Map-Based Cloning of the Gene Associated With the Soybean Maturity Locus <i>E3</i>

Watanabe, Satoshi; Hideshima, Rumiko; Xia, Zhengjun; Tsubokura, Yasutaka; Sato, Shusei; Nakamoto, Yuya; Yamanaka, Naoki; Takahashi, Ryōsuke; Ishimoto, Masao; Anai, Toyoaki; Tabata, Satoshi; Harada, Kyuya

doi:10.1534/genetics.108.098772

Cited by 334 publications

(364 citation statements)

References 65 publications

(69 reference statements)

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“…Group II consisted of landraces that are grown as a short-season crop across Japan and the Korean peninsula (9-15), including Sakamotowase, which has the genotype e3e3E4E4 and a dysfunctional allele (e1-fs) at the E1 locus [19][20][21]. Group III consisted of landraces collected in northern Honshu, Japan (16)(17)(18)(19)(20)(21). Tsukue-4 (group IV, accession 22) and Otomewase (group V, accession 23) together formed a loose clade.…”

Section: Classification Of Photoperiod-insensitive Soybean Accessionsmentioning

confidence: 99%

“…Approximately 75% of the genes are present as multiple copies, some of which have diverged in their functions, as suggested by different expression patterns between homoeologs [28,29]. phyA is one such example, and consists of 2 sets of homoeologous partners, GmphyA1/GmphyA2(E4) and GmphyA3(E3)/GmphyA4 [16][17][18]. The presence of multiple copies of soybean phyA contrasts sharply with other legume species such as pea (Pisum sativum), Medicago truncatula, and Lotus japonicus, which all possess a single phyA gene [30].…”

Section: Gmphya1mentioning

confidence: 99%

“…Four major maturity loci-E1, E3, E4, and E7-have so far been reported to be involved in the control of this insensitivity [9-15, reviewed in 16]. Recent molecular analyses have revealed that E3 and E4 encode the phytochrome A (phyA) proteins GmphyA3 and GmphyA2, respectively [17,18]; and that E1 encodes a protein that contains a putative bipartite nuclear localization signal and a region distantly related to a B3 domain, and controls time to flowering by suppressing the expression of two soybean orthologs of FT, GmFT2a and GmFT5a, under the regulation of E3 and E4 [19]. A phyA-regulated E1-GmFT pathway is thus a key determinant of the adaptation of soybean to long-daylength environments.…”

Section: Introductionmentioning

confidence: 99%

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Genetic Variation in Soybean at the Maturity Locus E4 Is Involved in Adaptation to Long Days at High Latitudes

Tsubokura

Matsumura

et al. 2013

Agronomy

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Soybean (Glycine max) cultivars adapted to high latitudes have a weakened or absent sensitivity to photoperiod. The purposes of this study were to determine the molecular basis for photoperiod insensitivity in various soybean accessions, focusing on the sequence diversity of the E4 (GmphyA2) gene, which encodes a phytochrome A (phyA) protein, and OPEN ACCESSAgronomy 2013, 3 118 its homoeolog (GmphyA1), and to disclose the evolutionary consequences of two phyA homoeologs after gene duplication. We detected four new single-base deletions in the exons of E4, all of which result in prematurely truncated proteins. A survey of 191 cultivated accessions sourced from various regions of East Asia with allele-specific molecular markers reliably determined that the accessions with dysfunctional alleles were limited to small geographical regions, suggesting the alleles' recent and independent origins from functional E4 alleles. Comparison of nucleotide diversity values revealed lower nucleotide diversity at non-synonymous sites in GmphyA1 than in E4, although both have accumulated mutations at almost the same rate in synonymous and non-coding regions. Natural mutations have repeatedly generated loss-of-function alleles at the E4 locus, and these have accumulated in local populations. The E4 locus is a key player in the adaptation of soybean to high-latitude environments under diverse cropping systems.

