Project description:Rapeseed (Brassica napus L.) is a globally significant oil-producing crop, and its structural variations (SVs) are fundamental to the enhancement and domestication of important agronomic traits. However, the effects of SVs on agronomic traits in allotetraploid rapeseed are still largely unexplored. Here, we conducted a whole-genome identification of SVs based on 300 re-sequenced rapeseed accessions and found 42,384 high-quality SVs consisted of 34,442 deletions, 6,653 insertions, 828 duplications and 461 inversions. Onset of inflorescence formation and subsequent flower opening at the proper time is crucial for successful propagation. To uncover significant SVs associated with inflorescence development, we performed genome-wide association study based on SVs (SV-GWAS) and identified seven significant SVs. Through analysis of each SV and referencing previous studies, we explored the SV in the second intron of LEAFY on Chromosome C3 (BnaC3.LFY), which is one of homologs of Arabidopsis floral identification gene LFY (AtLFY). BnaC3.LFY Hap1 is significantly related to early inflorescence development due to increased gene expression of BnaC3.LFY. By the CRISPR/Cas9 application in the wild-type spring accession Westar, multiple deletions in intron 2 region of BnaC3.LFY were received and the phenotype of delayed flowering opening was observed. Additionally, we discovered the conserved function of the second intron in Arabidopsis. This study demonstrates the whole-genome layout of SVs in Brassica napus genomes and highlights the conserved role of the second intron of BnaC3.LFY in influencing the timing of inflorescence formation and flower opening, with significant agronomic implications.

Project description:Rapeseed (Brassica napus L.) is a globally significant oil-producing crop, and its structural variations (SVs) are fundamental to the enhancement and domestication of important agronomic traits. However, the effects of SVs on agronomic traits in allotetraploid rapeseed are still largely unexplored. Here, we conducted a whole-genome identification of SVs based on 300 re-sequenced rapeseed accessions and found 42,384 high-quality SVs consisted of 34,442 deletions, 6,653 insertions, 828 duplications and 461 inversions. Onset of inflorescence formation and subsequent flower opening at the proper time is crucial for successful propagation. To uncover significant SVs associated with inflorescence development, we performed genome-wide association study based on SVs (SV-GWAS) and identified seven significant SVs. Through analysis of each SV and referencing previous studies, we explored the SV in the second intron of LEAFY on Chromosome C3 (BnaC3.LFY), which is one of homologs of Arabidopsis floral identification gene LFY (AtLFY). BnaC3.LFY Hap1 is significantly related to early inflorescence development due to increased gene expression of BnaC3.LFY. By the CRISPR/Cas9 application in the wild-type spring accession Westar, multiple deletions in intron 2 region of BnaC3.LFY were received and the phenotype of delayed flowering opening was observed. Additionally, we discovered the conserved function of the second intron in Arabidopsis. This study demonstrates the whole-genome layout of SVs in Brassica napus genomes and highlights the conserved role of the second intron of BnaC3.LFY in influencing the timing of inflorescence formation and flower opening, with significant agronomic implications.

Project description:The effect of the number of pods on the main inflorescence (NPMIs) on seed yield in Brassica napus plants grown at high density is a topic of great economic and scientific interest. We sought to identify patterns of gene expression that are associated with inflorescence and PMI differentiation and development in Brassica napus.

Project description:A critical barrier for improving crops yield is the compensatory effect between seed weight (SW) and seed number (SN), which has been widely reported in several crops including Brassica napus. Despite the agronomic relevance of this issue, the molecular factors involved in the interaction between SW and SN are largely unknown in crops. In this work, we performed a detailed transcriptomic analysis of 48 seed samples obtained from two rapeseed spring genotypes subjected to different source-sink (S-S) ratios in order to modify the relationship between SW and SN under field conditions.

Project description:MicroRNAs and siRNAs are important regulators of plant development and seed formation, yet their population and abundance in the oil crop Brassica napus are still less understood, especially at different developmental stages and among cultivars with varied seed oil contents. Here, we systematically analyzed the small RNA expression profiles of Brassica napus seeds at early embryonic developmental stages in a high oil content and a low oil content Brassica napus cultivars, both cultured in two environments. A total of 50 conserved miRNAs and 11 new miRNAs were identified, together with some new miRNA targets. Expression analysis revealed some miRNAs with varied expression levels in different seed oil content cultivars or at different embryonic developmental stages. A large amount of 23-nt small RNAs with specific nucleotide composition preference were also identified, which may present new classes of functional small RNAs. Examination of small RNA profiles in 2 different seed oil content rapeseed culvitars at 2 locations.

Project description:Compared to ordinary rapeseed, high-oleic acid rapeseed has higher levels of monounsaturated fatty acids and lower levels of saturated fatty acid and polyunsaturated fatty acids, and thus is of high nutritional and health value. In addition, high-oleic acid rapeseed oil imparts cardiovascular protective effects. Based on these properties, high-oleic acid oil crops have been extensively investigated and cultivated. In this study, we employed a microarray analysis with high oleic acid line and low oleic acid line from the developing seeds (27 days after flowering) of Brassica napus.

