A conserved molecular basis for photoperiod adaptation in two temperate legumes

Weller, James L.; Liew, Lim Chee; Hecht, Valérie; Rajandran, Vinodan; Laurie, Rebecca E.; Ridge, Stephen; Wenden, Bénédicte; Schoor, Jacqueline K. Vander; Jaminon, Odile; Blassiau, Christelle; Dalmais, Marion; Rameau, Catherine; Bendahmane, Abdelhafid; Macknight, Richard C.; Lejeune‐Hénaut, Isabelle

doi:10.1073/pnas.1207943110

Cited by 167 publications

(215 citation statements)

References 39 publications

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“…We subsequently identified a third recessive mutant allele, ppd-3, from EMS mutagenesis of the pea line NGB5839 (Hecht et al, 2007), which has been widely used as a reference wild-type line. Both of these parental lines carry the same hr mutation (Weller et al, 2012). Figure 1 and Supplemental Figure S1 confirm that in contrast to the photoperiod-responsive wild type (P , 0.001), the ppd-3 allele confers early flowering (P , 0.001) regardless of photoperiod, equivalent to ppd-1 and ppd-2 (Taylor and Murfet, 1996) and to sn and dne mutants (Murfet, 1971;King and Murfet, 1985;Liew et al, 2009Liew et al, , 2014.…”

Section: Ppd Contributes To Photoperiodic Floweringsupporting

confidence: 48%

“…In the closely syntenic region of Medicago truncatula chromosome 1, these markers correspond to gene models Medtr1g009200 and Medtr1g018840 and define an interval of around 4.3 Mb containing ;900 genes. Within this region we identified several genes potentially related to flowering time control, including two miR156 genes, the CONSTANS-like gene COLb (Wong et al, 2014), and a gene with strong similarity to the previously described HR/ELF3 gene (Weller et al, 2012), which we termed ELF3b. In view of the circadian clockrelated role of PPD, we considered only the last two sequences as plausible candidates.…”

Section: Ppd Is the Second Of Two Duplicate Elf3 Genes In Peamentioning

confidence: 99%

“…In the long-day legume species pea, the ELF3 ortholog HR has a central role in photoperiod adaptation, with a null mutation conferring partial loss of photoperiod responsiveness and earlier flowering under short photoperiods, and this appears to have been central to adaptation of the crop to spring sowing and expansion to higher latitudes (Weller et al, 2012). Naturally occurring and induced mutations in the LUX ortholog SN completely eliminate responsiveness to photoperiod (Liew et al, 2014), whereas a mutant for the ELF4 ortholog DNE enhances the effect of the hr mutation but has little effect when functional HR is present (Liew et al, 2009(Liew et al, , 2014.…”

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“…Interestingly, in both crop groups, mutations in ELF3 genes have been shown to contribute to the expansion in range of species through alteration of photoperiod responsiveness and the associated impact on yield (Faure et al, 2012;Matsubara et al, 2012;Weller et al, 2012;Zakhrabekova et al, 2012;Alvarez et al, 2016;Lu et al, 2017). In crop species, a role for ELF4 function has been clearly established only in the legume species pea (Pisum sativum; Liew et al, 2009), but mutations in LUX orthologs have also been shown to cause early flowering and impaired photoperiod response in pea and in the cereals einkorn wheat (Triticum aestivum) and barley (Hordeum vulgare; Mizuno et al, 2012;Campoli et al, 2013;Liew et al, 2014), suggesting that the EC genes are likely to be intimately linked to the photoperiod response mechanism in both crop groups.…”

