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Verde_2013_Nat.Genet_45_487

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Title : The high-quality draft genome of peach (Prunus persica) identifies unique patterns of genetic diversity, domestication and genome evolution - Verde_2013_Nat.Genet_45_487
Author(s) : Verde I , Abbott AG , Scalabrin S , Jung S , Shu S , Marroni F , Zhebentyayeva T , Dettori MT , Grimwood J , Cattonaro F , Zuccolo A , Rossini L , Jenkins J , Vendramin E , Meisel LA , Decroocq V , Sosinski B , Prochnik S , Mitros T , Policriti A , Cipriani G , Dondini L , Ficklin S , Goodstein DM , Xuan P , Del Fabbro C , Aramini V , Copetti D , Gonzalez S , Horner DS , Falchi R , Lucas S , Mica E , Maldonado J , Lazzari B , Bielenberg D , Pirona R , Miculan M , Barakat A , Testolin R , Stella A , Tartarini S , Tonutti P , Arus P , Orellana A , Wells C , Main D , Vizzotto G , Silva H , Salamini F , Schmutz J , Morgante M , Rokhsar DS
Ref : Nat Genet , 45 :487 , 2013
Abstract :

Rosaceae is the most important fruit-producing clade, and its key commercially relevant genera (Fragaria, Rosa, Rubus and Prunus) show broadly diverse growth habits, fruit types and compact diploid genomes. Peach, a diploid Prunus species, is one of the best genetically characterized deciduous trees. Here we describe the high-quality genome sequence of peach obtained from a completely homozygous genotype. We obtained a complete chromosome-scale assembly using Sanger whole-genome shotgun methods. We predicted 27,852 protein-coding genes, as well as noncoding RNAs. We investigated the path of peach domestication through whole-genome resequencing of 14 Prunus accessions. The analyses suggest major genetic bottlenecks that have substantially shaped peach genome diversity. Furthermore, comparative analyses showed that peach has not undergone recent whole-genome duplication, and even though the ancestral triplicated blocks in peach are fragmentary compared to those in grape, all seven paleosets of paralogs from the putative paleoancestor are detectable.
PubMedSearch : Verde_2013_Nat.Genet_45_487
PubMedID: 23525075
Gene_locus related to this paper: prupe-a0a251pfr7 , prupe-a0a251r634 , prupe-m5x0p5 , prupe-m5xkg4 , prupe-m5x0q4 , prupe-m5vqa7 , prupe-m5wiw5 , prupe-a0a0u2wu32 , prupe-a0a251mtk1 , prupe-m5vl29 , prupe-m5vn82 , prupe-m5vq88 , prupe-m5y2s7 , prupe-m5wye7 , prupe-m5wxm4 , prupe-m5xqp6 , prupe-m5x4q4 , prupe-m5x4m1 , prupe-m5x6b3 , prupe-m5vlb6 , prupe-m5w4h3 , prupe-m5vlu4 , prupe-m5vln3 , prupe-a0a251myy7 , prupe-a0a251mws4 , prupe-m5vi18 , prupe-m5vh66 , prupe-m5xd54 , prupe-m5xqn2 , prupe-m5xr64 , prupe-m5vrm7 , prupe-m5vrk6 , prupe-m5vqp6 , prupe-a0a251nbb1 , prupe-a0a251nbd3 , prupe-a0a251nbb3 , prupe-a0a251nba0 , prupe-a0a251ndd4 , prupe-a0a251nbb6 , prupe-m5w315 , prupe-a0a251mwh1 , prupe-a0a251qn57 , prupe-m5vzh8 , prupe-m5xpz7 , prupe-m5xrp5 , prupe-m5wsr5 , prupe-m5xs20 , prupe-m5vl10 , prupe-a0a251nay9 , prupe-a0a251ndz1 , prupe-a0a251puf0 , prupe-m5wr61 , prupe-a0a251nyu6 , prupe-m5vl63

Related information

Gene_locus prupe-a0a251pfr7    prupe-a0a251r634    prupe-m5x0p5    prupe-m5xkg4    prupe-m5x0q4    prupe-m5vqa7    prupe-m5wiw5    prupe-a0a0u2wu32    prupe-a0a251mtk1    prupe-m5vl29    prupe-m5vn82    prupe-m5vq88    prupe-m5y2s7    prupe-m5wye7    prupe-m5wxm4    prupe-m5xqp6    prupe-m5x4q4    prupe-m5x4m1    prupe-m5x6b3    prupe-m5vlb6    prupe-m5w4h3    prupe-m5vlu4    prupe-m5vln3    prupe-a0a251myy7    prupe-a0a251mws4    prupe-m5vi18    prupe-m5vh66    prupe-m5xd54    prupe-m5xqn2    prupe-m5xr64    prupe-m5vrm7    prupe-m5vrk6    prupe-m5vqp6    prupe-a0a251nbb1    prupe-a0a251nbd3    prupe-a0a251nbb3    prupe-a0a251nba0    prupe-a0a251ndd4    prupe-a0a251nbb6    prupe-m5w315    prupe-a0a251mwh1    prupe-a0a251qn57    prupe-m5vzh8    prupe-m5xpz7    prupe-m5xrp5    prupe-m5wsr5    prupe-m5xs20    prupe-m5vl10    prupe-a0a251nay9    prupe-a0a251ndz1    prupe-a0a251puf0    prupe-m5wr61    prupe-a0a251nyu6    prupe-m5vl63
Gene_locus_frgt prupe-a0a251mwh8    prupe-a0a251mwh7

Citations formats

Verde I, Abbott AG, Scalabrin S, Jung S, Shu S, Marroni F, Zhebentyayeva T, Dettori MT, Grimwood J, Cattonaro F, Zuccolo A, Rossini L, Jenkins J, Vendramin E, Meisel LA, Decroocq V, Sosinski B, Prochnik S, Mitros T, Policriti A, Cipriani G, Dondini L, Ficklin S, Goodstein DM, Xuan P, Del Fabbro C, Aramini V, Copetti D, Gonzalez S, Horner DS, Falchi R, Lucas S, Mica E, Maldonado J, Lazzari B, Bielenberg D, Pirona R, Miculan M, Barakat A, Testolin R, Stella A, Tartarini S, Tonutti P, Arus P, Orellana A, Wells C, Main D, Vizzotto G, Silva H, Salamini F, Schmutz J, Morgante M, Rokhsar DS (2013)
The high-quality draft genome of peach (Prunus persica) identifies unique patterns of genetic diversity, domestication and genome evolution
Nat Genet 45 :487

Verde I, Abbott AG, Scalabrin S, Jung S, Shu S, Marroni F, Zhebentyayeva T, Dettori MT, Grimwood J, Cattonaro F, Zuccolo A, Rossini L, Jenkins J, Vendramin E, Meisel LA, Decroocq V, Sosinski B, Prochnik S, Mitros T, Policriti A, Cipriani G, Dondini L, Ficklin S, Goodstein DM, Xuan P, Del Fabbro C, Aramini V, Copetti D, Gonzalez S, Horner DS, Falchi R, Lucas S, Mica E, Maldonado J, Lazzari B, Bielenberg D, Pirona R, Miculan M, Barakat A, Testolin R, Stella A, Tartarini S, Tonutti P, Arus P, Orellana A, Wells C, Main D, Vizzotto G, Silva H, Salamini F, Schmutz J, Morgante M, Rokhsar DS (2013)
Nat Genet 45 :487