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"Disease resistance"

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"Disease resistance"

Research Articles

Development of EMS Mutagenized Wheat Mutant Lines Resistant to Fusarium Crown Rot and Fusarium Head Blight
Kahsay Tadesse Mawcha, Dennis Ndolo, Wenxiang Yang, Olubukola Oluranti Babalola
Plant Breed. Biotech. 2024;12:98-121.   Published online September 13, 2024
DOI: https://doi.org/10.9787/PBB.2024.12.98

Plant breeding relies on genetic variation to produce new and improved cultivars. One way to obtain novel traits is by inducing mutations. The present study aimed to create a Fusarium crown rot (FCR) and Fusarium head blight (FHB)-resistant mutagenized wheat population using ethyl methane sulphonate (EMS) and identify mutant resistance to FCR and FHB, which could provide a starting point for resistance breeding. The optimal mutagenesis conditions were determined based on the germination percentage. This study used six Chinese wheat cultivars, namely Jimai22, Hengguan35, Shixin828, Gaoyou2018, Keiwei20, and Keiwei18, to create a mutant population by treating them with EMS. For Shixin828, the optimal condition was 0.8% EMS with a 50-55% germination rate. For Hengguan35 and Jimai22, it was 0.6% EMS. For Gaoyou2018 and Kewei20, it was 0.8% and 0.4-0.6%, respectively. The FCR disease index of the mutant lines (M1) ranged from 10.00 to 77.67. For M2, the number of individual mutant plants demonstrating resistance to FCR varied from 76 to 102. In M3, 570 healthy plants were obtained using various EMS concentrations. The mutant line Kewei18 demonstrated the most resistance to FCR, FHB, and Deoxynivalenol (DON) infection. Kewei20 mutants had a higher FHB susceptibility than other mutants. Overall, mutants from the Kewei18 genetic background displayed better disease resistance to both diseases and DON contamination than natural plants. Mutants with or moderate resistance to FCR and FHB could be used in breeding and genetic studies to identify FHB and FCR-resistant Quantitative Trait Locus (QTL) in wheat.

Citations

Citations to this article as recorded by  
  • Mutation breeding: an underutilized strategy for improving finger millet productivity and nutritional quality
    Maltase Mutanda, Sandiswa Figlan, Nemera G. Shargie, Eastonce T. Gwata
    Frontiers in Sustainable Food Systems.2025;[Epub]     CrossRef
  • GAMMA RAY-INDUCED MUTAGENESIS IN FORAGE CROPS: A BIBLIOMETRIC ANALYSIS
    B Putra, Harmini -, J Sirait, J Nulik, D.K. Hau, S Bahar, W Darwiati, D.J. Polakitan, Zubir -, S Agustini, R.F. Suneth, R.A. Saptati, K Simanihuruk
    The Journal of Animal and Plant Sciences.2025; (1): 1.     CrossRef
  • Enhancing drought tolerance in malting and forage barley through mutagenesis
    Dianey Celeste Cruz-Muñoz, Myriam Guadalupe Rodríguez-Gandarilla, Miguel Angel Avila-Perches, Rafael Urrea-López, Julio Armando Massange-Sánchez
    Journal of Crop Science and Biotechnology.2025; 28(4): 521.     CrossRef
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Development of SNP Markers to Distinguish Various Watermelon Traits and Validation Using Fluidigm Genotyping Assay
Sang-Min Yeo, Jeong-Eui Hong, Md Abdur Rahim, Saleh Ahmed Shahriar, Phillip Choe, Sun-Kyun Jung, Ill-Sup Nou
Plant Breed. Biotech. 2023;11(2):141-153.   Published online June 1, 2023
DOI: https://doi.org/10.9787/PBB.2023.11.2.141

