The Soybean-Specific Maturity Gene <i>E1</i> Family of Floral Repressors Controls Night-Break Responses through Down-Regulation of <i>FLOWERING LOCUS T</i> Orthologs

Xu, Ming; Yamagishi, Noriko; Zhao, Chen; Takeshima, Ryoma; Kasai, Megumi; Watanabe, Satoshi; Kanazawa, Akira; Yoshikawa, Nobuyuki; Liu, Baohui; Yamada, Tetsuya; Abe, Jun

doi:10.1104/pp.15.00763

Cited by 93 publications

(125 citation statements)

References 64 publications

(91 reference statements)

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“…However, genes in the FTb clade are clearly lacking in L. angustifolius , suggesting that these genes do not play an essential evolutionary role in legume photoperiod responses, and raising the question of which FT genes may mediate the photoperiod response in this species. In soybean, two genes in the FTa3 and FTc clades ( FT2a and FT5a ) (Kong et al ., ; Xu et al ., ) have prominent roles in induction of flowering by photoperiod, and our analysis of the lupin genome suggests that a minimum complement of FTa3 and FTc genes may be sufficient for both vernalization and photoperiod responsiveness. It will be interesting in future to examine which lupin FT gene(s) may be regulated by photoperiod.…”

Section: Discussionmentioning

confidence: 90%

The loss of vernalization requirement in narrow‐leafed lupin is associated with a deletion in the promoter and de‐repressed expression of a Flowering Locus T (FT) homologue

et al. 2016

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SummaryAdaptation of Lupinus angustifolius (narrow-leafed lupin) to cropping in southern Australian and northern Europe was transformed by a dominant mutation (Ku) that removed vernalization requirement for flowering. The Ku mutation is now widely used in lupin breeding to confer early flowering and maturity. We report here the identity of the Ku mutation.We used a range of genetic, genomic and gene expression approaches to determine whether Flowering Locus T (FT) homologues are associated with the Ku locus.One of four FT homologues present in the narrow-leafed lupin genome, LanFTc1, perfectly co-segregated with the Ku locus in a reference mapping population. Expression of LanFTc1 in the ku (late-flowering) parent was strongly induced by vernalization, in contrast to the Ku (early-flowering) parent, which showed constitutively high LanFTc1 expression. Cosegregation of this expression phenotype with the LanFTc1 genotype indicated that the Ku mutation impairs cis-regulation of LanFTc1. Sequencing of LanFTc1 revealed a 1.4-kb deletion in the promoter region, which was perfectly predictive of vernalization response in 216 wild and domesticated accessions. Linkage disequilibrium rapidly decayed around LanFTc1, suggesting that this deletion caused the loss of vernalization response. This is the first time a legume FTc subclade gene has been implicated in the vernalization response.

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Section: Discussionmentioning

confidence: 90%

The loss of vernalization requirement in narrow‐leafed lupin is associated with a deletion in the promoter and de‐repressed expression of a Flowering Locus T (FT) homologue

et al. 2016

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“…Stable QTL for days to flowering and putative QTL for days to pod-setting were overlapped and co-localized on linkage group Pv01 (closest markers ATA3 and BMb1024), suggesting pleiotropy for genes controlling these highly correlated traits. In soybean, such a gene involved in both maturation and induction of flowering (E1 and its homologues) has been reported [54]. The overall numbers of detected QTLs for phenological traits were higher in the season of 2014, which might be associated with observed difference in timing of flowering and maturation with regard to watering conditions.…”

Section: Discussionmentioning

confidence: 97%

QTL Mapping for Drought-Responsive Agronomic Traits Associated with Physiology, Phenology, and Yield in an Andean Intra-Gene Pool Common Bean Population

