<i><scp>O</scp>s<scp>FIE</scp>2</i> plays an essential role in the regulation of rice vegetative and reproductive development

Li, Shisheng; Zhou, Bing; Peng, Xiongbo; Kuang, Quan; Huang, Xiaolong; Yao, Jialing; Du, Bo; Sun, Mingwei

doi:10.1111/nph.12472

Cited by 64 publications

(55 citation statements)

References 69 publications

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“…This is consistent with the role of H3K27me in rice endosperm development as knocking-down of OsFIE2 by RNAi results in abnormal endosperm development lacking of cellularization (Nallamilli et al 2013; Li et al 2014. Conversely, the elevated expression of OsFIE2 and slight down-regulation of OsMET1b were observed in the maternal excess cross, in which endosperm precociously cellularized.…”

Section: Discussionsupporting

confidence: 82%

“…We investigated the expression levels of OsFIE2 and OsMET1b , two major epigenetic modification genes showing function seed development (Luo et al 2009; Yamauchi et al 2009; Nallamilli et al 2013; Hu et al 2014; Li et al 2014) in the endosperm derived from the interploidy crosses and the parents Nip2n, TH4n and H2n (Fig. 3).…”

Section: Resultsmentioning

confidence: 99%

“…The rice genome contains two FERTILISATION INDEPENDENT ENDOSPERM ( FIE ) genes encoding members of the PRC2 complex (Luo et al 2009; Nallamilli et al 2013; Li et al 2014) and two MET1 genes (Yamauchi et al 2009; Hu et al 2014). OsFIE2 and OsMET1b are the major genes potentially regulating endosperm development and other processes (Luo et al 2009; Yamauchi et al 2009; Nallamilli et al 2013; Hu et al 2014; Li et al 2014).…”

Section: Introductionmentioning

confidence: 99%

“…OsFIE2 and OsMET1b are the major genes potentially regulating endosperm development and other processes (Luo et al 2009; Yamauchi et al 2009; Nallamilli et al 2013; Hu et al 2014; Li et al 2014). Given that PRC2 and MET1 are required for establishing postzygotic hybridization barrier via controlling imprinted genes in Arabidopsis (Erilova et al 2009; Kradolfer et al 2013a; Schatlowski et al 2014) and differential expression of imprinted genes between parental genomes in rice are likely controlled by differential H3K27me and DNA methylation (Rodrigues et al 2013; Du et al 2014), it is interesting to know if the rice PRC2 and MET1 counterparts have the same functions in regulating postzygotic hybridization barrier as in Arabidopsis, and whether loss of imprinting also occurs in the rice endosperm with parental genome imbalance.…”

Section: Introductionmentioning

confidence: 99%

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Parental Genome Imbalance Causes Post-Zygotic Seed Lethality and Deregulates Imprinting in Rice

Zhang

Luo

Johnson

et al. 2016

Rice

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BackgroundReproductive isolation between rice of different ploidy levels is manifested as endosperm and embryo abortion in seeds produced by interploidy crosses. Genomic imprinting is considered to be the underlying mechanism establishing the post-zygotic hybridization barrier. We characterized disrupted seed development in reciprocal crosses between a diploid Japonica rice and a tetraploid Indica rice.ResultsTriploid seeds from these crosses had aborted development and could not germinate in soil but could be rescued in culture medium with significantly more seeds developing to seedlings in the 4n × 2n (♀-♂) cross with excess maternal genomes than in the 2n × 4n cross with excess paternal genome. Consistent with previous findings, precocious endosperm cellularization and bigger embryos were observed in the seeds from the maternal excess cross, whereas absence of cellularization and arrested globular embryos were found in the seeds from the paternal excess cross, supporting the idea that endosperm cellularization is an important transition for embryo development. Moreover, we found that starch granules were persistently deposited in the pericarp parenchyma cells of the paternal excess cross, while pericarp starch gradually decreased and relocated to the developing endosperm in balanced and maternal excess crosses in which cellularization and starch deposition occur in endosperm, suggesting that parental genome balance influences pericarp starch relocation via cellularization and starch deposition. Loss of imprinting, or altered expression of imprinted genes and epigenetic regulators, OsFIE2 and OsMET1b were observed, implying the potential role of imprinting and epigenetic mechanisms in regulating the differential parental genome dosage effects on endosperm development.ConclusionsOur results support the hypothesis that the maternal genome dosage promotes endosperm cellularization and the paternal genome dosage delays or inhibits cellularization via contributing different sets of imprinted genes.Electronic supplementary materialThe online version of this article (doi:10.1186/s12284-016-0115-4) contains supplementary material, which is available to authorized users.

