LncRNAs in polyploid cotton interspecific hybrids are derived from transposon neofunctionalization

Zhao, Ting; Tao, Xiaochun; Feng, Shouli; Wang, Luyao; Hong, Hui; Ma, Wei; Shang, Guan-Dong; Guo, Shisong; He, Yuxin; Zhou, Baoliang; Guan, Xueying

doi:10.1186/s13059-018-1574-2

Cited by 65 publications

(76 citation statements)

References 88 publications

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“…This is consistent with the apparent conservation of TE proportions between Cucurbita species, suggesting that TEs did not play an important role in lincRNA family evolution within Cucurbita after the whole-genome duplication, unlike in other taxa such as vertebrate species, where TEs play an important role in lincRNA birth (Kapusta et al, 2013). Our results also differ from those obtained in cotton, where a larger proportion of lincRNAs were homologous to TEs than to protein-coding loci (Zhao et al, 2018). This suggests that the evolutionary dynamics of lincRNAs can change drastically between different plant taxa.…”

Section: Molecular Plantsupporting

confidence: 88%

“…Studies regarding the evolutionary dynamics of lncRNAs are limited despite their evident importance in plant biology, due to a traditional focus on protein-coding genes in genome-wide studies (Ulitsky, 2016;Nelson et al, 2017). Furthermore, evolutionary analyses of these genes have been limited due to a lack of conservation at both the sequence level and the secondary structure level (Ulitsky, 2016), and research on their origin and evolution is still scarce (see Necsulea et al, 2014;Nelson et al, 2016;Zhao et al, 2018). Several hypotheses have been proposed to explain the emergence of new lncRNAs, such as the neofunctionalization of duplicated protein-coding genes, co-option of transposable elements in the genome, duplication followed by neofunctionalization from other lncRNAs, and de novo emergence (Kapusta et al, 2013).…”

Section: Introductionmentioning

confidence: 99%

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The Genome of Cucurbita argyrosperma (Silver-Seed Gourd) Reveals Faster Rates of Protein-Coding Gene and Long Noncoding RNA Turnover and Neofunctionalization within Cucurbita

et al. 2019

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Whole-genome duplications are an important source of evolutionary novelties that change the mode and tempo at which genetic elements evolve within a genome. The Cucurbita genus experienced a wholegenome duplication around 30 million years ago, although the evolutionary dynamics of the coding and noncoding genes in this genus have not yet been scrutinized. Here, we analyzed the genomes of four Cucurbita species, including a newly assembled genome of Cucurbita argyrosperma, and compared the gene contents of these species with those of five other members of the Cucurbitaceae family to assess the evolutionary dynamics of protein-coding and long intergenic noncoding RNA (lincRNA) genes after the genome duplication. We report that Cucurbita genomes have a higher protein-coding gene birth-death rate compared with the genomes of the other members of the Cucurbitaceae family. C. argyrosperma gene families associated with pollination and transmembrane transport had significantly faster evolutionary rates. lincRNA families showed high levels of gene turnover throughout the phylogeny, and 67.7% of the lincRNA families in Cucurbita showed evidence of birth from the neofunctionalization of previously existing protein-coding genes. Collectively, our results suggest that the whole-genome duplication in Cucurbita resulted in faster rates of gene family evolution through the neofunctionalization of duplicated genes.

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Section: Molecular Plantsupporting

confidence: 88%

Section: Introductionmentioning

confidence: 99%

The Genome of Cucurbita argyrosperma (Silver-Seed Gourd) Reveals Faster Rates of Protein-Coding Gene and Long Noncoding RNA Turnover and Neofunctionalization within Cucurbita

et al. 2019

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“…This phenomenon may be due to the regulation at the transcriptional or post‐transcriptional level. It has been reported that the activated expression of lncRNAs in interspecific hybrids was correlated with the demethylation of transposable elements (TEs) (Zhao et al ., ). We also found that citrus TE exhibited biased distribution toward lincRNA loci rather than protein‐coding genes and lincRNA loci contained significantly more TE segments at the exon and intron sequences compared with protein‐coding gene loci (Figure S12).…”

Section: Discussionmentioning

confidence: 97%

“…Although lincRNAs have been widely identified in plants, lincRNA conservation among different species remains largely unknown. Interspecies conservation of plant lincRNAs has been evaluated between distantly related rice and maize (Wang et al ., ), between two modern tomato species and one wild tomato species (Wang et al ., ), among four closely related cotton genomes (Wang et al ., ), and among tetraploid, diploid and F1 hybrid cotton (Zhao et al ., ). This study covered nine closely related citrus species and expanded the research scope to include primitive and modern citrus.…”