Watermelon [Citrullus lanatus (Thunb.) Matsum and Nakai] is one of the economically most important fruit crops of the Cucurbitaceae family. Among different watermelon traits, disease resistance and fruit quality are the important traits for growers and consumers. The single nucleotide polymorphism (SNP) markers similar to those traits can potentially and cost-effectively distinguish the genetic variations among these traits. Consequently, we developed 33 SNP makers linked to different watermelon traits associated with fruit quality and disease resistance, and validated in the genetic resources of watermelon and F1 breeding lines using ‘Fluidigm SNP Genotyping’ assay. Most of the SNP markers distinguished the alleles into three different types such as reference allele, alternative allele and heterozygous from watermelon genotypes for various traits. The SNP markers ‘ZymFL-T81P’ (ZYMV- resistance), ‘FON1-U161’ and ‘FON1-S075’ (Fusarium wilt-resistance), ‘Pmr21-Cla831’ (PM-resistance), and ‘ClGBS-J168’ and ‘GBS-GC230’ (GSB-resistance) can successfully differentiate resistant (R), susceptible (S) and heterozygous watermelon genotypes. Similarly, the SNP marker associated with sugar content, citrulline content, arginine content, rind hardness, flesh firmness, fruit shape, rind strip pattern of watermelon fruit and seed coat colour can successfully distinguished the watermelon genetic resources and F1 breeding lines as reference allele (A) type, alternative allele (B) type and heterozygous (H). These SNP markers could be utilized for marker assisted selection as well as screening of a large number of watermelon germplasm for fruit quality and disease resistance. However, further validation like artificial inoculation of pathogens for the traits related to disease resistance is required in watermelon crops.

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Review

The production of chili pepper (Capsicum annuum L.) is hindered by several biotic factors even though striding progresses were made in genetic improvement in the last two decades. Among the advancements were the fast-track genetic improvement of disease-resistant varieties by the use of marker-assisted selection (MAS) and the conventional breeding-based introgression of major resistance genes. Marker development, marker-based identification and fine mapping have revealed a large number of resistance genes, from which cloning of some candidate genes demonstrated the applicability and versatility of map-based cloning for disease resistance. In some of the recent fine mapping of disease resistance QTLs, closely linked DNA markers were identified, which in turn resulted in the rapid introgression of target gene(s) into breeding lines. Also, progresses were made on the characterization and map-based cloning of resistance genes conferring broad-spectrum resistance. As the number of identified and characterized resistance genes and the DNA markers linked to resistance genes are steadily generated, the development of multiple/durable resistance to major chili pepper diseases is accelerated by MAS. In the present review, the development of molecular markers, marker-based mapping of genes conferring resistance to ten major chili pepper diseases were discussed, focusing on the recent advancements in major and QTL-spanning resistance gene mapping. The review provides up-to-date insights into the development of DNA markers linked to disease resistance genes and the cloning of resistance genes, which are all so crucial in pepper breeding for disease resistance.

