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"Biotic Stress"

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"Biotic Stress"

Article

Genetic Control of Resistance Mechanisms Toward Brown Planthopper in Rice
Afifuddin Latif Adiredjo, Iwan Kiswanto
Plant Breed. Biotech. 2025;13:1-4.
Published online February 11, 2025
DOI: https://doi.org/10.9787/PBB.2025.13.1

The genetic control of rice resistance has been extensively studied, but how the resistance mechanism is genetically controlled has received less attention. This study revealed that the rice resistance mechanism toward brown planthopper was genetically controlled by several genes with several mendelian patterns. The tolerance mechanism is controlled by three complementary genes; this is confirmed by QTL analysis, whereas the Antibiosis is controlled by three separate loci on chromosomes 2, 8, and 11. The antixenosis was controlled by polygenic, but detected locus only on chromosome 3, with minor effects.

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  • ‘Drimi9ho’, A Lodging Tolerance with Mid-late Maturing, Improved White-backed Planthopper (Sogatella furcifera) and Cultivation Stability
    Jae-Ryoung Park, Eun-Gyeong Kim, Yoon-Hee Jang, Kyung-Min Kim
    Korean Journal of Breeding Science.2025; 57(4): 493.     CrossRef
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Research Articles

Development of SNP Marker Set to Select Varieties Tolerant to Multiple Abiotic Stresses in Rice
Jung-Woo Lee, Jung-Seok Oh, Soo-Cheul Yoo
Plant Breed. Biotech. 2023;11(3):208-219.   Published online September 1, 2023
DOI: https://doi.org/10.9787/PBB.2023.11.3.208

SNP-based markers have been widely used to identify tolerant varieties harboring major genes related to abiotic stress tolerance. Here, we developed Fluidigm markers for the core set of SNPs underlying tolerance to abiotic stresses such as salinity, drought, anaerobic germination and submergence. The core set of SNPs was selected from the major genes and/or QTLs for the abiotic stresses previously reported in rice; Saltol for salinity, qDTY2.2 and qDTY4.1 for drought, OsTPP7 for anaerobic germination, and Sub1A for submergence tolerance. First, a total of 17 KASP markers were developed and converted to Fluidigm markers. The developed Fluidigm markers were applied to genotypic screening of 172 domestic and abroad varieties. The phylogenetic analysis has revealed that the majority of varieties can be largely grouped into two clusters, which correspond to domestic and foreign categories. This observation could be attributed to the fact that most tolerance genes for abiotic stresses have been inherited from indica varieties. The developed Fluidigm marker set would be used for screening genotypes tolerant to major abiotic stresses in the rice plant breeding process.

Citations

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  • Agronomic and molecular performance of rice lines carrying spikelet number and days to heading loci
    Joko Prasetiyono, Tasliah, Nafisah, Ma'sumah, Chaerani, Supriyanta, Andari Risliawati, Kurniawan Rudi Trijatmiko, Mahrup
    Crop Breeding and Applied Biotechnology.2026;[Epub]     CrossRef
  • PCR-based single nucleotide polymorphism (SNP) genotyping for crop improvement-current status and future prospects
    Jayashree Sahoo, Rukmini Mishra, Raj Kumar Joshi
    Discover Plants.2025;[Epub]     CrossRef
  • Molecular Marker Applications in the Selection of Elite Genotypes for Plant Stress Tolerance and Genetic Fidelity
    Ezgi Cabuk Sahin, Yildiz Aydin, Ahu Altinkut Uncuoglu
    OBM Genetics.2024; 08(03): 1.     CrossRef
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RNA Sequencing-Based Transcriptome Analysis in Response to Different Types and Doses of Ionizing Radiation in Rice
Jae Wan Park, Gileung Lee, Jin-Baek Kim, Hong-Il Choi
Plant Breed. Biotech. 2021;9(3):213-226.   Published online September 1, 2021
DOI: https://doi.org/10.9787/PBB.2021.9.3.213