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Section: Discussionsupporting

confidence: 82%

Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Parental Genome Imbalance Causes Post-Zygotic Seed Lethality and Deregulates Imprinting in Rice

Zhang

Luo

Johnson

et al. 2016

Rice

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“…Thus, if there is a PRC2 complex regulating seed development in asterids, it probably contains the product of lineage-specific polycomb proteins and a mechanism independently evolved from Brassicaceae. In maize (Zea mays) and rice (Oryza sativa), there has been duplication of FIE (Luo et al, 2009;Li et al, 2014). Thus, the grasses may have PRC2 complexes that are divergent from the ancestral state.…”

Section: Functional Divergence In the Fis-prc2 Complexmentioning

confidence: 99%

Concerted Divergence after Gene Duplication in Polycomb Repressive Complexes

2017

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Duplicated genes are a major contributor to genome evolution and phenotypic novelty. There are multiple possible evolutionary fates of duplicated genes. Here, we provide an example of concerted divergence of simultaneously duplicated genes whose products function in the same complex. We studied POLYCOMB REPRESSIVE COMPLEX2 (PRC2) in Brassicaceae. The VERNALIZATION (VRN)-PRC2 complex contains VRN2 and SWINGER (SWN), and both genes were duplicated during a whole-genome duplication to generate FERTILIZATION INDEPENDENT SEED2 (FIS2) and MEDEA (MEA), which function in the Brassicaceae-specific FIS-PRC2 complex that regulates seed development. We examined the expression of FIS2, MEA, and their paralogs, compared their cytosine and histone methylation patterns, and analyzed the sequence evolution of the genes. We found that FIS2 and MEA have reproductive-specific expression patterns that are correlated and derived from the broadly expressed VRN2 and SWN in outgroup species. In vegetative tissues of Arabidopsis (Arabidopsis thaliana), repressive methylation marks are enriched in FIS2 and MEA, whereas active marks are associated with their paralogs. We detected comparable accelerated amino acid substitution rates in FIS2 and MEA but not in their paralogs. We also show divergence patterns of the PRC2-associated VERNALIZATION5/VIN3-LIKE2 that are similar to FIS2 and MEA. These lines of evidence indicate that FIS2 and MEA have diverged in concert, resulting in functional divergence of the PRC2 complexes in Brassicaceae. This type of concerted divergence is a previously unreported fate of duplicated genes. In addition, the Brassicaceae-specific FIS-PRC2 complex modified the regulatory pathways in female gametophyte and seed development.

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First the seed: Genomic advances in seed science for improved crop productivity and food security

Dwivedi¹,

Spillane

Lopez

et al. 2021

Crop Science

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Seeds are valuable sources of carbohydrates, lipids, proteins, fibers, minerals, and vitamins. They provide energy and nutrition to germinating seedlings, food to humans, feed to livestock and feedstocks to industry. High-throughput analyses of gene expression in crops has identified many candidate genes associated with seed dormancy, longevity, germination, and vigor. In this review, we cover the latest research focusing on such key seed traits. Transcriptome analyses of time-courses of seed filling have identified sets of genes expressed at different stages of this process. The potential role of epigenetics (including seed-endosperm imprinted genes) in regulating seed development and chemistry is highlighted herein. We also discuss how advances in genomics and seed biology are facilitating the unravelling of associations between seed traits with genebank accessions and gene sequences, including how functional research can accelerate the discovery of allelic variants. Such knowledge of functional effects relating to gene variants is necessary for more efficient and cost-effective management of genetic resources or for redesigning crops with specific seed characteristics. For instance, genebank curators may assess seed viability by monitoring changes in gene expression of biomarker genes in dry seed samples to decide germplasm regeneration and assess genetic integrity of collections by monitoring changes in This article is protected by copyright. All rights reserved. diversity and allele frequencies between samples of same accession stored in genebanks. We highlight that resistance to preharvest sprouting can be enhanced through genomicsassisted breeding in otherwise nondormant rice and wheat cultivars, while pimt, another valuable marker for seed longevity, may be deployed to enhance seed vigor in crops.

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OsFIE2 plays an essential role in the regulation of rice vegetative and reproductive development

Cited by 64 publications

References 69 publications

Parental Genome Imbalance Causes Post-Zygotic Seed Lethality and Deregulates Imprinting in Rice

Parental Genome Imbalance Causes Post-Zygotic Seed Lethality and Deregulates Imprinting in Rice

Concerted Divergence after Gene Duplication in Polycomb Repressive Complexes

First the seed: Genomic advances in seed science for improved crop productivity and food security

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