Citations

Citations to this article as recorded by  
  • Effects of a Coal-derived Soil Amendment on Plant Growth of Sweet Pepper (Capsicum annuum) and Rhizosphere Microbial Communities
    Xing-Feng Huang, Paul H. Fallgren, Kenneth F. Reardon, Song Jin
    Journal of Soil Science and Plant Nutrition.2026; 26(1): 2799.     CrossRef
  • Integrating Hybrid and Molecular Breeding as Approaches in Vegetable Breeding Strategies
    Janko Červenski, Srđan Zec, Gordana Tamindžić, Dragana Miljaković, Jelena Marinković, Boris Adamović, Đorđe Vojnović, Aleksandra Ilić
    Horticulturae.2026; 12(6): 666.     CrossRef
  • Molecular and genomic insights into viral resistance in Capsicum spp.: pathogenesis, defense mechanisms, and breeding innovations
    Jayabalan Shilpha, Won-Hee Kang
    Frontiers in Plant Science.2025;[Epub]     CrossRef
  • Fine mapping of the Chilli veinal mottle virus resistance 4 (cvr4) gene in pepper (Capsicum annuum L.)
    Joung-Ho Lee, Jung-Min Kim, Jin-Kyung Kwon, Byoung-Cheorl Kang
    Theoretical and Applied Genetics.2025;[Epub]     CrossRef
  • Wild-type and resistance-breaking strains of tomato spotted wilt virus differentially upregulate the immunosuppressive epoxyoctadecamonoenoic acid biosynthesis of its insect vector, Frankliniella occidentalis
    Niayesh Shahmohammadi, Falguni Khan, Donghee Lee, Daehong Lee, Yonggyun Kim
    Journal of General Virology .2025;[Epub]     CrossRef
  • Development of SNP Markers for ms3 Gene of Genetic Male Sterility in Pepper (Capsicum annuum L.)
    Soeun Lee, Bora Geum, Jundae Lee
    Korean Journal of Breeding Science.2025; 57(4): 391.     CrossRef
  • Cleaved Amplified Polymorphic Sequence Markers in Horticultural Crops: Current Status and Future Perspectives
    Krishnanand P. Kulkarni, Richmond K. Appiah, Umesh K. Reddy, Kalpalatha Melmaiee
    Agronomy.2024; 14(11): 2598.     CrossRef
  • The landscape of sequence variations between resistant and susceptible hot peppers to predict functional candidate genes against bacterial wilt disease
    Ji-Su Kwon, Junesung Lee, Jayabalan Shilpha, Hakgi Jang, Won-Hee Kang
    BMC Plant Biology.2024;[Epub]     CrossRef
  • Phenotypical and molecular characterization of new pepper genotypes resistant to Chili pepper mild mottle virus firstly detected in Europe and other tobamoviruses
    Mikel Ojinaga, Ana Aragones, Mónica Hernández, Santiago Larregla
    Scientia Horticulturae.2024; 330: 113074.     CrossRef
  • Assessment of elite pepper breeding lines using molecular markers
    Ercan Ekbiç, Ceylan Özlem Okay
    Plant Biotechnology Reports.2024; 18(4): 515.     CrossRef
  • Current knowledge and breeding strategies for management of aphid-transmitted viruses of pepper (Capsicum spp.) in Africa
    Herbaud P. F. Zohoungbogbo, Fabrice Vihou, Enoch G. Achigan-Dako, Derek W. Barchenger
    Frontiers in Plant Science.2024;[Epub]     CrossRef
  • Comparison of effectiveness of molecular markers linked to Me1 and N genes in pepper (Capsicum annuum L.) (Solanales: Solanaceae)
    Gülsüm Uysal, Zübeyir Devran
    Turkish Journal of Entomology.2024; 48(2): 239.     CrossRef
  • Pepper mild mottle virus: a formidable foe of capsicum production—a review
    Nidhi Kumari, Vivek Sharma, Priyankaben Patel, P. N. Sharma
    Frontiers in Virology.2023;[Epub]     CrossRef
  • Development and Application of a Cleaved Amplified Polymorphic Sequence Marker (Phyto) Linked to the Pc5.1 Locus Conferring Resistance to Phytophthora capsici in Pepper (Capsicum annuum L.)
    Giacomo Bongiorno, Annamaria Di Noia, Simona Ciancaleoni, Gianpiero Marconi, Vincenzo Cassibba, Emidio Albertini
    Plants.2023; 12(15): 2757.     CrossRef
  • QTL Mapping for Resistance to Bacterial Wilt Caused by Two Isolates of Ralstonia solanacearum in Chili Pepper (Capsicum annuum L.)
    Saeyoung Lee, Nidhi Chakma, Sunjeong Joung, Je Min Lee, Jundae Lee
    Plants.2022; 11(12): 1551.     CrossRef
  • A multiplex RT-PCR assay for detection of emergent pepper Tsw resistance-breaking variants of tomato spotted wilt virus in South Korea
    Sun-Jung Kwon, Young-Eun Cho, Hee-Seong Byun, Hae-Ryun Kwak, Jang-Kyun Seo
    Molecular and Cellular Probes.2022; 61: 101792.     CrossRef
  • Advances in S gene targeted genome-editing and its applicability to disease resistance breeding in selected Solanaceae crop plants
    Geleta Dugassa Barka, Jundae Lee
    Bioengineered.2022; 13(6): 14646.     CrossRef
  • Genomic regions and candidate genes linked with Phytophthora capsici root rot resistance in chile pepper (Capsicum annuum L.)
    Dennis N. Lozada, Guillermo Nunez, Phillip Lujan, Srijana Dura, Danise Coon, Derek W. Barchenger, Soumaila Sanogo, Paul W. Bosland
    BMC Plant Biology.2021;[Epub]     CrossRef
  • Resistance-Breaking Tomato Spotted Wilt Virus Variant that Recently Occurred in Pepper in South Korea is a Genetic Reassortant
    Sun-Jung Kwon, Young-Eun Cho, Oh-Hun Kwon, Hyung-Gon Kang, Jang-Kyun Seo
    Plant Disease.2021; 105(10): 2771.     CrossRef
  • Identification of QTLs Controlling α-Glucosidase Inhibitory Activity in Pepper (Capsicum annuum L.) Leaf and Fruit Using Genotyping-by-Sequencing Analysis
    Doie Park, Geleta Dugassa Barka, Eun-Young Yang, Myeong-Cheoul Cho, Jae Bok Yoon, Jundae Lee
    Genes.2020; 11(10): 1116.     CrossRef
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Research Articles

