Genome of the long-living sacred lotus (Nelumbo nucifera Gaertn.)

Ming, Ray; VanBuren, Robert; Liu, Yanling; Yang, Mei; Han, Yuepeng; Li, Lei Ting; Zhang, Qiong; Kim, Min Jeong; Schatz, Michael C.; Campbell, Michael S.; Li, Jingping; Bowers, John E.; Tang, Haibao; Lyons, Eric; Ferguson, Ann A.; Narzisi, Giuseppe; Nelson, David R.; Blaby‐Haas, Crysten E.; Gschwend, Andrea R.; Jiao, Yuannian; Der, Joshua P.; Zeng, Fanchang; Han, Jennifer; Min, Xiang Jia; Hudson, Karen A.; Singh, Ratnesh; Grennan, Aleel K.; Karpowicz, Steven J.; Watling, Jennifer R.; K, Ito; Robinson, Sharon A.; Hudson, Matthew E.; Yu, Qingyi; Mockler, Todd C.; Carroll, Andrew; Zheng, Yun; Sunkar, Ramanjulu; Jia, Ruizong; Chen, Nancy; Arro, Jie; Wai, Ching Man; Wafula, Eric; Spence, Ashley K.; Han, Yinfeng; Xu, Liming; Zhang, Jisen; Peery, Rhiannon; Haus, Miranda J.; Xiong, Wenwei; Walsh, James A.; Wu, Jun; Wang, Ming Li; Zhu, Yun; Paull, Robert E.; Britt, Anne B.; Du, Chunguang; Downie, Stephen R.; Schuler, Mary A.; Michael, Todd P.; Long, Stephen P.; Ort, Donald R.; Schopf, J. William; Gang, David R.; Jiang, Ning; Yandell, Mark; dePamphilis, Claude W.; Merchant, Sabeeha; Paterson, Andrew H.; Buchanan, Bob B.; Li, Shaohua; Shen-Miller, J.

doi:10.1186/gb-2013-14-5-r41

Cited by 344 publications

(409 citation statements)

References 33 publications

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“…At least one more polyploidy event was identified along the branches leading to all eudicot lineages depicted except Vitis [30,58,93,95]. Three independent polyploidy events were proposed on the terminal branch to Musa acuminata [34].…”

Section: Palaeopolyploidy and Gene Family Gainsmentioning

confidence: 98%

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Polyploidy-associated genome modifications during land plant evolution

Jiao

Paterson

2014

Phil. Trans. R. Soc. B

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The occurrence of polyploidy in land plant evolution has led to an acceleration of genome modifications relative to other crown eukaryotes and is correlated with key innovations in plant evolution. Extensive genome resources provide for relating genomic changes to the origins of novel morphological and physiological features of plants. Ancestral gene contents for key nodes of the plant family tree are inferred. Pervasive polyploidy in angiosperms appears likely to be the major factor generating novel angiosperm genes and expanding some gene families. However, most gene families lose most duplicated copies in a quasi-neutral process, and a few families are actively selected for single-copy status. One of the great challenges of evolutionary genomics is to link genome modifications to speciation, diversification and the morphological and/or physiological innovations that collectively compose biodiversity. Rapid accumulation of genomic data and its ongoing investigation may greatly improve the resolution at which evolutionary approaches can contribute to the identification of specific genes responsible for particular innovations. The resulting, more ‘particulate’ understanding of plant evolution, may elevate to a new level fundamental knowledge of botanical diversity, including economically important traits in the crop plants that sustain humanity.

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Section: Palaeopolyploidy and Gene Family Gainsmentioning

confidence: 98%

“…This is somewhat in conflict with the other large gains, which usually accompanied one or more WGD events. The inconsistency could be due to the timing and nature of the gamma event, which may actually be two events that occurred in close proximity, very early in the evolutionary history of eudicots [93].…”

