Long-read assembly of the <i>Brassica napus</i> reference genome Darmor-bzh

Rousseau‐Gueutin, Mathieu; Belser, Caroline; Silva, Corinne Da; Richard, Gautier; Istace, Benjamin; Cruaud, Corinne; Falentin, Cyril; Boideau, Franz; Boutte, Julien; Delourme, Régine; Deniot, Gwenaëlle; Engelen, Stéfan; Carvalho, Julie Ferreira de; Lemainque, Arnaud; Maillet, Loeiz; Morice, Jérôme; Wincker, Patrick; Chèvre, Anne‐Marie; Aury, Jean‐Marc

doi:10.1093/gigascience/giaa137

Cited by 82 publications

(112 citation statements)

References 53 publications

(52 reference statements)

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“…The Darmor-bzh 4.1 reference assembly was constructed prior to the advance of long-read sequencing technologies mainly based on Illumina short-read sequencing and is thus highly fragmented (Lee et al, 2020). We have to note that between the submission and publication of this article, an upgraded, Oxford Nanoporebased version of Darmor-bzh genome (v10) was published, in which the region in question is assembled in agreement with the results of our study and other long-read assemblies (Rousseau-Gueutin et al, 2020). Moreover, it has been shown that in B. napus more than 50% of known RGA copies do not occur in a single reference genotype assembly but require analysis of pangenome assemblies for detection (Dolatabadian et al, 2020).…”

Section: Discussionsupporting

confidence: 80%

Local Duplication of TIR-NBS-LRR Gene Marks Clubroot Resistance in Brassica napus cv. Tosca

et al. 2021

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Clubroot, caused by Plasmodiophora brassicae infection, is a disease of growing importance in cruciferous crops, including oilseed rape (Brassica napus). The affected plants exhibit prominent galling of the roots that impairs their capacity for water and nutrient uptake, which leads to growth retardation, wilting, premature ripening, or death. Due to the scarcity of effective means of protection against the pathogen, breeding of resistant varieties remains a crucial component of disease control measures. The key aspect of the breeding process is the identification of genetic factors associated with variable response to the pathogen exposure. Although numerous clubroot resistance loci have been described in Brassica crops, continuous updates on the sources of resistance are necessary. Many of the resistance genes are pathotype-specific, moreover, resistance breakdowns have been reported. In this study, we characterize the clubroot resistance locus in the winter oilseed rape cultivar “Tosca.” In a series of greenhouse experiments, we evaluate the disease severity of P. brassicae-challenged “Tosca”-derived population of doubled haploids, which we genotype with Brassica 60 K array and a selection of SSR/SCAR markers. We then construct a genetic map and narrow down the resistance locus to the 0.4 cM fragment on the A03 chromosome, corresponding to the region previously described as Crr3. Using Oxford Nanopore long-read genome resequencing and RNA-seq we review the composition of the locus and describe a duplication of TIR-NBS-LRR gene. Further, we explore the transcriptomic differences of the local genes between the clubroot resistant and susceptible, inoculated and control DH lines. We conclude that the duplicated TNL gene is a promising candidate for the resistance factor. This study provides valuable resources for clubroot resistance breeding programs and lays a foundation for further functional studies on clubroot resistance.

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Section: Discussionsupporting

confidence: 80%

Local Duplication of TIR-NBS-LRR Gene Marks Clubroot Resistance in Brassica napus cv. Tosca

et al. 2021

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“…The context sequences of each SNP marker were physically localized on the reference genome B. rapa Chiifu v1.5 [45] and B. napus cv. Darmor-bzh v10 [46] using BLASTn (ver. 2.9.0, min.…”

Section: Dna Extraction and Snp Genotypingmentioning

confidence: 99%

“…Darmor A01 chromosome was selected for its pericentromeric localization. The context sequences of the SNP markers (derived from Brassica 60 K Illumina infinium array) flanking this QTL were retrieved and physically localized on the B. napus reference genome Darmor-bzh v10 [46] using BLASTn [47].…”