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 Breed. Biotech. 2019;7(3):272-286.   Published online September 1, 2019
DOI: https://doi.org/10.9787/PBB.2019.7.3.272

Developing elite hybrid rice varieties is one important
objective
of rice breeding programs. Several genes related to male sterilities, restores, and pollinators have been identified through map-based gene cloning within natural variations of rice. These identified genes are good targets for introducing genetic traits in molecular breeding. This study was conducted to breed elite hybrid lines with major genes related to hybrid traits and disease/insect resistance in 240 genetic resources and F1 hybrid combinations of rice. Molecular markers were reset for three major hybrid genes (S5, Rf3, Rf4) and thirteen disease/insect resistant genes (rice bacterial blight resistance genes Xa3, Xa4, xa5, Xa7, xa13, Xa21; blast resistance genes Pita, Pib, Pi5, Pii; brown planthopper resistant genes Bph18(t) and tungro virus resistance gene tsv1). Genotypes were then analyzed using molecular marker-assisted selection (MAS). Biological assay was then performed at the Red River Delta region in Vietnam using eleven F1 hybrid combinations and two control vatieties. Results showed that nine F1 hybrid combinations were highly resistant to rice bacterial blight and blast. Finally, eight F1 hybrid rice varieties with resistance to disease/insect were selected from eleven F1 hybrid combinations. Their characteristics such as agricultural traits and yields were then investigated. These F1 hybrid rice varieties developed with major genes related to hybrid traits and disease/insect resistant genes could be useful for hybrid breeding programs to achieve high yield with biotic and abiotic resistance.

