Development and evaluation of near-isogenic lines for brown planthopper resistance in rice cv. 9311

Xiao, Cong; Hu, Jie; Ao, Yiting; Cheng, Ming Huei; Gao, Guanjun; Zhang, Qinglu; He, Guangming; He, Yuqing

doi:10.1038/srep38159

Cited by 32 publications

(24 citation statements)

References 38 publications

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“…Many cloned genes with disease resistance have been widely applied to the breeding and improvement of new GSR varieties (Jiang et al 2016;Hu et al 2016Hu et al , 2017. These included introduction of Pi2 (blast resistance gene) and Xa23 (bacterial blight resistance gene) into the photo-thermo-sensitive genic male sterile (PTGMS) line Guangzhan63-4S, which significantly enhanced the resistance of newly developed two-line hybrid breeding lines to bacterial blight and blast (Jiang et al 2015a QBph3,QBph4,Bph6,Bph3,Bph9,Bph10,Bph14,Bph15,Bph17,Bph18,Bph20,Bph21,and Bph24) were developed, which showed stronger brown planthopper resistance at the seedling stage (Xiao et al 2016). Recently, a novel gene, Bph38(t) on the long arm of chromosome 1, was mapped to a small genomic region of 496.2 kb explaining the phenotypic variation of 35.9% in a backcross population derived from a cross of HHZ and Khazar (Balachiranjeevi et al 2019).…”

Section: Green Genes For the Breeding Of New Gsr Varietiesmentioning

confidence: 99%

“…2). As a result, a large number of restorer lines, male sterile lines, and new pre-breeding lines with the advantages of disease/insect resistance, weed-competitive ability, high nitrogen-and phosphorususe efficiency, water-saving, drought tolerance, and high yield and quality were bred (Jiang et al 2015b(Jiang et al , 2016Xiao et al 2016;Wang et al 2016;Dimaano et al 2017). Meanwhile, these lines were screened and identified for their resistance to drought, low phosphorus, low nitrogen, weed-competitive ability, blast, bacterial blight, rice false smut, and rice planthopper, creating a batch of new germplasm with multiple green traits such as multi-resistance, high nutrient-use efficiency, water-saving, drought tolerance, and high yield and quality.…”

Section: Development Of New Pre-breeding Gsr Lines With Pyramided Grementioning

confidence: 99%

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Genomic Breeding of Green Super Rice Varieties and Their Deployment in Asia and Africa

Ali

Zhang

et al. 2020

Theor Appl Genet

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Key message The "Green Super Rice" (GSR) project aims to fundamentally transform crop production techniques and promote the development of green agriculture based on functional genomics and breeding of GSR varieties by whole-genome breeding platforms. Abstract Rice (Oryza sativa L.) is one of the leading food crops of the world, and the safe production of rice plays a central role in ensuring food security. However, the conflicts between rice production and environmental resources are becoming increasingly acute. For this reason, scientists in China have proposed the concept of Green Super Rice for promoting resource-saving and environment-friendly rice production, while still achieving a yield increase and quality improvement. GSR is becoming one of the major goals for agricultural research and crop improvement worldwide, which aims to mine and use vital genes associated with superior agronomic traits such as high yield, good quality, nutrient efficiency, and resistance against insects and stresses; establish genomic breeding platforms to breed and apply GSR; and set up resource-saving and environment-friendly cultivation management systems. GSR has been introduced into eight African and eight Asian countries and has contributed significantly to rice cultivation and food security in these countries. This article mainly describes the GSR concept and recent research progress, as well as the significant achievements in GSR breeding and its application.

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Section: Green Genes For the Breeding Of New Gsr Varietiesmentioning

confidence: 99%

Section: Development Of New Pre-breeding Gsr Lines With Pyramided Grementioning

confidence: 99%

Genomic Breeding of Green Super Rice Varieties and Their Deployment in Asia and Africa