Ionizing radiation (IR) is regarded as an abiotic stressor for plants because it causes oxidative stress and changes the expression of genes. We investigated RNA sequencing-based global transcriptome changes induced by three different types of IR (gamma rays (GR), ion beams (IB), and proton beams (PB)) at different doses in rice. On average, 489 upregulated and 234 downregulated differentially expressed genes (DEGs) were found per sample. The union of the DEGs for each IR type was collected to simplify the comparison of effects among the different IR treatments. This resulted to a total of 1,558 DEGs after GR irradiation, 1,865 DEGs after IB irradiation, and 1,347 DEGs after PB irradiation. The gene ontology (GO) enrichment analysis of the union DEG sets revealed 69 and 12 commonly enriched GO terms for up- and downregulated DEGs, respectively, many of which were closely related to oxidative stress responses. The Kyoto Encyclopedia of Genes and Genomes (KEGG) pathway mapping and enrichment analysis of the union DEG sets also showed that most of the DEGs fell into common pathways related to oxidative stress, stress signaling, and redox reactions. A total of 137 transcription factor (TF) genes were differentially expressed, and many belong to families associated with stress responses. Our results suggest that different types and doses of IR can induce universal gene expression changes in response to oxidative stress. This study contributes to our understanding of the molecular response mechanisms to IR in plants.

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  • Molecular and Functional Analysis of U-box E3 Ubiquitin Ligase Gene Family in Rice (Oryza sativa)
    Me-Sun Kim, Kwon-Kyoo Kang, Yong-Gu Cho
    International Journal of Molecular Sciences.2021; 22(21): 12088.     CrossRef
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Overexpression of S-Adenosylmethionine Synthetase Gene from Pyropia tenera Enhances Tolerance to Abiotic Stress
Hyun-Ju Hwang, Jin-Woo Han, Hyun Dae Hong, Jong Won Han
Plant Breed. Biotech. 2017;5(4):304-313.   Published online December 1, 2017
DOI: https://doi.org/10.9787/PBB.2017.5.4.304

Pyropia tenera is an intertidal red alga of commercial significance owing to its popularity as a health-promoting seafood product. This alga grows in marine environments and is frequently exposed to high salinity and osmotic stress, which impact its growth. Therefore, the enhancement of stress tolerance in P. tenera is critical. In the present work, we aimed to elucidate the mechanisms underlying abiotic stress tolerance in this species; specifically, we identified the P. tenera S-adenosylmethionine synthetase-encoding gene (PtSAMS) and characterized its biological function. This gene, which is known to play a role in stress tolerance in other plants, was cloned and overexpressed in Escherichia coli under high-salinity conditions. The PtSAMS gene was found to encode a 385-amino-acid protein with a molecular weight of 41.8 kDa. In silico sequence alignment and phylogenetic analysis of the PtSAMS amino acid sequence showed that the encoded protein comprises three conserved domains and two motifs that are highly conserved in other plants. Growth assay results indicated that PtSAMS-overexpressing E. coli cells exhibit enhanced tolerance to salt stress. The results suggest that PtSAMS expression is induced by a combination of ion toxicity and osmotic stress resulting from exposure to high salinity in marine environments, and that this gene is expressed at housekeeping levels owing to growth in such conditions. The findings suggest that PtSAMS could be used as a potentially valuable bioresource with utility in the genetic engineering of salt stress-tolerant crop plants.

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  • Gibberellin mediates spermidine-induced salt tolerance and the expression of GT-3b in cucumber
    Yu Wang, Xiaowen Gong, Weikang Liu, Lei Kong, Xinyu Si, Shirong Guo, Jin Sun
    Plant Physiology and Biochemistry.2020; 152: 147.     CrossRef
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Review Articles

Current Applicable DNA Markers for Marker Assisted Breeding in Abiotic and Biotic Stress Tolerance in Rice (Oryza sativa L.)
Franz Marielle Nogoy, Jae-Young Song, Sothea Ouk, Shadi Rahimi, Soon Wook Kwon, Kwon-Kyoo Kang, Yong-Gu Cho
Plant Breed. Biotech. 2016;4(3):271-284.   Published online August 31, 2016
DOI: https://doi.org/10.9787/PBB.2016.4.3.271

Abiotic and biotic stresses adversely affect rice (Oryza sativa L.) growth and yield. Conventional breeding is a very effective method to develop tolerant rice variety; however, it takes a decade long to establish a new rice variety. DNA-based markers have a huge potential to improve the efficiency and precision of conventional plant breeding via marker-assisted selection (MAS). The large number of quantitative trait loci (QTLs) mapping studies for rice has provided an abundance of DNA marker-trait associations. The limitations of conventional breeding such as linkage drag and lengthy time consumption can be overcome by utilizing DNA markers in plant breeding. The major applications of DNA markers such as MAS, QTL mapping and gene pyramiding have been surveyed. In this review, we presented the latest markers available for some of the most important abiotic and biotic stresses in rice breeding programs. Achieving a significant impact on crop improvement by marker assisted breeding (MAB) represents the great challenge for agricultural scientists in the next few decades.

