Phenotypic Effects of the U-genome Variation in Nascent Synthetic Hexaploids Derived from Interspecific Crosses Between Durum Wheat and Its Diploid Relative Aegilops Umbellulata

Overview

Journal PLoS One

Specialties General Medicine
Science

Date 2020 Apr 3

PMID 32240263

Citations 5

Authors

Moeko Okada

Asami Michikawa

Kentaro Yoshida

Kiyotaka Nagaki

Tatsuya M Ikeda

Shigeo Takumi

Affiliations

Soon will be listed here.

Abstract

Aegilops umbellulata is a wild diploid wheat species with the UU genome that is an important genetic resource for wheat breeding. To exploit new synthetic allohexaploid lines available as bridges for wheat breeding, a total of 26 synthetic hexaploid lines were generated through crossing between the durum wheat cultivar Langdon and 26 accessions of Ae. umbellulata. In nascent synthetic hexaploids with the AABBUU genome, the presence of the set of seven U-genome chromosomes was confirmed with U-genome chromosome-specific markers developed based on RNA-seq-derived data from Ae. umbellulata. The AABBUU synthetic hexaploids showed large variations in flowering- and morphology-related traits, and these large variations transmitted well from the parental Ae. umbellulata accessions. However, the variation ranges in most traits examined were reduced under the AABBUU hexaploid background compared with under the diploid parents. The AABBUU and AABBDD synthetic hexaploids were clearly discriminated by several morphological traits, and an increase of plant height and in the number of spikes and a decrease of spike length were commonly observed in the AABBUU synthetics. Thus, interspecific differences in several morphological traits between Ae. umbellulata and A. tauschii largely affected the basic plant architecture of the synthetic hexaploids. In conclusion, the AABBUU synthetic hexaploid lines produced in the present study are useful resources for the introgression of desirable genes from Ae. umbellulata to common wheat.

Citing Articles

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