A single-nucleotide polymorphism causes smaller grain size and loss of seed shattering during African rice domestication

Wu, Weiping; Liu, Xiaoyun; Wang, Muhua; Meyer, Rachel S.; Luo, Xin; Ndjiondjop, Marie Noëlle; Tan, Lubin; Zhang, Jian Wei; Wu, Jianzhong; Cai, Hongwei; Sun, Chuanqing; Wang, Xiangkun; Wing, Rod A.; Zhu, Zuofeng

doi:10.1038/nplants.2017.64

Cited by 135 publications

(117 citation statements)

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“…A comparison of the re-acquisition of the seed dispersal mechanisms of rice and wheat may help to clarify this issue. Cultivated rice is diploid, and several seed shattering-related genes have been cloned in diverse backgrounds, including qSH1 (Konishi et al, 2006), OsCPL1 (Ji et al, 2010), SHTA1 (Zhou et al, 2012), OsSH1 (Lin et al, 2012), SH5 (Yoon et al, 2014), GL4 (Wu et al, 2017), SH3 (Lv et al, 2018) and SSH1 (Jiang et al, 2019). A complex network regulating seed shattering has gradually emerged.…”

Section: Comparison Of the De-domestications Of Rice And Wheatmentioning

confidence: 99%

Re‐acquisition of the brittle rachis trait via a transposon insertion in domestication gene Q during wheat de‐domestication

et al. 2019

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Summary De‐domestication is a unique evolutionary process during which crops re‐acquire wild‐like traits to survive and persist in agricultural fields without the need for human cultivation. The re‐acquisition of seed dispersal mechanisms is crucial for crop de‐domestication. Common wheat is an important cereal crop worldwide. Tibetan semi‐wild wheat is a potential de‐domesticated common wheat subspecies. However, the crucial genes responsible for its brittle rachis trait have not been identified. Genetic mapping, functional analyses and phylogenetic analyses were completed to identify the gene associated with Qbr.sau‐5A, which is a major locus for the brittle rachis trait of Tibetan semi‐wild wheat. The cloned Qbr.sau‐5A gene is a new Q allele (Qt) with a 161‐bp transposon insertion in exon 5. Although Qt is expressed normally, its encoded peptide lacks some key features of the APETALA2 family. The abnormal functions of Qt in developing wheat spikes result in brittle rachises. Phylogenetic and genotyping analyses confirmed that Qt originated from Q in common wheat and is naturally distributed only in Tibetan semi‐wild wheat populations. The identification of Qt provides new evidence regarding the origin of Tibetan semi‐wild wheat, and new insights into the re‐acquisition of wild traits during crop de‐domestication.

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Section: Comparison Of the De-domestications Of Rice And Wheatmentioning

confidence: 99%

Re‐acquisition of the brittle rachis trait via a transposon insertion in domestication gene Q during wheat de‐domestication

et al. 2019

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“…Meanwhile, qLGY3 encodes the MADS-domain transcription factor OsMADS1, which is associated with long and slender grains resulting from increased cell division in a longitudinal direction in the outer epidermis (Liu et al, 2018). GL4 encodes a MYB-like transcription factor and controls grain length by regulating longitudinal cell elongation in the outer and inner glumes in African rice (Wu et al, 2017). Moreover, the OsGBP1 transcription factor represses grain length while OsGBP3 enhances grain length (Gong et al, 2018).…”

Section: Introductionmentioning

confidence: 99%

The basic helix‐loop‐helix transcription factor, OsPIL15, regulates grain size via directly targeting a purine permease gene OsPUP7 in rice

