Sequence differences in the seed dormancy gene Qsd1 among various wheat genomes

Onishi, Kazumitsu; Yamane, Minoru; Yamaji, Nami; Tokui, Mayumi; Kanamori, Hajime; Wu, Jianzhong; Komatsuda, Takao; Sato, Kazuhiro

doi:10.1186/s12864-017-3880-6

Cited by 19 publications

(18 citation statements)

References 24 publications

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“…We previously identified the orthologous sequence of Qsd1 in hexaploid wheat cv. Chinese Spring (IWGSC, 2018;Onishi et al, 2017). However, Qsd1 orthologs have not been functionally characterized in hexaploid wheat lines harboring spontaneous or induced mutations, likely due to its polyploid nature and the difficulty in collecting all three homeoalleles in a single plant.…”

Section: Discussionmentioning

confidence: 99%

Genome-Edited Triple-Recessive Mutation Alters Seed Dormancy in Wheat

et al. 2019

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Section: Discussionmentioning

confidence: 99%

Genome-Edited Triple-Recessive Mutation Alters Seed Dormancy in Wheat

et al. 2019

Self Cite

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“…It segregates under a recessive genetic system (Sato, Matsumoto, Ooe, & Takeda, 2009), and loss of function of the Qsd1 allele results in longer seed dormancy (Sato et al, 2016). Onishi et al (2017) weight, and amylase activity in seeds and oxidation rate in roots, all contribute to seedling vigor in rice (Anandan, Anumalla, Pradhan, & Ali, 2016;Cui et al, 2002). Wild and weedy rice Oryza nivara is well known for its vigor and survival in adverse environmental conditions (Eizenga et al, 2016).…”

Section: Genomic Assisted Breeding To Select For Preharvest Sproutingmentioning

confidence: 99%

First the seed: Genomic advances in seed science for improved crop productivity and food security

Dwivedi¹,

Spillane

Lopez

et al. 2021

Crop Science

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Seeds are valuable sources of carbohydrates, lipids, proteins, fibers, minerals, and vitamins. They provide energy and nutrition to germinating seedlings, food to humans, feed to livestock and feedstocks to industry. High-throughput analyses of gene expression in crops has identified many candidate genes associated with seed dormancy, longevity, germination, and vigor. In this review, we cover the latest research focusing on such key seed traits. Transcriptome analyses of time-courses of seed filling have identified sets of genes expressed at different stages of this process. The potential role of epigenetics (including seed-endosperm imprinted genes) in regulating seed development and chemistry is highlighted herein. We also discuss how advances in genomics and seed biology are facilitating the unravelling of associations between seed traits with genebank accessions and gene sequences, including how functional research can accelerate the discovery of allelic variants. Such knowledge of functional effects relating to gene variants is necessary for more efficient and cost-effective management of genetic resources or for redesigning crops with specific seed characteristics. For instance, genebank curators may assess seed viability by monitoring changes in gene expression of biomarker genes in dry seed samples to decide germplasm regeneration and assess genetic integrity of collections by monitoring changes in This article is protected by copyright. All rights reserved. diversity and allele frequencies between samples of same accession stored in genebanks. We highlight that resistance to preharvest sprouting can be enhanced through genomicsassisted breeding in otherwise nondormant rice and wheat cultivars, while pimt, another valuable marker for seed longevity, may be deployed to enhance seed vigor in crops.

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“…In wheat, certain TaQsd1-B allelic variants produce significantly longer seed dormancy periods compared to others; for example, the TaQsd1-B allele in cv. Chinese Spring produces longer dormancy (Onishi et al 2017).…”

Section: Pre-harvest Sprouting and Seed Dormancymentioning

confidence: 99%

Gene editing applications to modulate crop flowering time and seed dormancy

et al. 2020

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Gene editing technologies such as CRISPR/Cas9 have been used to improve many agricultural traits, from disease resistance to grain quality. Now, emerging research has used CRISPR/Cas9 and other gene editing technologies to target plant reproduction, including major areas such as flowering time and seed dormancy. Traits related to these areas have important implications for agriculture, as manipulation of flowering time has multiple applications, including tailoring crops for regional adaptation and improving yield. Moreover, understanding seed dormancy will enable approaches to improve germination upon planting and prevent pre-harvest sprouting. Here, we summarize trends and recent advances in using gene editing to gain a better understanding of plant reproduction and apply the resulting information for crop improvement.

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Sequence differences in the seed dormancy gene Qsd1 among various wheat genomes

Cited by 19 publications

References 24 publications

Genome-Edited Triple-Recessive Mutation Alters Seed Dormancy in Wheat

Genome-Edited Triple-Recessive Mutation Alters Seed Dormancy in Wheat

First the seed: Genomic advances in seed science for improved crop productivity and food security

Gene editing applications to modulate crop flowering time and seed dormancy

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