Citations

Citations to this article as recorded by  
  • Efficiency of doubled haploid technology in mining of multiple BB resistance genes from indica rice hybrid
    Sudhansu Sekhar Bhuyan, Byomkesh Dash, Prachitara Rout, Nupur Naik, Manjusha Chandravani, Nibedita Swain, Ram Lakhan Verma, Jawahar Lal Katara, Arup Kumar Mukherjee, C. Parameswaran, BN. Devanna, Snigdha Samir Pattnaik, Sanghamitra Samantaray
    Cereal Research Communications.2025; 53(3): 1319.     CrossRef
  • The Development of Multi-Resistant Rice Restorer Lines and Hybrid Varieties by Pyramiding Resistance Genes against Blast and Brown Planthopper
    Zhao Deng, Peng Qin, Kaiyu Liu, Nan Jiang, Tianze Yan, Xuanwen Zhang, Chenjian Fu, Guangcun He, Kai Wang, Yuanzhu Yang
    Agronomy.2024; 14(5): 878.     CrossRef
  • Emerging Trends in Wheat (Triticum spp.) Breeding: Implications for the Future
    Mujahid Alam, P. Stephen Baenziger, Katherine Frels
    Frontiers in Bioscience-Elite.2024;[Epub]     CrossRef
  • Genomics and transcriptomics to protect rice (Oryza sativa. L.) from abiotic stressors: -pathways to achieving zero hunger
    Mushtaq Ahmad
    Frontiers in Plant Science.2022;[Epub]     CrossRef
  • Advances from Conventional to Modern Plant Breeding Methodologies
    Sashi Lamichhane, Sapana Thapa
    Plant Breeding and Biotechnology.2022; 10(1): 1.     CrossRef
  • Review on harnessing biotechnological tools for the development of stable bacterial wilt resistant solanaceous vegetable crops
    Shweta Sharma, Viveka Katoch, Devinder Kumar Banyal
    Scientia Horticulturae.2021; 285: 110158.     CrossRef
  • Genotyping for Blast (Pyricularia oryzae) Resistance Genes in F2 Population of Supa Aromatic Rice (Oryza sativa L.)
    L. Kanyange, J. Kamau, O. Ombori, A. Ndayiragije, M. Muthini
    International Journal of Genomics.2019; 2019: 1.     CrossRef
  • Breeding Hybrid Rice with Genes Resistant to Diseases and Insects Using Marker-Assisted Selection and Evaluation of Biological Assay
    Me-Sun Kim, Sothea Ouk, Kuk-Hyun Jung, Yoohan Song, Le Van Trang, Ju-Young Yang, Yong-Gu Cho
    Plant Breeding and Biotechnology.2019; 7(3): 272.     CrossRef
  • Insight into MAS: A Molecular Tool for Development of Stress Resistant and Quality of Rice through Gene Stacking
    Gitishree Das, Jayanta Kumar Patra, Kwang-Hyun Baek
    Frontiers in Plant Science.2017;[Epub]     CrossRef
  • Application and utilization of marker assisted selection for biotic stress resistance in hybrid rice (Oryza sativaL.)
    Jae-Young Song, Sothea Ouk, Franz Marielle Nogoy, Marjohn C. Niño, Soon Wook Kwon, Woongoo Ha, Kwon-Kyoo Kang, Yong-Gu Cho
    Journal of Plant Biotechnology.2016; 43(3): 317.     CrossRef
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Research on Biotic and Abiotic Stress Related Genes Exploration and Prediction in Brassica rapa and B. oleracea: A Review
Md. Abdul Kayum, Hoy-Taek Kim, Ujjal Kumar Nath, Jong-In Park, Kang Hee Kho, Yong-Gu Cho, Ill-Sup Nou
Plant Breed. Biotech. 2016;4(2):135-144.   Published online May 31, 2016
DOI: https://doi.org/10.9787/PBB.2016.4.2.135

