<p>Transcriptome sequencing for high throughput SNP development and genetic mapping in Pea</p>

Publication Overview
TitleTranscriptome sequencing for high throughput SNP development and genetic mapping in Pea
AuthorsDuarte J, Riviere N, Barabger A, Aubert G, Burstin J, Cornet L, Lavaud C, Lejeune-Henaut I, Martinant JP, Pichon JP, Pilet-Nayel ML, Boutet G
TypeJournal Article
Journal NameBMC Genomics
Volume15
Year2014
Page(s)126
CitationDuarte J, Riviere N, Barabger A, Aubert G, Burstin J, Cornet L, Lavaud C, Lejeune-Henaut I, Martinant JP, Pichon JP, Pilet-Nayel ML, Boutet G. Transcriptome sequencing for high throughput SNP development and genetic mapping in Pea. BMC Genomics. 2014; 15:126.

Abstract

Background: Pea has a complex genome of 4.3 Gb for which only limited genomic resources are available to date. Although SNP markers are now highly valuable for research and modern breeding, only a few are described and used in pea for genetic diversity and linkage analysis. Results: We developed a large resource by cDNA sequencing of 8 genotypes representative of modern breeding material using the Roche 454 technology, combining both long reads (400 bp) and high coverage (3.8 million reads, reaching a total of 1,369 megabases). Sequencing data were assembled and generated a 68 K unigene set, from which 41 K were annotated from their best blast hit against the model species Medicago truncatula. Annotated contigs showed an even distribution along M. truncatula pseudochromosomes, suggesting a good representation of the pea genome. 10 K pea contigs were found to be polymorphic among the genetic material surveyed, corresponding to 35 K SNPs. We validated a subset of 1538 SNPs through the GoldenGate assay, proving their ability to structure a diversity panel of breeding germplasm. Among them, 1340 were genetically mapped and used to build a new consensus map comprising a total of 2070 markers. Based on blast analysis, we could establish 1252 bridges between our pea consensus map and the pseudochromosomes of M. truncatula, which provides new insight on synteny between the two species. Conclusions: Our approach created significant new resources in pea, i.e. the most comprehensive genetic map to date tightly linked to the model species M. truncatula and a large SNP resource for both academic research and breeding.
Features
This publication contains information about 2,066 features:
Feature NameUniquenameType
Ps000473Ps000473genetic_marker
Ps000280Ps000280genetic_marker
Ps000545Ps000545genetic_marker
Ps000696Ps000696genetic_marker
Ps900157Ps900157genetic_marker
Ps900299Ps900299genetic_marker
Ps000009Ps000009genetic_marker
Ps000144Ps000144genetic_marker
Ps000475Ps000475genetic_marker
Ps000462Ps000462genetic_marker
Ps000289Ps000289genetic_marker
Ps000487Ps000487genetic_marker
Ps000712Ps000712genetic_marker
Ps000549Ps000549genetic_marker
Ps000605Ps000605genetic_marker
Ps000692Ps000692genetic_marker
Ps000622Ps000622genetic_marker
Ps000089Ps000089genetic_marker
Ps000499Ps000499genetic_marker
Ps000526Ps000526genetic_marker
Ps000759Ps000759genetic_marker
Ps000620Ps000620genetic_marker
Ps900294Ps900294genetic_marker
Ps900382Ps900382genetic_marker
Ps900195Ps900195genetic_marker

Pages

Featuremaps
This publication contains information about 1 maps:
Map Name
Pea-Composite_Map-RIL
Properties
Additional details for this publication include:
Property NameValue
URLhttp://www.biomedcentral.com/1471-2164/15/126