Generation and Characterization of a Foxtail Millet () Mutant Library

Overview

Journal Front Plant Sci

Date 2019 Apr 20

PMID 31001298

Citations 6

Authors

Jing Sun

Ngoc Sinh Luu

Zhenhua Chen

Bing Chen

Xuean Cui

Jinxia Wu

Zhiguo Zhang

Tiegang Lu

Affiliations

Soon will be listed here.

Abstract

Foxtail millet () is attractive to plant scientists as a model plant because of several distinct characteristics, such as its short stature, rapid life cycle, sufficient seed production per plant, self-compatibility, true diploid nature, high photosynthetic efficiency, small genome size, and tolerance to abiotic and biotic stress. However, the study on the genetic resources of foxtail millet largely lag behind those of the other model plants such as , rice and maize. Mutagenized populations cannot only create new germplasm resources, but also provide materials for gene function research. In this manuscript, an ethyl methanesulfonate (EMS)-induced foxtail millet population comprising ∼15,000 individual M lines was established. Total 1353 independent lines with diverse abnormal phenotypes of leaf color, plant morphologies and panicle shapes were identified in M. Resequencing of sixteen randomly selected M plants showed an average estimated mutation density of 1 loci/213 kb. Moreover, we provided an example for rapid cloning of the gene by a map-based cloning method. A white panicle mutant, named as , exhibited significantly reduced chlorophyll (Chl) and carotenoid contents in leaf and panicle. Map-based cloning results showed an eight-base pair deletion located at the sixth exon of in LOC101786849, which caused the premature termination. encoded phytoene synthase. Moreover, the sequencing analysis and cross test verified that a white panicle mutant was an allelic mutant of . The filed phenotypic observation and gene cloning example showed that our foxtail millet EMS-induced mutant population would be used as an important resource for functional genomics studies of foxtail millet.

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