Global population is increasing day-by-day, simultaneously, crop production need to increase proportionately. Whereas, increase crop production being restricted due to abiotic and biotic stresses. Abiotic stresses are adversely affected crop growth and development, leading to crop loss globally and thereby causing huge amount of economic loss as well. Contrary, pathogens are attacked the plants imposing biotic stress and severely hampers the yield. Therefore, it is prime need to understand the molecular mechanism and genes involved to minimize the biotic and abiotic stresses for mitigating the Brassica vegetable crop losses. The stress responsive, pathogens related genes are involved in tolerance or resistance to stress in plants that are cross-talk with different types of stress components in signal transduction pathways. The plants have their own mechanism to overcome biotic and abiotic stresses to follow the abscisic acid (ABA)-dependent and ABA-independent pathways. Several transcription factors such as WRKY, Alfin-like, MYB, NAC, DREB, CBF are integrating to various stress signals and controlling the gene expression through networking with their related cis-elements. To develop stress tolerance and/or resistant crops plants, there is need to realize both of the plant and pathogenic disease development mechanisms. Therefore, this article is focused on (i) major and devastating stresses on vegetable crops, (ii) role of genes to overcome the stresses, and (iii) differential genes expressed under biotic and abiotic stresses in Brassica oleracea and B. rapa for getting insight of the mechanisms of development of resistance lines.

Citations

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  • Biochar Enhances Nutrient Uptake, Yield, and NHX Gene Expression in Chinese Cabbage Under Salinity Stress
    Periyasamy Rathinapriya, Theivanayagam Maharajan, Tae-Jun Lim, Byeongeun Kang, Seung Tak Jeong
    Plants.2025; 14(17): 2743.     CrossRef
  • Implication of ribosomal protein in abiotic and biotic stress
    Zainab Fakih, Hugo Germain
    Planta.2025;[Epub]     CrossRef
  • CRISPR/Cas9: efficient and emerging scope for Brassica crop improvement
    Shiv Shankar Sharma, Ashwani Pandey, Anamika Kashyap, Lakshay Goyal, Pooja Garg, Ranjeet Kushwaha, Jyoti Sharma, Shikha Tripathi, Sujata Kumari, George Thomas, Malkhey Verma, Navin C. Gupta, Ashish Kumar Gupta, Ramcharan Bhattacharya, Sandhya Sharma, Mahe
    Planta.2025;[Epub]     CrossRef
  • Rewilding agriculture: utilising wild relatives to enhance legume crop traits
    Vinay T. K., B. K. Savitha, C. Indu Rani, M. Suganthy, G. Ashokkumar, Jothimani P.
    New Zealand Journal of Crop and Horticultural Science.2025; 53(5): 1362.     CrossRef
  • Variances in physiological parameters associated with stress tolerance between seven Brassica oleracea varieties
    Dino Davosir, Ivana Šola, Jutta Ludwig-Müller
    Frontiers in Plant Science.2025;[Epub]     CrossRef
  • Genome-Wide Identification of GYF-Domain Encoding Genes in Three Brassica Species and Their Expression Responding to Sclerotinia sclerotiorum in Brassica napus
    Xiaobo Zhang, Lei Qin, Junxing Lu, Yunong Xia, Xianyu Tang, Xun Lu, Shitou Xia
    Genes.2023; 14(1): 224.     CrossRef
  • Plant hormone crosstalk mediated by humic acids
    Aline Costa Souza, Fábio Lopes Olivares, Lázaro Eustáquio Pereira Peres, Alessandro Piccolo, Luciano Pasqualoto Canellas
    Chemical and Biological Technologies in Agriculture.2022;[Epub]     CrossRef
  • A novel thaumatin-like protein from durum wheat, TdPR-5, is homologous to known plant allergens, responsive to stress exposure, and confers multiple-abiotic stress tolerances to transgenic yeast
    Rania Djemal, Ons Bahloul, Habib Khoudi
    Plant Gene.2022; 31: 100360.     CrossRef
  • Evidence that miR168a contributes to salinity tolerance of Brassica rapa L. via mediating melatonin biosynthesis
    Roohollah Shamloo‐Dashtpagerdi, Angelica Lindlöf, Sirous Tahmasebi
    Physiologia Plantarum.2022;[Epub]     CrossRef
  • Genome-Wide Identification, Evolution, and Comparative Analysis of B-Box Genes in Brassica rapa, B. oleracea, and B. napus and Their Expression Profiling in B. rapa in Response to Multiple Hormones and Abiotic Stresses
    Sonam Singh, Sushil Satish Chhapekar, Yinbo Ma, Jana Jeevan Rameneni, Sang Heon Oh, Jusang Kim, Yong Pyo Lim, Su Ryun Choi
    International Journal of Molecular Sciences.2021; 22(19): 10367.     CrossRef
  • Effects of Short-Term Root Cooling before Harvest on Yield and Food Quality of Chinese Broccoli (Brassica oleracea var. Alboglabra Bailey)
    Fang He, Björn Thiele, David Kraus, Souhaila Bouteyine, Michelle Watt, Thorsten Kraska, Ulrich Schurr, Arnd Jürgen Kuhn
    Agronomy.2021; 11(3): 577.     CrossRef
  • Confirmation of Radish Isolate of Turnip mosaic virus in India Through Biological and Serological Evidences
    Shelly Kapoor, Anil Handa, John A. Walsh, Rajnish Sharma
    Plant Pathology Journal.2020; 19(4): 211.     CrossRef
  • Role of Major Glucosinolates in the Defense of Kale Against Sclerotinia sclerotiorum and Xanthomonas campestris pv. campestris
    Pari Madloo, Margarita Lema, Marta Francisco, Pilar Soengas
    Phytopathology®.2019; 109(7): 1246.     CrossRef
  • The interplay between miR156/SPL13 and DFR/WD40–1 regulate drought tolerance in alfalfa
    Biruk A. Feyissa, Muhammad Arshad, Margaret Y. Gruber, Susanne E. Kohalmi, Abdelali Hannoufa
    BMC Plant Biology.2019;[Epub]     CrossRef
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    Rout George Kerry, Gyana Prakash Mahapatra, Sushmita Patra, Santi Lata Sahoo, Chinmay Pradhan, Bijaya Kumar Padhi, Jyoti Ranjan Rout
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    Rajesh Kumar Pathak, Mamta Baunthiyal, Dinesh Pandey, Anil Kumar
    3 Biotech.2018;[Epub]     CrossRef
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Global Trends in Plant Genomics Research to Improve Crop Productivity at PAG XXIV Conference
Shadi Rahimi, Kwon-Kyoo Kang, Yong-Gu Cho
Plant Breed. Biotech. 2016;4(1):1-15.   Published online February 28, 2016
DOI: https://doi.org/10.9787/PBB.2016.4.1.1