Ali

Zhang

et al. 2020

Theor Appl Genet

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“…Some secondary metabolites, such as flavanoids, were found different in resistant and susceptible rice varieties, and can inhibit the feeding behavior of N. lugens at concentrations high enough ( Grayer et al 1994 , Stevenson et al 1996 ). N. lugens feeding on the resistant variety RHT generally ingested lower quantity of phloem sap, which indicated that the N. lugens was in nutritional deficiency states ( Ghaffar et al 2011 , Peñalver et al 2011 , Xiao et al 2016 ). Third, the endosymbionts are suggested to have evolved to complement the amino acids needs of their host, so that N. lugens can survive on a nutritionally imbalanced food source ( Chen et al 2011 , Xue et al 2014 ).…”

Section: Discussionmentioning

confidence: 99%

Expression and RNA Interference of Ribosomal Protein L5 Gene in Nilaparvata lugens (Hemiptera: Delphacidae)

Zhu¹,

Hao²,

Lu³

et al. 2017

Journal of Insect Science

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The ribosomal proteins play important roles in the growth and development of organisms. This study aimed to explore the function of NlRPL5 (GenBank KX379234), a ribosomal protein L5 gene, in the brown planthopper Nilaparvata lugens. The open reading frame of NlRPL5 was cloned from N. lugens based on a previous transcriptome analysis. The results revealed that the open reading frame of NlRPL5 is of 900 bp, encoding 299 amino acid residues. The reverse transcription quantitative PCR results suggested that the expression of NlRPL5 gene was stronger in gravid females, but was relatively low in nymphs, males, and newly emerged females. The expression level of NlRPL5 in the ovary was about twofolds of that in the head, thorax, or fat body. RNAi of dsNlRPL5 resulted in a significant reduction of mRNA levels, ∼50% decrease in comparison with the dsGFP control at day 6. Treatment of dsNlRPL5 significantly restricted the ovarian development, and decreased the number of eggs laid on the rice (Oryza sativa) plants. This study provided a new clue for further study on the function and regulation mechanism of NlRPL5 in N. lugens.

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“…To date, MAS has been successfully utilized to breed plants with major BPH, GM, WBPH, and GRH resistance genes. A series of near-isogenic lines (NILs) with a single BPH resistance gene/QTL, including BPH3, bph4, BPH6, BPH9, BPH10, BPH14, BPH15, BPH17, BPH18, BPH20, BPH21, BPH24, BPH26, BPH32, qBPH3, and qBPH4, were developed in the background of the susceptible cultivar 9311 and IR24, respectively (Qiu et al 2010;Xiao et al 2016;. Furthermore, the NILs with a single GM (GM4, GM11), WBPH (Ovc, qOVA-1-3, qOVA-4, qOVA-5-1, and qOVA-5-2), and GRH (GRH1, GRH2, GRH4, GRH5, GRH6, and qGRH4) resistance genes were also developed (Yamasaki et al 2003;Fujita et al 2010b;Himabindu et al 2010;Divya et al 2015).…”

Section: Marker-assisted Selectionmentioning

confidence: 99%

Current understanding of the genomic, genetic, and molecular control of insect resistance in rice

Chen

Guo

et al. 2020

Mol Breeding

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Rice (Oryza sativa) is both a vital source of food and a key model cereal for genomic research. Insect pests are major factors constraining rice production. Here, we provide an overview of recent progress in functional genomics research and the genetic improvements of insect resistance in rice. To date, many insect resistance genes have been identified in rice, and 14 such genes have been cloned via a map-based cloning approach. The proteins encoded by these genes perceive the effectors of insect and activate the defense pathways, including the expression of defense-related genes, including mitogen-activated protein kinase, plant hormone, and transcription factors; and defense mechanism against insects, including callose deposition, trypsin proteinase inhibitors (TryPIs), secondary metabolites, and green leaf volatiles (GLVs). These ongoing functional genomic studies provide insights into the molecular basis of rice-insect interactions and facilitate the development of novel insect-resistant rice varieties, improving long-term control of insect pests in this crucial crop.

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Development and evaluation of near-isogenic lines for brown planthopper resistance in rice cv. 9311

Cited by 32 publications

References 38 publications

Genomic Breeding of Green Super Rice Varieties and Their Deployment in Asia and Africa

Genomic Breeding of Green Super Rice Varieties and Their Deployment in Asia and Africa

Expression and RNA Interference of Ribosomal Protein L5 Gene in Nilaparvata lugens (Hemiptera: Delphacidae)

Current understanding of the genomic, genetic, and molecular control of insect resistance in rice

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