Section: Discussionmentioning

confidence: 99%

Evolutionary dynamics of lincRNA transcription in nine citrus species

Zhou

et al. 2019

The Plant Journal

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Summary Long intergenic non‐coding RNAs (lincRNAs) play important roles in various biological processes in plants. However, little information is known about the evolutionary characteristics of lincRNAs among closely related plant species. Here, we present a large‐scale comparative study of lincRNA transcription patterns in nine citrus species. By strand‐specific RNA‐sequencing, we identified 18 075 lincRNAs (14 575 lincRNA loci) from 34 tissue samples. The results indicated that the evolution of lincRNA transcription is more rapid than that of mRNAs. In total, 82.8–97.6% of sweet orange (Citrus sinensis) lincRNA genes were shown to have homologous sequences in other citrus genomes. However, only 15.5–28.8% of these genes had transcribed homologous lincRNAs in these citrus species, presenting a strong contrast to the high conservation of mRNA transcription (81.6–84.7%). Moreover, primitive and modern citrus lincRNAs were preferentially expressed in reproductive and vegetative organs, respectively. Evolutionarily conserved lincRNAs showed higher expression levels and lower tissue specificity than species‐specific lincRNAs. Notably, we observed a similar tissue expression pattern of homologous lincRNAs in sweet orange and pummelo (Citrus grandis), suggesting that these lincRNAs may be functionally conserved and selectively maintained. We also identified and validated a lincRNA with the highest expression in fruit that acts as an endogenous target mimic (eTM) of csi‐miR166c, and two lincRNAs that act as a precursor and target of csi‐miR166c, respectively. These lincRNAs together with csi‐miR166c could form an eTM166‐miR166c‐targeted lincRNA regulatory network that possibly affects citrus fruit development.

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“…However, hybrids often show a large spectrum of phenotypes, including extreme values that are unexpected given the parental traits (Rieseberg et al 1999;Landry et al 2007;Maheshwari & Barbash 2011;Bar-Zvi et al 2017). Indeed, previous studies have demonstrated the importance of large-scale regulatory rewiring in hybrids that impacts many processes and molecular phenotypes such as nucleosome positioning, translation efficiency, protein abundance, methylation, transcription of non-coding RNA, and the replication program (Landry et al 2007;Tirosh et al 2010;Tirosh & Barkai 2011;McManus et al 2014;Zhu et al 2017;Bar-Zvi et al 2017;Bamberger et al 2018;Zhao et al 2018).…”

Section: Introductionmentioning

confidence: 99%

Frequent assembly of chimeric complexes in the protein interaction network of an interspecies yeast hybrid

Dandage

Berger

Gagnon‐Arsenault

et al. 2020

Preprint

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Hybrids between species often show extreme phenotypes. The molecular determinants underlying such phenotypes are yet to be comprehensively explored. In this study, we investigated the phenotypes of an interspecies diploid hybrid in terms of protein-protein interactions detected by protein correlation profiling. We used two yeast species, Saccharomyces cerevisiae and Saccharomyces uvarum , which are interfertile, but yet have proteins diverged enough to be differentiated using mass spectrometry. Most of the protein-protein interactions are similar between hybrid and parents, and are consistent with the assembly of chimeric complexes, which we validated using an orthogonal approach for prefoldin complex. We also identify instances of altered protein-protein interactions in the hybrid, for instance in complexes related to proteostasis and in mitochondrial protein complexes. Overall, this study uncovers likely frequent occurrence of chimeric protein complexes with few exceptions, which may result from incompatibilities or imbalances between the parental proteomes.

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LncRNAs in polyploid cotton interspecific hybrids are derived from transposon neofunctionalization

Cited by 65 publications

References 88 publications

The Genome of Cucurbita argyrosperma (Silver-Seed Gourd) Reveals Faster Rates of Protein-Coding Gene and Long Noncoding RNA Turnover and Neofunctionalization within Cucurbita

The Genome of Cucurbita argyrosperma (Silver-Seed Gourd) Reveals Faster Rates of Protein-Coding Gene and Long Noncoding RNA Turnover and Neofunctionalization within Cucurbita

Evolutionary dynamics of lincRNA transcription in nine citrus species

Frequent assembly of chimeric complexes in the protein interaction network of an interspecies yeast hybrid

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