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EARLY FLOWERING3 Redundancy Fine-Tunes Photoperiod Sensitivity

et al. 2017

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Three pea (Pisum sativum) loci controlling photoperiod sensitivity, HIGH RESPONSE (HR), DIE NEUTRALIS (DNE), and STERILE NODES (SN), have recently been shown to correspond to orthologs of Arabidopsis (Arabidopsis thaliana) circadian clock genes EARLY FLOWERING3 (ELF3), ELF4, and LUX ARRHYTHMO, respectively. A fourth pea locus, PHOTOPERIOD (PPD), also contributes to the photoperiod response in a similar manner to SN and DNE, and recessive ppd mutants on a springflowering hr mutant background show early, photoperiod-insensitive flowering. However, the molecular identity of PPD has so far remained elusive. Here, we show that the PPD locus also has a role in maintenance of diurnal and circadian gene expression rhythms and identify PPD as an ELF3 co-ortholog, termed ELF3b. Genetic interactions between pea ELF3 genes suggest that loss of PPD function does not affect flowering time in the presence of functional HR, whereas PPD can compensate only partially for the lack of HR. These results provide an illustration of how gene duplication and divergence can generate potential for the emergence of more subtle variations in phenotype that may be adaptively significant.

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Section: Ppd Contributes To Photoperiodic Floweringsupporting

confidence: 48%

Section: Ppd Is the Second Of Two Duplicate Elf3 Genes In Peamentioning

confidence: 99%

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EARLY FLOWERING3 Redundancy Fine-Tunes Photoperiod Sensitivity

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“…In legumes such as Pisum sativum (pea), Glycine max (Soybean) and Medicago truncatula (Medicago), studies on flowering gene orthologues have discovered several genes with a conserved role in the regulation of flowering time in response to photoperiod. However, the function of these CO homologues in photoperiod response is still not clear (Hecht et al, 2005;Hecht et al, 2007;Jiang et al, 2011;Liu et al, 2011;Watanabe et al, 2011;Weller et al, 2012;Wong et al, 2014).…”

Section: Timing Of Cab Expression (Cct)mentioning

confidence: 99%

Molecular characterisation of flowering genes in Pongamia Pinnata

Kamde¹

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Pongamia pinnata (Pongamia) is a multipurpose tree that has been used traditionally for medicine, green manure, insecticide, fuel and also a source of timber. It is an indigenous plant to the Indian subcontinent and Southeast Asia, and has been successfully introduced to Northern Australia, New Zealand and several other countries with humid tropical lowlands. Recently, Pongamia has attracted interest as one of the alternative feedstock for biodiesel productions due to its ability to produce seeds with high oil content. The fatty acid methyl ester (FAME) composition of Pongamia met the biodiesel specification standards of USA (ASTMD 6751), Germany (DIN 51606) and European Standard Organisation (EN 14214), and is considered as one of the most suitable sources of biodiesel. Despite the positive attributes described above, Pongamia is not a domesticated species and further research is required for the selection of elite cultivars with desirable traits optimal for large scale production of Pongamia oil. In addition, limited information is currently available regarding the flowering mechanism of Pongamia at the molecular level that could provide the platform for the development of oil-rich seeds.The aim of this thesis is to provide insight and increase the understanding of the genetic network that leads to flowering in Pongamia. Based on large phenotypic diversity of Pongamia, this information could subsequently be used to determine and select traits with unique flowering time that will allow a harvesting window, where harvesting process will not clash with flowering. The first objective of this project is to identify, isolate and characterise the candidate genes that regulate flowering time in Pongamia. This was achieved using molecular biology techniques and bioinformatic approaches based on the information available on flowering mechanisms of Arabidopsis and soybean in the literature. The second objective of this project is to determine the expression pattern of isolated genes during flowering onset. This was achieved through transcriptome methodologies such as RT-PCR and qRT-PCR. The third objective of this project is to investigate the genetic variety of Pongamia. This was achieved through Single Nucleotide Polymorphism (SNPs) analysis and its correlation with the late flowering phenotype of Pongamia.PpCOL-1 and PpPHYB are the two genes that were investigated in this thesis. The orthologue genes of PpCOL-1 and PpPHYB are involved in the flowering regulation of the annual plant Arabidopsis.Since Arabidopsis and Pongamia are both long day plants, it is postulated that these genes might play a role in the flowering time control in Pongamia. PpCOL-1 and PpPHYB were successfully isolated, characterised and compared to their respective orthologue genes in Arabidopsis, Soybean and Medicago. It was found that the amino acid residues within the domain regions in these genes iii are highly conserved in Pongamia. Interestingly, there were no significant differences in the expression patterns of PpCOL-1 and PpPHYB in...

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