Citations

Citations to this article as recorded by  
  • Resistance gene against Xanthomonas oryzae pv. Oryzae (Xoo) in rice: molecular mechanisms and breeding strategies for bacterial leaf blight
    Hongrui Jiang, Qina Huang, Changdeng Yang, Yan Liang
    Frontiers in Plant Science.2026;[Epub]     CrossRef
  • Identification of new genetic resources for broad-spectrum blast resistance genes in Iranian rice germplasm
    Mostafa Modarresi, Hadis Shahbazi, Alireza Tarang, Farzin Pouramir, Maryam Hosseini Chaleshtori, Fatemeh Habibi
    Euphytica.2025;[Epub]     CrossRef
  • ‘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
  • Origins of Susceptibility to Insect Herbivores in High-Yielding Hybrid and Inbred Rice Genotypes
    Finbarr G. Horgan, Maria Liberty P. Almazan, Carmencita C. Bernal, Christine Jade Dilla-Ermita, Goli Ardestani, Enrique A. Mundaca, Eduardo Crisol-Martínez
    Insects.2024; 15(8): 608.     CrossRef
  • Heterosis for Interactions between Insect Herbivores and 3-Line Hybrid Rice under Low and High Soil Nitrogen Conditions
    Finbarr G. Horgan, Carmencita C. Bernal, Angelee Fame Ramal, Maria Liberty P. Almazan, Enrique A. Mundaca, Eduardo Crisol-Martínez
    Insects.2024; 15(6): 416.     CrossRef
  • Genomic Architecture of Yield Performance of an Elite Rice Hybrid Revealed by its Derived Recombinant Inbred Line and Their Backcross Hybrid Populations
    Fan Zhang, Conghe Zhang, Xiuqin Zhao, Shuangbing Zhu, Kai Chen, Guixiang Zhou, Zhichao Wu, Min Li, Tianqing Zheng, Wensheng Wang, Zhi Yan, Qinyong Fei, Zhikang Li, Jinjie Chen, Jianlong Xu
    Rice.2022;[Epub]     CrossRef
  • Genomic Approaches to Identify Molecular Bases of Crop Resistance to Diseases and to Develop Future Breeding Strategies
    Antonia Mores, Grazia Maria Borrelli, Giovanni Laidò, Giuseppe Petruzzino, Nicola Pecchioni, Luca Giuseppe Maria Amoroso, Francesca Desiderio, Elisabetta Mazzucotelli, Anna Maria Mastrangelo, Daniela Marone
    International Journal of Molecular Sciences.2021; 22(11): 5423.     CrossRef
  • Genetic dissection of heterosis of indica–japonica by introgression line, recombinant inbred line and their testcross populations
    Wenqing Yang, Fan Zhang, Sundus Zafar, Junmin Wang, Huajin Lu, Shahzad Naveed, Jue Lou, Jianlong Xu
    Scientific Reports.2021;[Epub]     CrossRef
  • Hybrid Incompatibility of the Plant Immune System: An Opposite Force to Heterosis Equilibrating Hybrid Performances
    Vanesa Calvo-Baltanás, Jinge Wang, Eunyoung Chae
    Frontiers in Plant Science.2021;[Epub]     CrossRef
  • History and Results of Rice Breeding in Korea
    Young-Chan Cho, Man-Kee Baek, Hyun-Su Park, Jun-Hyun Cho, Eok-Keun Ahn, Jung-Pil Suh, Ji-Ung Jeung, Jong-Hee Lee, Yong-Jae Won, Yoo-Chun Song, Eung-Gi Jeong, Bo-Kyeong Kim, Jeom-Ho Lee
    Korean Journal of Breeding Science.2020; 52(S): 58.     CrossRef
  • Transcriptional Modulation of Resistance against Xanthomonas oryzae pv. oryzae Korean Race K2 in japonica Rice
    Marjohn C. Niño, Yong-Gu Cho
    Agronomy.2020; 10(7): 960.     CrossRef
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Expression of Genes Related with Defense Responses against Pathogen Infections in Vitis flexuosa
Md Zaherul Islam, Soon Young Ahn, Seon Ae Kim, Yong-Bum Kwack, Hae Keun Yun
Plant Breed. Biotech. 2016;4(3):324-335.   Published online August 31, 2016
DOI: https://doi.org/10.9787/PBB.2016.4.3.324

Induced defense responses are regulated through a network of signal transduction pathways. Major signal transduction pathways in plants include salicylic acid (SA)- and jasmonic acid (JA)-mediated signaling pathways. In this study, we attempted to identify potential resistance mechanisms/pathways in Vitis flexuosa and the interaction between resistance and resistance related genes of V. flexuosa and several pathogens. To accomplish this, we investigated transcriptional expression of genes in the SA- and JA-mediated pathway and in the flavonoid biosynthesis pathway in V. flexuosa that had been infected by Elsinoë ampelina, Botrytis cinerea, Colletotrichum acutatum, Erysiphe necator, and Rhizobium vitis using real-time polymerase chain reaction (PCR) analysis. Quantitative real-time PCR revealed that R and R-related genes in V. flexuosa induced defense responses through expression of genes in SA-pathway rather than in the JA-pathway, and R-related genes were more closely correlated with lignin and phytoalexin biosynthesis than anthocyanin biosynthesis against different pathogen infections in V. flexuosa. Specifically, genes such as VfRLK586, VfRLK2422, VfRLK5099, VfRLK29610, VfRLK55257, VfRPS5-like4135, VfRPS5-like4832, VfRPS5-like20585, VfRPS5-like55532, VfEDL2, VfEDL3, VfCXE5585, VfCXE12827, and VfCXE13132 showed close correlation with induction of genes in the SA-mediated pathway, lignin, phytoalexin, and anthocyanin biosynthesis. Genes including VfRLK2422, VfRLK5099, VfRLK29610, VfRPS5-like55532, VfEDL3, and VfCXE12827 were also correlated with the JA-mediated signaling pathway in induction of defense responses.