Project description:Global climate changes on one aspect of extreme temperature records would suddenly reset environmental growth conditions for field-grown crops, which severely affects agronomic and commercial traits. Taking the cold-season preferable crop rapeseed Brassica napus L. for example, low-temperature shocks change endogenous regulatory networks and cause phenotypic damages during most lifespan. Here we screened out two genetic breeding elites with different temperature-dependent germination rates, core germplasms with good germination performance and genetic loci and candidate genes potentially involved in low-temperature tolerant functions for the pre-breeding purpose of cold-tolerant germination. By using the phenotype of the germination index of 273 core germplasms under normal temperature and 10 transcriptomic datasets of cold-tolerant Jia You (JY) 1621 and cold-sensitive JY1605 elite cultivars on three timepoints during germination process, we successfully identified clustered genes of early and late temperature response germination (ETRG and LTRG) genes and several cold-tolerant (CDT) and temperature-insensitive (TPI) candidate regulators. This study performed comprehensive multi-omics research on potential cold-responsive genes for the rapeseed improvement of cold tolerance germination.

Project description:C3-C4 intermediate Moricandia suffruticosa showed tolerance to drought and heat stresses, and high photosynthetic capacity under these abiotic stresses as comparing with C3 relative crop rapeseed (Brassica napus). In our study, systematic analysis was conducted to reveal photosynthetic difference between C3-C4 Moricandia suffruticosa and its relative C3 rapeseed from the same Brassiceae tribe. It was found that Moricandia leaf photosynthesis and anatomy were significantly changed compared to rapeseed under drought and heat stress conditions. De novo transcriptome of Moricandia was assembled by next generation sequencing, and unigenes were mapped to respective rapeseed gene locus. Then comparative transcriptome analysis was conducted in leaf tissues of Moricandia and rapeseed under both drought and heat stresses. Main pathways and candidate genes were revealed from this analysis, which may be associated with the stress induced change in Moricandia.

Project description:Exploring the molecular mechanism underlying plant architecture and breeding new varieties suitable for mechanized harvesting are primary objectives for rapeseed breeders in China. However, few genes controlling plant architecture have been cloned in Brassica napus. In this study, SX3, a scattered-bud B. napus line with a dwarf and compact plant architecture, was characterized. To identify the genes underlying bud arrangement, plant height and branch angle, segregating populations were constructed by crossing SX3 with two clustered-bud lines with a tall and loose plant architecture. Genetic analysis revealed that the scattered-bud trait (SBT) was controlled by a single dominant gene, BnaSBT. BnaSBT is likely a pleiotropic gene that simultaneously controls plant height and branch angle. Using BSA-seq analysis, BnaSBT was mapped to a 4.15 Mb region on ChrA10. Owing to the lack of recombinants within this region, it was infeasible to finely map BnaSBT. RNA-seq analysis of BC2 plants with contrasting inflorescence and plant architectures revealed that the upregulation of genes involved in amino acid and lipid metabolism and genes encoding MADS-box transcription factors is related to the the phenotype of SX3. These findings together with comparative sequencing indicated that BnaA10.SEP1, BnaA10.AGL15, BnaA10.GLN1-4 and BnaA10.AGP15 are candidate genes for BnaSBT. Markers closely linked to the scattered-bud trait were developed for selecting dwarf and compact plants. These findings provide molecular markers and germplasms for breeding new varieties with ideal plant types and lay a theoretical foundation for cloning key genes and elucidating the genetic basis of inflorescence and plant architectures in B. napus.

Project description:Background: MicroRNAs (miRNAs), a class of non-coding small RNAs, are crucial to the regulation of various developmental processes. Plant architecture is a collection of genetically controlled agronomic traits that determine crop production and mechanized harvesting. Although several genes had been found to regulate plant architecture, the mechanisms whereby miRNAs regulate plant architecture in the rapeseed Brassica napus remain unknown. Results: In this study, we characterized a rod-like rapeseed mutant with an ideal plant architecture that substantially enhanced its breeding potential. To explore miRNAs that contribute to the rapeseed plant architecture, backcross progenies that developed into small plants (rod-like) and tall plants (normal) were used for study. Four small RNA (sRNA) libraries and two degradome libraries from the shoot apex of normal and rod-like plants were sequenced. A total of 925 non-redundant B. napus miRNA precursors were identified, representing 315 precursors for 74 known miRNAs and 610 precursors for 327 novel miRNAs. Expression analysis revealed that 10 known miRNAs and 7 novel miRNAs were differentially expressed between the normal and rod-like plants. In addition, 408 targets were identified through degradome sequencing and 14 targets were further validated via RNA ligase-mediated 5′ rapid amplification of cDNA ends. Furthermore, the functions of miR319 and its target gene TCP4 were studied and provided a novel insight into how miR319 regulates plant architecture. Conclusions: Correlation analysis between differentially expressed miRNAs and their targets demonstrated that nutrition and metal deprivation, energy supply deficiency, senescence and TEOSINTE BRANCHED1/CYCLOIDEA/PCF (TCPs) contributed to the premature termination of shoot development in rod-like mutant. The work further elucidates the mechanism of miRNAs participate in the regulation of plant architecture.