Increasing demand for food commodities and energy supply highlight the necessity to further improve crop productivity. At the Plant and Animal Genome Conference (PAG XXIV), recent developments and future plans for genomics research of plants and animals were presented. PAG XXIV provided a forum to explore crop genomes with the aim of providing new opportunities for crop breeding and the foundation for functional genomic studies to improve agriculture production and help feed the growing population. Genetic diversity and population structure studies of crops have allowed us to explore alleles related to different characteristics important for plant breeding. Several useful databases were introduced in PAG XXIV. They were developed to integrate a growing set of commonly used data types and analysis tools with new capabilities for visualization, exploration, and predictive analysis. This review highlights the global trends in plant genomics presented at PAG XXIV by focusing on crop productivity.

Citations

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  • Drought-Tolerant Biotech Soybean Breeding in South America: Current Status, Commercialization, and Implications for Korea’s Technology Export Strategy
    Seung Young Choi, Yong Hun Song, Seung Muk Won, Kyeong Hee Lee, Ga Ram Kim, Taeyoung Um
    Korean Journal of Breeding Science.2026; 58(1): 13.     CrossRef
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Research Articles
Development of Resistant Gene-Pyramided Japonica Rice for Multiple Biotic Stresses Using Molecular Marker-Assisted Selection
Jung-Pil Suh, Young-Chan Cho, Yong-Jae Won, Eok-Keun Ahn, Man-Kee Baek, Myeong-Ki Kim, Bo-Kyeong Kim, Kshirod K. Jena
Plant Breed. Biotech. 2015;3(4):333-345.   Published online November 30, 2015
DOI: https://doi.org/10.9787/PBB.2015.3.4.333

