomes to one containing A and C genome versions for each of the 94,558 original unigenes. We aligned reads from Brassica napus to this cured reference, finding 38% more reads mapping in resynthesised lines and 28% in natural lines. Where the A and C versions differed at single nucleotide positions, termed inter-homoeologue polymorphisms (IHPs), we were able to apportion expression in the polyploid to the A or C genome homoeologues. 43,761 unigenes contained at least one IHP, with a mean frequency of 10.5 per kb unigene sequence. 6,350 of the unigenes with IHPs were differentially expressed between homoeologous gene pairs in resynthesised B. napus. 3,212 unigenes showed a similar pattern of differential expression across a range of natural B. napus crop varieties and, of these, 995 were in common with resynthesised B. napus. Functional classification showed over-representation in gene ontology categories not associated with dosage-sensitivity.

Project description:Allopolyploidization-induced "genome shock" poses severe challenges to subgenome stability. However, the mechanisms by which subgenomes achieve functional homeostasis through genomic and epigenomic regulation remain poorly understood. This study integrates multi-omics data from Brassica napus and its putative diploid progenitors to reveal that coordinated convergence of genomic and epigenomic plays a central role in maintaining subgenome functional homeostasis within allopolyploids. Here, we present the first comprehensive, high-quality epigenomic maps to date for the diploid Brassica rapa and Brassica oleracea. Comparative genomic analyses revealed that epigenomic reprogramming in A and C subgenomes of the allotetraploid drives convergent chromatin states, which substantially diminished expression divergence between homoeologous gene pairs. Notably, compared to the A subgenome, the C subgenome in the allotetraploid exhibits more pronounced sequence conservation of regulatory elements and epigenetic homeostasis. Furthermore, transcription factor binding sites (TFBSs) influenced by genomic variation in the A subgenome demonstrate convergent evolutionary patterns toward the C subgenome. This study provides novel insights into the coordinated convergence of genomic and epigenomic regulation between subgenomes in allotetraploid Brassica napus, demonstrating that allopolyploids resolve subgenomic conflicts through multi-layered regulatory networks. These findings establish a novel paradigm for elucidating the molecular basis of polyploidy advantages in crops and for enabling rational design of synthetic polyploids.

Project description:Allopolyploidization-induced "genome shock" poses severe challenges to subgenome stability. However, the mechanisms by which subgenomes achieve functional homeostasis through genomic and epigenomic regulation remain poorly understood. This study integrates multi-omics data from Brassica napus and its putative diploid progenitors to reveal that coordinated convergence of genomic and epigenomic plays a central role in maintaining subgenome functional homeostasis within allopolyploids. Here, we present the first comprehensive, high-quality epigenomic maps to date for the diploid Brassica rapa and Brassica oleracea. Comparative genomic analyses revealed that epigenomic reprogramming in A and C subgenomes of the allotetraploid drives convergent chromatin states, which substantially diminished expression divergence between homoeologous gene pairs. Notably, compared to the A subgenome, the C subgenome in the allotetraploid exhibits more pronounced sequence conservation of regulatory elements and epigenetic homeostasis. Furthermore, transcription factor binding sites (TFBSs) influenced by genomic variation in the A subgenome demonstrate convergent evolutionary patterns toward the C subgenome. This study provides novel insights into the coordinated convergence of genomic and epigenomic regulation between subgenomes in allotetraploid Brassica napus, demonstrating that allopolyploids resolve subgenomic conflicts through multi-layered regulatory networks. These findings establish a novel paradigm for elucidating the molecular basis of polyploidy advantages in crops and for enabling rational design of synthetic polyploids.

