A Study on the Genetic Relationships of Avena Taxa and the Origins of Hexaploid Oat

Overview

Journal Theor Appl Genet

Publisher Springer

Specialty Genetics

Date 2016 Apr 7

PMID 27048238

Citations 14

Authors

Paul Chew

Kendra Meade

Alec Hayes

Carlos Harjes

Yong Bao

Aaron D Beattie

Ian Puddephat

Gabe Gusmini

Steven D Tanksley

Affiliations

Soon will be listed here.

Abstract

Using next-generation DNA sequencing, it was possible to clarify the genetic relationships of Avena species and deduce the likely pathway from which hexaploid oat was formed by sequential polyploidization events. A sequence-based diversity study was conducted on a representative sample of accessions from species in the genus Avena using genotyping-by-sequencing technology. The results show that all Avena taxa can be assigned to one of four major genetic clusters: Cluster 1 = all hexaploids including cultivated oat, Cluster 2 = AC genome tetraploids, Cluster 3 = C genome diploids, Cluster 4 = A genome diploid and tetraploids. No evidence was found for the existence of discrete B or D genomes. Through a series of experiments involving the creation of in silico polyploids, it was possible to deduce that hexaploid oat likely formed by the fusion of an ancestral diploid species from Cluster 3 (A. clauda, A. eriantha) with an ancestral diploid species from Cluster 4D (A. longiglumis, A. canariensis, A. wiestii) to create the ancestral tetraploid from Cluster 2 (A. magna, A. murphyi, A. insularis). Subsequently, that ancestral tetraploid fused again with another ancestral diploid from Cluster 4D to create hexaploid oat. Based on the geographic distribution of these species, it is hypothesized that both the tetraploidization and hexaploidization events may have occurred in the region of northwest Africa, followed by radiation of hexaploid oat to its current worldwide distribution. The results from this study shed light not only on the origins of this important grain crop, but also have implications for germplasm collection and utilization in oat breeding.

Citing Articles

The mitochondrial genome of the diploid oat Avena longiglumis.

Liu Q, Yuan H, Xu J, Cui D, Xiong G, Schwarzacher T BMC Plant Biol. 2023; 23(1):218.

PMID: 37098475 PMC: 10131481. DOI: 10.1186/s12870-023-04217-8.

Oat chromosome and genome evolution defined by widespread terminal intergenomic translocations in polyploids.

Tomaszewska P, Schwarzacher T, Heslop-Harrison J Front Plant Sci. 2022; 13:1026364.

PMID: 36483968 PMC: 9725029. DOI: 10.3389/fpls.2022.1026364.

New Insights into the Genomic Structure of L.: Comparison of the Divergence of A-Genome and One C-Genome Oat Species.

Gnutikov A, Nosov N, Loskutov I, Blinova E, Shneyer V, Probatova N Plants (Basel). 2022; 11(9).

PMID: 35567104 PMC: 9102028. DOI: 10.3390/plants11091103.

Comparative sequencing and SNP marker validation for oat stem rust resistance gene Pg6 in a diverse collection of Avena accessions.

Gordon T, Jin Y, Tinker N, Bekele W, Gale S, Bockelman H Theor Appl Genet. 2022; 135(4):1307-1318.

PMID: 35113191 PMC: 9033690. DOI: 10.1007/s00122-022-04032-z.

Cytogenetic evidence supports Avena insularis being closely related to hexaploid oats.

Fominaya A, Loarce Y, Gonzalez J, Ferrer E PLoS One. 2021; 16(10):e0257100.

PMID: 34653181 PMC: 8519437. DOI: 10.1371/journal.pone.0257100.

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