Section: New Results
NGS applications
Participants : Susete Alves Carvalho, Rumen Andonov, Anaïs Gouin, Fabrice Legeai, Dominique Lavenier, Claire Lemaitre, Pierre Peterlongo, Ivaylo Petrov, Guillaume Rizk.
Identification of genomic regions of biological interest
The extraction and selection of 400 microsatellites among the large and fragmented Acyrthosiphon pisum genome led to the identification of a single 9cM region controlling the loss of sex in the pea aphid. The genotyping of these markers on geographically distant populations under divergent selection for reproductive strategies revealed a strong signature of selection in this genomic region, suggesting gene flow between populations with distinct reproductive modes. [15]
Transcriptome assembly
For this study, we incorporated various sources of RNA sequences from 454, Illumina and Sanger sequencing technologies obtained from more than 35 S. frugiperda developmental time-points and tissue samples and developed a custom pipeline to achieve their assembly. As a result, we provided a first valid transcriptome for Spodoptera frugiperda, a major agricultural pest. [16]
Catalogue of long non coding RNAs
We established a new bioinformatics pipeline for the detection of lncRNAs from RNA-Seq data, produced the first catalogue of aphids lncRNAs, and asserted for each lncRNA a classification of putative cis-interactions based on its genomic distance to neighboring mRNAs. These results allow the constitution of a broad gene regulation network of the aphid phenotypic plasticity at the embryo level. This workflow is available in Galaxy on the BioInformatics Platform for Arthopods of Agroecosystems (www.inra.fr/bipaa) and can be applied to any organism for which an annotated genome sequence and RNA-Seq data are provided.[23]
Identification and correction of genome mis-assemblies due to heterozygosity
Assembly tools are more and more efficient to reconstruct a genome from next-generation sequencing data but some problems remain. One of them corresponds to mis-assemblies due to heterozygosity (2 alleles instead of a consensus). Thus, we propose a strategy to detect and correct false duplications in assemblies based on several metrics: sequence similarity, matche length and average read coverage. Our method allows to decrease redundancy in the genome assembly, to improve the scaffolding and then to increase the N50 statistic by removal of one of the two alleles or joining of scaffolds by their extremities. This method was applied on the Spodoptera frugiperda genome.[39]
Questioning the classical re-sequencing analyses approach
Classical re-sequencing analyses are based on a first step of read mapping, then only mapped reads are taken into account in following analyses such as variant calling. We investigated the sources of unmapped reads in aphid re-sequencing data of 33 individuals, and we demonstrated that these reads contain valuable information that should not be discarded as usually done in such analyses. For instance, the analysis of the contigs obtained from assembling the unmapped reads led to recover some divergent genomic regions previously excluded from analysis and to discover putative novel sequences of A. pisum and its symbionts. We proposed strategies, based on assembly and re-mapping, to aid the capture and interpretation of this information.[14]
Application of discoSnp on pea data
The pea is a non-model organism with a large (4.5 GB) and complex genome which has not been sequenced yet. We compared, on the same set of low depth pea sequences, the SNPs generated by discoSnp with those obtained with a previous SNP discovery pipeline, and those generated using classical mapping approach combining Bowtie2 and GATK tools. [31]