Project description:Allopolyploidization-induced "genome shock" poses severe challenges to subgenome stability. However, the mechanisms by which subgenomes achieve functional homeostasis through genomic and epigenomic regulation remain poorly understood. This study integrates multi-omics data from Brassica napus and its putative diploid progenitors to reveal that coordinated convergence of genomic and epigenomic plays a central role in maintaining subgenome functional homeostasis within allopolyploids. Here, we present the first comprehensive, high-quality epigenomic maps to date for the diploid Brassica rapa and Brassica oleracea. Comparative genomic analyses revealed that epigenomic reprogramming in A and C subgenomes of the allotetraploid drives convergent chromatin states, which substantially diminished expression divergence between homoeologous gene pairs. Notably, compared to the A subgenome, the C subgenome in the allotetraploid exhibits more pronounced sequence conservation of regulatory elements and epigenetic homeostasis. Furthermore, transcription factor binding sites (TFBSs) influenced by genomic variation in the A subgenome demonstrate convergent evolutionary patterns toward the C subgenome. This study provides novel insights into the coordinated convergence of genomic and epigenomic regulation between subgenomes in allotetraploid Brassica napus, demonstrating that allopolyploids resolve subgenomic conflicts through multi-layered regulatory networks. These findings establish a novel paradigm for elucidating the molecular basis of polyploidy advantages in crops and for enabling rational design of synthetic polyploids.

Project description:Allopolyploidization-induced "genome shock" poses severe challenges to subgenome stability. However, the mechanisms by which subgenomes achieve functional homeostasis through genomic and epigenomic regulation remain poorly understood. This study integrates multi-omics data from Brassica napus and its putative diploid progenitors to reveal that coordinated convergence of genomic and epigenomic plays a central role in maintaining subgenome functional homeostasis within allopolyploids. Here, we present the first comprehensive, high-quality epigenomic maps to date for the diploid Brassica rapa and Brassica oleracea. Comparative genomic analyses revealed that epigenomic reprogramming in A and C subgenomes of the allotetraploid drives convergent chromatin states, which substantially diminished expression divergence between homoeologous gene pairs. Notably, compared to the A subgenome, the C subgenome in the allotetraploid exhibits more pronounced sequence conservation of regulatory elements and epigenetic homeostasis. Furthermore, transcription factor binding sites (TFBSs) influenced by genomic variation in the A subgenome demonstrate convergent evolutionary patterns toward the C subgenome. This study provides novel insights into the coordinated convergence of genomic and epigenomic regulation between subgenomes in allotetraploid Brassica napus, demonstrating that allopolyploids resolve subgenomic conflicts through multi-layered regulatory networks. These findings establish a novel paradigm for elucidating the molecular basis of polyploidy advantages in crops and for enabling rational design of synthetic polyploids.

Project description:Transcription profiling of Brassica rapa, Brassica oleracea and Brassica napus I and II The nuclear genomes of the resynthesised B. napus lines should be identical but, as one (B. napus I) involved a cross of B. oleracea onto B. rapa, and the other (B. napus II) involved a cross of B rapa onto B. oleracea, they differ in cytoplasm, and hence contain different chloroplast and mitochondrial genomes.

Project description:ngs2017_08_brasilice-transilice - What are the genes with modulated expression in response to brassica napus treatment (1.7mM, One week, root supply)-Brassica napus were grown on hydropnic conditions using Hoagland nutrient solution containing or not 1.7 mM of Si

Project description:Transcription profiling of Brassica rapa, Brassica oleracea and Brassica napus I and II The nuclear genomes of the resynthesised B. napus lines should be identical but, as one (B. napus I) involved a cross of B. oleracea onto B. rapa, and the other (B. napus II) involved a cross of B rapa onto B. oleracea, they differ in cytoplasm, and hence contain different chloroplast and mitochondrial genomes. Four-condition experiment, comparison of transcription profiles of the genomes. Four biological replicates were used, independently grown and harvested. One replicate per array.

Project description:Time course of gene expression profiles during seed development and maturation in Brassica napus were studied using Combimatrix Brassica microarray. The time course expression of 90K Brassica napus EST contigs were measured at 8 developing seed stages of 10, 15, 20, 25, 30, 35, 40 and 45 DAF (days after flowering) using single color microarray

Project description:This study aimed to evaluate the effects of UV-B wavelength regions (< 300 nm) in canola plants (Brassica napus L.). Agilent One-Color Gene Expression Microarray analysis was conducted using an Agilent-022520 Brassica napus 4x44K Array.