et al. 2019

Plant Biotechnology Journal

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Background: Rice amylose content and amylopectin structure corporately determine rice eating and cooking qualities (ECQs). Soluble starch synthase (SS) IV-2 is a member of the soluble starch synthesis gene family but with unknown effects on ECQs. Results: In this study, three populations derived from a cross of two parents who possess the same major genes of starch bio-synthesis were employed to investigate the in uence of SSIV-2 and its combined effects with ADPglucose pyrophorylase large unit (AGPlar) and Pullulanase (PUL) on ECQs. The results illustrated that the polymorphism of SSIV-2 alleles signi cantly affected gel consistency (GC), gelatinization temperature (GT), percent of retrogradation (PR) and three crucial rapid viscosity analysis (RVA) pro le parameters: peak viscosity (PKV), breakdown viscosity (BDV) and setback viscosity (SBV). And SSIV-2 allele derived from CG173R had better quality traits with lower GT, SBV and PR. Moreover, its interaction with AGPlar was responsible for the variations of GC, apparent amylose content (AAC), GT, PR and all RVA parameters except for pasting temperature (PaT) and peak time (PeT), in terms of GC, PKV and CSV, AGPlar derived from CG173R had an epistatic effect on SSIV-2 ; additionally, interaction of SSIV-2 and PUL mainly affected GC, AAC, PKV, CPV, CSV and SBV. I-C and C-1 (I, allele of AGPlar from Guangzhan 63S; C, allele of SSIV-2 from CG173R; 1, allele of PUL from Guangzhan 63S) combinations had better ECQs. Conclusions: SSIV-2 alleles signi cantly affect rice quality, especially the parameters relevant to gelatinized and thermal characteristics of starch (GC, PR, GT, PKV, BDV and SBV) under the same major genes (Waxy and SSII-3) background. It indicates that SSIV-2 functions elongation of starch chain. These ndings suggest that the effects of SSIV-2 and its interaction with AGPlar and PUL are vital for rice quality breeding with the same major genes.

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“…Our previous studies reported that the non‐shattering characteristic resulted from the selection of different sh4 mutant alleles in domesticated of both Asian and African rice (Lin et al ., ; Wu et al ., ). In the present work we found that the transition of plant architecture from the prostrate growth of wild rice to the erect growth of cultivated rice also resulted from the same locus during Asian and African rice domestication.…”

Section: Discussionmentioning

confidence: 97%

“…Crop domestication is the process of genetic reshaping of wild species to meet human needs (Doebley et al ., ). Several morphological characteristics, such as plant architecture, seed size and dispersal, have been changed during domestication (Tan et al ., ; Lin et al ., ; Pourkheirandish et al ., ; Wu et al ., ); this has been called ‘domestication syndrome’. The identification of genes controlling domestication‐related traits will provide insight into the rules of parallel domestication of crops (Paterson et al ., ; Meyer and Purugganan, ).…”

Section: Introductionmentioning

confidence: 99%

“…For instance, loss of seed shattering was a key step during rice domestication (Konishi et al, 2006;Li et al, 2006;Lin et al, 2007). Recent studies have suggested that the non-shattering characteristic resulted from the selection of different sh4 mutant alleles during the domesticated of both Asian and African rice (Wang et al, 2014;Huang et al, 2015;Wu et al, 2017).…”

Section: Introductionmentioning

confidence: 99%

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The domestication of plant architecture in African rice

et al. 2018

The Plant Journal

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SUMMARYPlant architecture is a key agronomical factor determining crop yield and has been a major target of cereal crop domestication. The transition of plant architecture from the prostrate tiller of typical African wild rice (Oryza barthii) to the erect tiller of African cultivated rice (Oryza glaberrima) was a key step during domestication of African rice. Here we show that PROG7 (PROSTRATE GROWTH 7), a zinc-finger transcription factor gene on chromosome 7, is required for the prostrate growth of African wild rice. Mutations in the promoter region of prog7 reduced the level of gene expression in the tiller base, leading to erect growth in African cultivated rice. Sequence comparison and haplotype analysis show that 90 varieties of cultivated rice from 11 countries carry the same mutations in the prog7 region. A strong signal in a 60-kb genomic region was detected around the prog7 gene, suggesting that the region was under strong positive selection during the domestication process. Identification of the PROG7 gene provides new insights into the molecular basis of plant architecture in crops and facilitates investigation of the history of domestication of African rice.

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A single-nucleotide polymorphism causes smaller grain size and loss of seed shattering during African rice domestication

Cited by 135 publications

References 36 publications

Re‐acquisition of the brittle rachis trait via a transposon insertion in domestication gene Q during wheat de‐domestication

Re‐acquisition of the brittle rachis trait via a transposon insertion in domestication gene Q during wheat de‐domestication

The basic helix‐loop‐helix transcription factor, OsPIL15, regulates grain size via directly targeting a purine permease gene OsPUP7 in rice

The domestication of plant architecture in African rice

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