DNA methylation repatterning accompanying hybridization, whole genome doubling and homoeolog exchange in nascent segmental rice allotetraploids

Li, Ning; Xu, Chunming; Zhang, Ai; Lv, Ruili; Meng, Xiangying; Lin, Xiuyun; Gong, Lei; Wendel, Jonathan F.; B, Liu

doi:10.1111/nph.15820

Cited by 61 publications

(66 citation statements)

References 108 publications

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“…For example, half of the MIXTAs, 40% of the CESAs, and 34% of CSL genes were highly expressed during fiber development of cultivated tetraploid cotton compared with wild species [13]. Polyploidy and domestication are associated with some epigenetic modifications (e.g., DNA methylation, miRNA, and siRNA biogenesis), which facilitate the increased transcripts of some key genes in fiber development [33][34][35]. The enrichment and high expression of fiber-related genes might contribute synergistically to fiber development.…”

Section: Genomic Basis Of Fibermentioning

confidence: 99%

Gossypium Genomics: Trends, Scope, and Utilization for Cotton Improvement

Yang

Qanmber

Wang

et al. 2020

Trends in Plant Science

110

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Cotton (Gossypium spp.) is the most important natural fiber crop worldwide. The diversity of Gossypium species also provides an ideal model for investigating evolution and domestication of polyploids. However, the huge and complex cotton genome hinders genomic research. Technical advances in high-throughput sequencing and bioinformatics analysis have now largely overcome these obstacles, bringing about a new era of cotton genomics. Here, we review recent progress in Gossypium genomics based on whole genome sequencing, resequencing, and comparative genomics, which have provided insights about the genomic basis of fiber biogenesis and the landscape of cotton functional genomics. We address current challenges and present multidisciplinary genomics-enabled breeding strategies covering the breadth of high fiber yield, quality, and environmental resilience for future cotton breeding programs. Gossypium Genomics at a Glance As the world's most important fiber crop and a major source of seed oil and protein, cotton is cultivated in more than 75 countries around the globe [1]. Cotton fibers are seed trichomes, up to 65 mm long, composed of almost pure cellulose, and provide a unique single-celled model system for studying cell elongation and cell wall biogenesis [2]. The Gossypium genus is extraordinarily diverse, with eight diploid genome groups (A-G, and K) and one allopolyploid group (AD) [3,4]. Hybridization and polyploidization of two parental diploids, an A genome-like species with a D genome-like species, has resulted in at least seven allotetraploid species. Two allotetraploid species, Gossypium hirsutum and Gossypium barbadense, evolved independently; these two account for over 90% of annual commercial fiber production. Gossypium is ideal for investigating the origin, evolution, and domestication of polyploids [5-7]. Highlights Cotton is an important natural fiber crop cultivated worldwide that also provides an ideal model for investigating evolution and domestication of polyploids Combinations of the latest technologies, such as optical mapping, high-throughput chromosome conformation capture (Hi-C), and Pacific Biosciences (PacBio) long-reads, have been used to generate multiple high-quality reference genomes of diploid and allotetraploid cotton. Comparative population genomics illuminated the genetic history of cotton domestication and identified the genomic variation determining fiber yield, quality, and stress resistance.

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Section: Genomic Basis Of Fibermentioning

confidence: 99%

Gossypium Genomics: Trends, Scope, and Utilization for Cotton Improvement

Yang

Qanmber

Wang

et al. 2020

Trends in Plant Science

110

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“…Without directly altering the underlying DNA sequence, epigenetic signals such as histone modifications, DNA methylation and RNA interference (RNAi) can be specific to particular internal or external conditions and they can have phenotypic implications (e.g. Alonso et al , 2019b; Ding et al , 2019; Gehring, 2019; Li et al , 2019; Zhao et al , 2019). Epigenetics was first addressed in New Phytologist in 2003 in the context of genomic changes after whole genome doubling (Soltis et al , 2003).…”

Section: Figmentioning

confidence: 99%

“…Given their prevalence, disentangling the effects of hybridization and polyploidy from one another promises to improve our knowledge about plant genome evolution. Li et al (2019) report a large‐scale methylome stability across several rice accessions, including diploid parents, diploid F 1 hybrids and allotetraploids. However, they observed in the allopolyploids considerable but regional re‐patterning in the DNA methylation landscape that was missing in the diploid hybrid genomes, indicating that in this system hybridity can exacerbate, only in combination with polyploidy, a rewiring of epigenetic and gene expression landscape.…”

Section: Epigenetic Relevance Of Hybridization and Whole Genome Doublingmentioning

confidence: 99%

Current research frontiers in plant epigenetics: an introduction to a Virtual Issue

et al. 2020

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“…Given that gene expression level dominance occurs instantly following the initial hybridization event (15) , resynthesized allopolyploids are the ideal system to investigate the establishment and escalation of subgenome dominance. Few studies have used multiple independently derived resynthesized allopolyploids to investigate the variability of subgenome dominance (21)(22)(23)(24)(25)(26) . Thus it remains unclear the extent to which the emergence of subgenome dominance is a result of pre-existing characteristics of the diploid progenitors or due to independent and non-recurrent events during polyploid formation.…”

Section: Introductionmentioning

confidence: 99%

Replaying the evolutionary tape to investigate subgenome dominance in allopolyploid Brassica napus

Bird

Niederhuth

et al. 2019

Preprint

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One of the parental diploid genomes (subgenomes) in an allopolyploid often exhibits higher gene expression levels compared to the other subgenome(s) in the nucleus. However, the genetic basis and deterministic fate of subgenome expression dominance remains poorly understood. We examined the establishment of subgenome expression dominance in six isogenic resynthesized Brassica napus (rapeseed) allopolyploid lines over the first ten generations, and uncovered consistent expression dominance patterns that were biased towards the Brassica oleracea 'C' subgenome across each of the independent lines and generations. The number and direction of gene dosage changes from homoeologous exchanges (HEs) was highly variable between lines and generations, however, we recovered HE hotspots overlapping with those in multiple natural B. napus cultivars. Additionally, we found a greater number of 'C' subgenome regions replacing 'A' subgenome regions among resynthesized lines with rapid reduction in pollen counts and viability. Furthermore, DNA methylation differences between subgenomes mirrored the observed gene expression bias towards the 'C' subgenome in all lines and generations. Gene-interaction network analysis indicated an enrichment for network interactions and several biological functions for 'C' subgenome biased pairs, but no enrichment was observed for 'A' subgenome biased pairs. These findings demonstrate that "replaying the evolutionary tape" in allopolyploids results in repeatable and predictable subgenome expression dominance patterns based on preexisting genetic differences among the parental species.

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DNA methylation repatterning accompanying hybridization, whole genome doubling and homoeolog exchange in nascent segmental rice allotetraploids

Cited by 61 publications

References 108 publications

Gossypium Genomics: Trends, Scope, and Utilization for Cotton Improvement

Gossypium Genomics: Trends, Scope, and Utilization for Cotton Improvement

Current research frontiers in plant epigenetics: an introduction to a Virtual Issue

Replaying the evolutionary tape to investigate subgenome dominance in allopolyploid Brassica napus

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