Advances in plant molecular techniques have dramatically widened the applicability of gene identification and pyramiding valuable genes. This study was carried out to pyramid five resistance genes for biotic stress into the japonica rice cultivar using marker-assisted selection (MAS) and marker-assisted background analysis of selected progenies using SSR markers. The Pi40, Xa4, xa5, Xa21 and Bph18 genes were combined in Jinbubyeo, a Korean japonica rice variety using MAS. Gene specific co-dominant PCR-based markers were used to select for homozygous recombinant lines in a segregating population derived from a cross between the parental homozygous resistant gene introgression lines. We had successfully developed multiple gene pyramided breeding lines (GPLs) for bacterial blight, blast, and brown planthopper using MAS in rice. The GPLs exhibited high resistance against biotic stress and had around 93% of the genetic background of the recurrent parent Jinbubyeo based on SSR graphical mapping. The yield and agronomic traits of the GPLs were similar to those of the recurrent parent, indicating that there is no apparent agronomic trait penalty associated with the presence of the resistance genes. The strategy of simultaneous foreground and phenotypic selection to introduce multiple R genes is very useful to reduce the cost and the time required for the isolation of desirable recombinants with target resistance genes in rice. The GPLs could be useful to enhance effective resistance for biotic stress and produce stable grain yield in japonica rice breeding programs.