Section: Palaeopolyploidy and Gene Family Gainsmentioning

confidence: 99%

Polyploidy-associated genome modifications during land plant evolution

Jiao

Paterson

2014

Phil. Trans. R. Soc. B

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“…Like the SEP1-SQUA and SEP3-SFT tandems in Figure 4A, we found that the AGL6-TM3 tandem gene arrangement is widespread across angiosperms (Figures 4B and 4C; Supplemental Data Set 3). For example, there is one AGL6-TM3 tandem gene pair in A. trichopoda and two such tandems in N. nucifera likely due to the most recent WGD this species experienced (Ming et al, 2013;Wang et al, 2013) ( Figure 4C; Supplemental Data Set 3). In V. vinifera, we also found two AGL6-TM3 tandems ( Figure 4C; Supplemental Data Set 3) that likely originated from the g triplication after which one tandem lost its AGL6 locus.…”

Section: Ii2 Angiosperm-wide Conserved Agl6-tm3 Tandemmentioning

confidence: 99%

Phylogenomic Synteny Network Analysis of MADS-Box Transcription Factor Genes Reveals Lineage-Specific Transpositions, Ancient Tandem Duplications, and Deep Positional Conservation

et al. 2017

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Conserved genomic context provides critical information for comparative evolutionary analysis. With the increase in numbers of sequenced plant genomes, synteny analysis can provide new insights into gene family evolution. Here, we exploit a network analysis approach to organize and interpret massive pairwise syntenic relationships. Specifically, we analyzed synteny networks of the MADS-box transcription factor gene family using 51 completed plant genomes. In combination with phylogenetic profiling, several novel evolutionary patterns were inferred and visualized from synteny network clusters. We found lineage-specific clusters that derive from transposition events for the regulators of floral development (APETALA3 and PI) and flowering time (FLC) in the Brassicales and for the regulators of root development (AGL17) in Poales. We also identified two large gene clusters that jointly encompass many key phenotypic regulatory Type II MADS-box gene clades (SEP1, SQUA, TM8, SEP3, FLC, AGL6, and TM3). Gene clustering and gene trees support the idea that these genes are derived from an ancient tandem gene duplication that likely predates the radiation of the seed plants and then expanded by subsequent polyploidy events. We also identified angiosperm-wide conservation of synteny of several other less studied clades. Combined, these findings provide new hypotheses for the genomic origins, biological conservation, and divergence of MADS-box gene family members.

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“…Notably, its seeds can survive for thousands of years, making it the oldest viable seed for which an age has been directly determined (Priestley and Posthumus, 1982). To date, the entire genomic sequence of N. nucifera has been published (Ming et al, 2013); however, the UBC gene has not yet been reported. Therefore, in this study, the UBC gene was cloned and characterized in N. nucifera.…”

Section: Introductionmentioning

confidence: 99%

Cloning and characterization of the UBC gene from lotus (Nelumbo nucifera)

Diao

Xw³

et al. 2016

Genet. Mol. Res.

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ABSTRACT. Protein ubiquitination is extensively involved in the regulation of a considerable number of physiological processes in plant cells. E2 (ubiquitin-conjugating enzyme, UBC), one of the essential enzymes of eukaryotic ubiquitination, catalyzes protein ubiquitination together with E1 and E3. In this study, we cloned four full-length cDNA NnUBCs of Nelumbo nucifera. With the same coding sequence length of 459 bp and coding 153 amino acids, these four genes are highly homologous with the AtUBC1 and AtUBC2 of Arabidopsis thaliana. Quantitative fluorescence polymerase chain reaction showed that these four genes exhibited different expression patterns in different tissues of N. nucifera. Overall, the expression of NnUBC3 was the highest in all plant tissues. Tests of different stress treatments showed that NnUBC3 plays an important role in response to heat, salt, and drought stresses in N. nucifera. Moreover, transgenic Arabidopsis plants (Atubc1-1Atubc2-1 mutant) expressing NnUBC3 presented a wild-type phenotype, indicating that NnUBC3 performs the same function as AtUBC1 and AtUBC2.

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Genome of the long-living sacred lotus (Nelumbo nucifera Gaertn.)

Cited by 344 publications

References 33 publications

Polyploidy-associated genome modifications during land plant evolution

Polyploidy-associated genome modifications during land plant evolution

Phylogenomic Synteny Network Analysis of MADS-Box Transcription Factor Genes Reveals Lineage-Specific Transpositions, Ancient Tandem Duplications, and Deep Positional Conservation

Cloning and characterization of the UBC gene from lotus (Nelumbo nucifera)

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