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Section: Classification Of Photoperiod-insensitive Soybean Accessionsmentioning

confidence: 99%

Section: Gmphya1mentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Genetic Variation in Soybean at the Maturity Locus E4 Is Involved in Adaptation to Long Days at High Latitudes

Tsubokura

Matsumura

et al. 2013

Agronomy

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“…Thanks to advances in sequencing and the genomewide identification of sequence polymorphisms (e.g. SNPs), MBC became more accessible, and has been conducted in a range of crop species such as rice (Vij and Tyagi 2007) as well as in some legumes including soybean (Watanabe et al 2009). …”

Section: Forward Genetics Based Gene Cloningmentioning

confidence: 99%

“…The majority of the MBC projects in crop legumes have been applied in soybean. For example, the soybean phytochrome A gene (GmPhyA3) which modulates flowering time has been cloned using an MBC approach (Watanabe et al 2009). In a different study, a candidate gene Ln controlling leaflet and seed number per pod was cloned with a combination of MBC and association study (Fang et al 2013).…”

Section: Forward Genetics Based Gene Cloningmentioning

confidence: 99%

Functional genomics to study stress responses in crop legumes: progress and prospects

Kudapa

Ramalingam

Nayakoti

et al. 2013

Functional Plant Biol.

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Abstract. Legumes are important food crops worldwide, contributing to more than 33% of human dietary protein. The production of crop legumes is frequently impacted by abiotic and biotic stresses. It is therefore important to identify genes conferring resistance to biotic stresses and tolerance to abiotic stresses that can be used to both understand molecular mechanisms of plant response to the environment and to accelerate crop improvement. Recent advances in genomics offer a range of approaches such as the sequencing of genomes and transcriptomes, gene expression microarray as well as RNA-seq based gene expression profiling, and map-based cloning for the identification and isolation of biotic and abiotic stressresponsive genes in several crop legumes. These candidate stress associated genes should provide insights into the molecular mechanisms of stress tolerance and ultimately help to develop legume varieties with improved stress tolerance and productivity under adverse conditions. This review provides an overview on recent advances in the functional genomics of crop legumes that includes the discovery as well as validation of candidate genes.

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Genetic control of flowering time in legumes

Weller¹,

Macknight²

2019

The Model Legume Medicago Truncatula

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The timing of flowering, and in particular the degree to which it is responsive to the environment, is a key factor in the adaptation of a given species to various ecogeographic locations and agricultural practices. Flowering time variation has been documented in many crop legumes, and selection for specific variants has permitted significant expansion and improvement in cultivation, from prehistoric times to the present day. Recent advances in legume genomics have accelerated the process of gene identification and functional analysis, and opened up new prospects for a molecular understanding of flowering time adaptation in this important crop group. Within the legumes, two species have been prominent in flowering time studies; the vernalization-responsive long-day species pea (Pisum sativum) and the warm-season short-day plant soybean (Glycine max). Analysis of flowering in these species is now being complemented by reverse genetics capabilities in the model legumes Medicago truncatula and Lotus japonicus, and the emergence of genome-scale resources in a range of other legumes. This review will outline the insights gained from detailed forward genetic analysis of flowering time in pea and soybean, highlighting the importance of light perception, the circadian clock and the FT family of flowering integrators. It discusses the current state of knowledge on genetic mechanisms for photoperiod and vernalization response, and concludes with a broader discussion of flowering time adaptation across legumes generally.

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Map-Based Cloning of the Gene Associated With the Soybean Maturity Locus E3

Cited by 334 publications

References 65 publications

Genetic Variation in Soybean at the Maturity Locus E4 Is Involved in Adaptation to Long Days at High Latitudes

Genetic Variation in Soybean at the Maturity Locus E4 Is Involved in Adaptation to Long Days at High Latitudes

Functional genomics to study stress responses in crop legumes: progress and prospects

Genetic control of flowering time in legumes

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