Citations

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  • Genetic Dissection of Resistance to Pseudomonas amygdali pv. tabaci in Soybean [Glycine max (L.) Merr.] by Linkage Analysis
    Seo Yoon Yang, In-Jeong Kang, Ji-Min Kim, Sungtaeg Kang, Sungwoo Lee
    The Plant Pathology Journal.2026; 42(2): 207.     CrossRef
  • Grain quality characterization of indigenous rice (Oryza sativa L.) landraces using mixed clustering and selection index approaches
    A. K. Jukanti, S. Rathod, C. N. Neeraja, S. Gopala Krishnan, D. Aleena, G. Mahesh, G. Prasanna, R. M. Sundaram
    Discover Food.2025;[Epub]     CrossRef
  • Genomic Confirmation of Resistance Genes for Blast, Bacterial Leaf Blight, Rice Tungro Spherical Virus, and Brown Planthopper in Tropically Adapted Temperate Japonica Rice Varieties
    Myrish Alvarez Pacleb, Seongkyeong Lee, Sherry Lou Hechanova, Thelma Padolina, Lenie Pautin, Jesson Del-Amen, Dong-Soo Park, Il-Ryong Choi, Sung-Ryul Kim, Dongjin Shin, Jung-Pil Suh
    Agronomy.2025; 15(11): 2585.     CrossRef
  • Superior haplotypes towards the development of blast and bacterial blight-resistant rice
    Shamshad Alam, Krishna Tesman Sundaram, Uma Maheshwar Singh, Madamshetty Srinivas Prasad, Gouri Sankar Laha, Pallavi Sinha, Vikas Kumar Singh
    Frontiers in Plant Science.2024;[Epub]     CrossRef
  • Toward Food Security in 2050: Gene Pyramiding for Climate-Smart Rice
    Isnaini Isnaini, Yudhistira Nugraha, Niranjan Baisakh, Nono Carsono
    Sustainability.2023; 15(19): 14253.     CrossRef
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    Ayumi Agata, Motoyuki Ashikari, Yutaka Sato, Hidemi Kitano, Tokunori Hobo
    Breeding Science.2023; 73(1): 86.     CrossRef
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    Yilong Yao, Denghao Xiang, Nai Wu, Yao Wang, Yu Chen, Yang Yuan, Ying Ye, Dan Hu, Chang Zheng, Yu Yan, Qingya Lv, Xiaokai Li, Guoxing Chen, Honghong Hu, Haiyan Xiong, Shaobing Peng, Lizhong Xiong
    Molecular Plant.2023; 16(12): 1911.     CrossRef
  • Drought stress in rice: morpho-physiological and molecular responses and marker-assisted breeding
    Muhammad A. Hassan, Ni Dahu, Tong Hongning, Zhu Qian, Yi Yueming, Li Yiru, Wang Shimei
    Frontiers in Plant Science.2023;[Epub]     CrossRef
  • Genetic Improvement of Rice for Bacterial Blight Resistance: Present Status and Future Prospects
    R. Abdul Fiyaz, D. Shivani, K. Chaithanya, K. Mounika, M. Chiranjeevi, G.S. Laha, B.C. Viraktamath, L.V. Subba Rao, R.M. Sundaram
    Rice Science.2022; 29(2): 118.     CrossRef
  • Pyramiding of Four Broad Spectrum Bacterial Blight Resistance Genes in Cross Breeds of Basmati Rice
    Irfan Ullah, Hamid Ali, Tariq Mahmood, Mudassar Nawaz Khan, Muhammad Haris, Hussain Shah, Adil Mihoub, Aftab Jamal, Muhammad Farhan Saeed, Roberto Mancinelli, Emanuele Radicetti
    Plants.2022; 12(1): 46.     CrossRef
  • Molecular Breeding of Water-Saving and Drought-Resistant Rice for Blast and Bacterial Blight Resistance
    Anning Zhang, Yi Liu, Feiming Wang, Deyan Kong, Junguo Bi, Fenyun Zhang, Xingxing Luo, Jiahong Wang, Guolan Liu, Lijun Luo, Xinqiao Yu
    Plants.2022; 11(19): 2641.     CrossRef
  • A quantitative genomics map of rice provides genetic insights and guides breeding
    Xin Wei, Jie Qiu, Kaicheng Yong, Jiongjiong Fan, Qi Zhang, Hua Hua, Jie Liu, Qin Wang, Kenneth M. Olsen, Bin Han, Xuehui Huang
    Nature Genetics.2021; 53(2): 243.     CrossRef
  • Identification of QTL Combinations that Cause Spikelet Sterility in Rice Derived from Interspecific Crosses
    Chang-Min Lee, Jung-Pil Suh, Hyun-Su Park, Man-Kee Baek, O-Young Jeong, Song-Joong Yun, Young-Chan Cho, Suk-Man Kim
    Rice.2021;[Epub]     CrossRef
  • Mapping novel QTLs for yield related traits from a popular rice hybrid KRH-2 derived doubled haploid (DH) population
    Swapnil Ravindra Kulkarni, S. M. Balachandran, K. Ulaganathan, Divya Balakrishnan, A. S. Hari Prasad, G. Rekha, M. B. V. N. Kousik, S. K. Hajira, Ravindra Ramarao Kale, D. Aleena, M. Anila, E. Punniakoti, T. Dilip, K. Pranathi, M. Ayyappa Das, Mastanbee S
    3 Biotech.2021;[Epub]     CrossRef
  • Recent Advances in Rice Varietal Development for Durable Resistance to Biotic and Abiotic Stresses through Marker-Assisted Gene Pyramiding
    Md Azadul Haque, Mohd Y. Rafii, Martini Mohammad Yusoff, Nusaibah Syd Ali, Oladosu Yusuff, Debi Rani Datta, Mohammad Anisuzzaman, Mohammad Ferdous Ikbal
    Sustainability.2021; 13(19): 10806.     CrossRef
  • Effect of Resistance Genes on the Occurrence of Rice Undesirable Characters in a Wide Cross
    Chang-Min Lee, Hyun-Su Park, Man-Kee Baek, Jung-Pil Suh, O-Young Jeong, Song-Joong Yun, Suk-Man Kim
    Korean Journal of Breeding Science.2021; 53(4): 392.     CrossRef
  • Molecular mapping of QTLs for yield related traits in recombinant inbred line (RIL) population derived from the popular rice hybrid KRH-2 and their validation through SNP genotyping
    Swapnil Ravindra Kulkarni, S. M. Balachandran, K. Ulaganathan, Divya Balakrishnan, M. Praveen, A. S. Hari Prasad, R. A. Fiyaz, P. Senguttuvel, Pragya Sinha, Ravindra R. Kale, G. Rekha, M. B. V. N. Kousik, G. Harika, M. Anila, E. Punniakoti, T. Dilip, S. K
    Scientific Reports.2020;[Epub]     CrossRef
  • Impact of Marker Assisted Breeding for Bacterial Blight Resistance in Rice: A Review
    Hari Kesh, Prashant Kaushik
    Plant Pathology Journal.2020; 19(2): 151.     CrossRef
  • Characterization and application of a gall midge resistance gene (Gm6) from Oryza sativa ‘Kangwenqingzhan’
    Yang Li, Yi Mo, Zhihua Li, Meng Yang, Lihua Tang, Ling Cheng, Yongfu Qiu
    Theoretical and Applied Genetics.2020; 133(2): 579.     CrossRef
  • Marker Assisted Forward Breeding to Combine Multiple Biotic-Abiotic Stress Resistance/Tolerance in Rice
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Overexpression of Oshsp16.9 Gene Encoding Small Heat Shock Protein Enhances Tolerance to Abiotic Stresses in Rice
Yu Jin Jung, Ill Sup Nou, Kwon Kyoo Kang
Plant Breed. Biotech. 2014;2(4):370-379.   Published online December 31, 2014
DOI: https://doi.org/10.9787/PBB.2014.2.4.370