Section: Localization Of a Qtl Of Interestmentioning

confidence: 99%

“…The centromeric regions were defined by blasting several centromeric-specific repeats (CentBr1, CentBr2, TR238, TR805, PCRBr and CRB; [50,51]) against B. napus cv. Darmorbzh v10 [46] and by examining the plot density of the BLASTn results (e-value less than 1 × 10 −20 ). The pericentromeric borders for each chromosome were inferred by using the mean gene density along the chromosomes (as presented in [52]) and defined as the regions surrounding the centromere with a gene density below the chromosome average.…”

Section: Inferring the Position Of Centromeric And Pericentromeric Regionsmentioning

confidence: 99%

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A Modified Meiotic Recombination in Brassica napus Largely Improves Its Breeding Efficiency

Boideau

Pelé

Tanguy

et al. 2021

Biology

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Meiotic recombination is the main tool used by breeders to generate biodiversity, allowing genetic reshuffling at each generation. It enables the accumulation of favorable alleles while purging deleterious mutations. However, this mechanism is highly regulated with the formation of one to rarely more than three crossovers, which are not randomly distributed. In this study, we showed that it is possible to modify these controls in oilseed rape (Brassica napus, AACC, 2n = 4x = 38) and that it is linked to AAC allotriploidy and not to polyploidy per se. To that purpose, we compared the frequency and the distribution of crossovers along A chromosomes from hybrids carrying exactly the same A nucleotide sequence, but presenting three different ploidy levels: AA, AAC and AACC. Genetic maps established with 202 SNPs anchored on reference genomes revealed that the crossover rate is 3.6-fold higher in the AAC allotriploid hybrids compared to AA and AACC hybrids. Using a higher SNP density, we demonstrated that smaller and numerous introgressions of B. rapa were present in AAC hybrids compared to AACC allotetraploid hybrids, with 7.6 Mb vs. 16.9 Mb on average and 21 B. rapa regions per plant vs. nine regions, respectively. Therefore, this boost of recombination is highly efficient to reduce the size of QTL carried in cold regions of the oilseed rape genome, as exemplified here for a QTL conferring blackleg resistance.

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“…Gene prediction was performed using several proteomes: 8 from other genotypes of B. napus [51] (Westar, Zs11, QuintaA, Zheyou73, N02127, GanganF73, Tapidor3, and Shen-gli3), Arabidopsis thaliana (UP000006548) and the 2021 annotation of Darmor-bzh [30]. Regions of low complexity in genomic sequences were masked with the DustMasker algorithms [52] (version 1.0.0 from the blast 2.10.0 package).…”

Section: Gene Predictionmentioning

confidence: 99%

Sequencing and Chromosome-Scale Assembly of Plant Genomes, <em>Brassica rapa</em> as a Use Case

Istace¹,

Belser²,

Falentin³

et al. 2021

Preprint

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With the rise of long-read sequencers and long-range technologies, delivering high-quality plant genome assemblies is no longer reserved to large consortia. Indeed, sequencing techniques but also computer algorithms have reached a point where the reconstruction of assemblies at the chromosome-scale is now feasible at the laboratory scale. Current technologies, and especially long-range technologies, are numerous and selecting the most promising one for the genome of interest is crucial to obtain optimal results. In this study, we resequenced the genome of the yellow sarson, Brassica rapa cv. Z1, using the Oxford Nanopore PromethION sequencer and assembled the sequenced data using current assemblers. To reconstruct complete chromosomes, we used and compared three long-range techniques, optical mapping, Omni-C and Pore-C sequencing libraries commercialized by Bionano Genomics, Dovetail Genomics and Oxford Nanopore Technologies respectively, or a combination of the three, in order to evaluate the capability of each technology.

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Long-read assembly of the Brassica napus reference genome Darmor-bzh

Cited by 82 publications

References 53 publications

Local Duplication of TIR-NBS-LRR Gene Marks Clubroot Resistance in Brassica napus cv. Tosca

Local Duplication of TIR-NBS-LRR Gene Marks Clubroot Resistance in Brassica napus cv. Tosca

A Modified Meiotic Recombination in Brassica napus Largely Improves Its Breeding Efficiency

Sequencing and Chromosome-Scale Assembly of Plant Genomes, <em>Brassica rapa</em> as a Use Case

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