et al. 2020

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Understanding the genetic background of drought tolerance in common bean (Phaseolus vulgaris L.) can aid its resilience improvement. However, drought response studies in large seeded genotypes of Andean origin are insufficient. Here, a novel Andean intra-gene pool genetic linkage map was created for quantitative trait locus (QTL) mapping of drought-responsive traits in a recombinant inbred line population from a cross of two cultivars differing in their response to drought. Single environment and QTL × environment analysis revealed 49 QTLs for physiology, phenology, and yield-associated traits under control and/or drought conditions. Notable QTLs for days to flowering (Df1.1 and Df 1.2) were co-localized with a putative QTL for days to pods (Dp1.1) on linkage group 1, suggesting pleiotropy for genes controlling them. QTLs with stable effects for number of seeds per pod (Sp2.1) in both seasons and putative water potential QTLs (Wp1.1, Wp5.1) were detected. Detected QTLs were validated by projection on common bean consensus linkage map. Drought response-associated QTLs identified in the novel Andean recombinant inbred line (RIL) population confirmed the potential of Andean germplasm in improving drought tolerance in common bean. Yield-associated QTLs Syp1.1, Syp1.2, and Sp2.1 in particular could be useful for marker-assisted selection for higher yield of Andean common beans.

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“…The E series of genes were shown to be important factors for plant adaptation in soybean growing regions [12], [14]. It was recently hypothesized that three of those E genes ( E1 , E3 , and E4 ) play larger roles in pre- and post-flowering photoperiod responses [11].…”

Section: Discussionmentioning

confidence: 99%

“…It was shown that E1-E4 genes are involved in regulation of both pre-flowering and post-flowering growth of plants under different photoperiod length [11]. E1 is a flowering repressor and encodes a transcription factor that contains a putative nuclear localization signal and region related to the B3 DNA-binding domain [7], [12]. E2 is an orthologue of the Arabidopsis flowering gene GIGANTEA [2], [13].…”

Section: Introductionmentioning

confidence: 99%

Assessment of Soybean Flowering and Seed Maturation Time in Different Latitude Regions of Kazakhstan

et al. 2016

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Soybean is still a minor crop in Kazakhstan despite an increase in planting area from 4,500 to 11,400 km2 between 2006 and 2014. However, the Government’s recently accepted crop diversification policy projects the expansion of soybean cultivation area to more than 40,000 km2 by 2020. The policy is targeting significant expansion of soybean production in South-eastern, Eastern, and Northern regions of Kazakhstan. Successful realization of this policy requires a comprehensive characterization of plant growth parameters to identify optimal genotypes with appropriate adaptive phenotypic traits. In this study 120 soybean accessions from different parts of the World, including 18 accessions from Kazakhstan, were field tested in South-eastern, Eastern, and Northern regions of the country. These studies revealed positive correlation of yield with flowering time in Northern Kazakhstan, with seed maturity time in Eastern Kazakhstan, and with both these growth stages in South-eastern Kazakhstan. It was determined that in South-eastern, Eastern and Northern regions of Kazakhstan the majority of productive genotypes were in maturity groups MGI, MG0, and MG00, respectively. The accessions were genotyped for four major maturity genes (E1, E2, E3, and E4) in order to assess the relationship between E loci and agronomic traits. The allele composition of the majority of accessions was e1-as/e2/E3/E4 (specific frequencies 57.5%, 91.6%, 65.0%, and 63.3%, respectively). Accessions with dominant alleles in either E3 or E4 genes showed higher yield in all three regions, although the specific genotype associated with greatest productivity was different for each site. Genotype-environment interaction studies based on yield performances suggest that South-east and East regions formed one mega-environment, which was well separated from North Kazakhstan where significantly earlier time to maturation is required. The results provide important insights into the relationship between genetic and phenotypic patterns in new soybean growing territories in Kazakhstan.

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The Soybean-Specific Maturity Gene E1 Family of Floral Repressors Controls Night-Break Responses through Down-Regulation of FLOWERING LOCUS T Orthologs

Cited by 93 publications

References 64 publications

The loss of vernalization requirement in narrow‐leafed lupin is associated with a deletion in the promoter and de‐repressed expression of a Flowering Locus T (FT) homologue

The loss of vernalization requirement in narrow‐leafed lupin is associated with a deletion in the promoter and de‐repressed expression of a Flowering Locus T (FT) homologue

QTL Mapping for Drought-Responsive Agronomic Traits Associated with Physiology, Phenology, and Yield in an Andean Intra-Gene Pool Common Bean Population

Assessment of Soybean Flowering and Seed Maturation Time in Different Latitude Regions of Kazakhstan

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