Plants have adapted the ability to respond to various abiotic stresses such as high salinity, osmotic stress, high and low temperatures, and drought in order to survive. Small heat shock proteins (sHsps) play important and extensive roles in plant defenses against abiotic stresses. Herein, we cloned an sHsp gene from the rice, which we named Oshsp16.9 based on the molecular weight of the protein. Real-time PCR analysis showed that expression of the Oshsp16.9 gene was rapidly and strongly induced by stresses including high-salinity (250 mM NaCl), osmotic stress (300 mM mannitol), 100 μM ABA, cold (4°C) and heat (45°C). Subcellular localization assay indicated that Oshsp16.9 was localized specifically in the cytoplasm. In addition, overexpression of Oshsp16.9 in rice conferred tolerance of transgenic plants to salt and drought stress. Taken together, these results suggest that the Oshsp16.9 gene is an important determinant of stress response in plants.

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Transgenic Tomato Plants Ectopically Expressing BrRZFP1 Gene Encoding C3HC4-type RING Zinc Finger Protein
Yu-Jin Jung, Yong Gu Cho, Ill Sup Nou, Kwon Kyoo Kang
Plant Breed. Biotech. 2014;2(1):25-34.   Published online March 31, 2014
DOI: https://doi.org/10.9787/PBB.2014.2.1.025

C3HC4-type RING zinc finger proteins are known to be essential in the regulation of plant processes, including responses to abiotic stress. In order to explore the potential of the BrRZFP1 gene to enhance tolerance toward multiple stresses in different host plant genomes, we generated transgenic tomato (Solanum lycopersicum L. cv. Goldenbell) plants. The tomato plants overexpressing BrRZFP1 acquired a higher tolerance to drought stress. However, the transgenic plants did not appear to be more cold tolerant than the WT, in any tested condition. The data obtained indicate that the specificity and the degree of BrRZFP1 activity depend on the host genomic background. In physiological assessment of salt stress tolerance, transgenic plants showed more dry matter accumulation and maintained significantly higher levels of leaf chlorophyll content along with increasing levels of salt stress than the wild type plants. This study shows that BrRZFP1 is a candidate gene in the engineering of crops for enhanced drought and salt stress tolerance.

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Development and Identification of Transgenic Rice Lines with Abiotic Stress Tolerance by using a Full-length Overexpressor Gene Hunting System
Sailila E. Abdula, Hye Jung Lee, Moo Geun Jee, Yu Jin Jung, Kwon Kyoo Kang, Ill Sup Nou, Sang-Bok Lee, Won-Ha Yang, Yong-Gu Cho
Plant Breed. Biotech. 2013;1(1):33-48.   Published online March 31, 2013
DOI: https://doi.org/10.9787/PBB.2013.1.1.033

The latest report on the draft genome of Brassica rapa sequence has been published. To elucidate the functions of these genes and to efficiently search for agriculturally useful genes, a Full-length cDNA Over-eXpressor (FOX) gene hunting system was used. The FOX library from Chinese cabbage was introduced into rice via Agrobacterium-mediated transformation. Approximately 1,150 FOX-rice lines were generated. Genomic PCR analysis indicated that the average length of FL-cDNAs introduced into individual lines was 900~1,200 bp. Basic Local Alignment System Tool (BLAST) analysis of the FL-cDNA genes revealed that 35.5% have unknown function. Most of the randomly selected transgenic rice lines showed overexpression (92%) of these genes relative to the wild-type Gopum. Moreover, 94% of the 850 transgenic rice lines were moderately tolerant (slightly yellow) to cold and 9 lines were tolerant (seedlings were light green). Morphological evaluation of the transgenic rice lines showed minimal phenotypic alteration (12%). Approximately 25.1% and 22% of the plants were significantly ahead in the days to heading and had elevated chlorophyll content, respectively. Other agronomic traits such as filled grains, number of tiller, panicle length, and culm and plant height were relatively less variable among the transgenic lines. These results provide a resource for defining genes that are associated with tolerance in transgenic rice lines.

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