Citations

Citations to this article as recorded by  
  • Mining of differentially expressed genes from Korean wild grapes responding to grapevine leaf rust pathogen (Phakopsora euvitis) infection
    Zar Le Myint, Srinivasan Ramalingam, Soon Young Ahn, Hae Keun Yun
    Horticulture, Environment, and Biotechnology.2024; 65(4): 607.     CrossRef
  • Induction of defense responses related to scavenging reactive oxygen species in Ampelopsis species inoculated with Rhizobium vitis
    Hae In Lee, Zar Le Myint, Soon Young Ahn, Seung Heui Kim, Hae Keun Yun
    Horticulture, Environment, and Biotechnology.2023; 64(4): 655.     CrossRef
  • Anatomical and biochemical changes in leaves of Vitis labrusca L. cv. Niagara Rosada in response to infection by Elsinoë ampelina Shear
    Zélia Valente Braga, Larissa Fernanda Muniz, Gislene Roberta Manarim, Claudio Lima de Aguiar, Beatriz Appezzato-da-Glória
    Brazilian Journal of Botany.2021; 44(1): 187.     CrossRef
  • Identification and functional characterisation of an allene oxide synthase from grapevine (Vitis vinifera L. Sauvignon blanc)
    Walftor Dumin, Michael Rostas, Christopher Winefield
    Molecular Biology Reports.2018; 45(3): 263.     CrossRef
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Review Article
Molecular Markers for Selecting Diverse Disease Resistances in Tomato Breeding Programs
Je Min Lee, Chang-Sik Oh, Inhwa Yeam
Plant Breed. Biotech. 2015;3(4):308-322.   Published online November 30, 2015
DOI: https://doi.org/10.9787/PBB.2015.3.4.308

Tomato (Solanum lycopersicum L.) is an economically important crop worldwide. In addition, tomato serves as an excellent model system for plant genetics and biology, including fruit biology, abiotic stress tolerance, and plant-microbe interactions. Development and practical use of molecular markers have been actively pursued in molecular breeding programs for tomato, especially for disease resistance to allow selection of a single resistance gene and combination of multiple resistance genes. Due to insufficient genetic variation in cultivated tomatoes, various wild relatives of tomato have been investigated and utilized as disease resistance sources. In order to pursue the resistance provided by these wild relatives in developing new tomato varieties, molecular markers have been developed and intensively utilized in tomato breeding programs. In this review, we summarize the currently available molecular markers that confer resistance against major tomato diseases, including Tomato yellow leaf curl virus (TYLCV), Tomato spotted wilt virus (TSWV), Tomato mosaic virus (ToMV), verticillium wilt, fusarium wilt, late blight caused by Phytophthora infestans, leaf mold caused by Cladosporium fulvum, root-knot caused by Meloidogyne spp., bacterial spot caused by Xanthomonas spp., and bacterial speck caused by Pseudomonas syringae. The provided marker information is expected to contribute to development of marker-assisted selection for disease resistance and to exploration of novel genetic sources for a tomato breeding program.

Citations

Citations to this article as recorded by  
  • From Genetic Diversity to Genetic Gain: Molecular Approaches and Breeding Strategies in Tomato with Insights from Lithuanian Germplasm
    Audrius Radzevičius, Danguolė Juškevičienė, Jonas Viškelis, Rasa Karklelienė
    International Journal of Molecular Sciences.2026; 27(12): 5433.     CrossRef
  • Molecular screening of wild and cultivated tomato germplasm reveals potential materials for multi-locus disease resistance breeding
    Ehtisham Hussain, Chien-yu Cheng, I-min Huang, Chen-yu Lin, Samrin Gul, Ijaz Rasool Noorka, Assaf Eybishitz, Chutchamas Kanchana-udomkan, Maarten van Zonneveld, Ya-ping Lin
    Genetic Resources and Crop Evolution.2025; 72(7): 8619.     CrossRef
  • An advanced 10K SNP panel for genotyping tomato (Solanum lycopersicum L.) via targeted genome sequencing
    Yawo Mawunyo Nevame Adedze, Yanfen Xu, Song Liu, Yaran Zhao, Changjuan Mo, Renxu Zhang, Jiahui Dong, Haofa Lan, Jingjing Huang, Xingming Chen, Xuefei Gao, Qingzhen Yin, Jianan Zhang
    Frontiers in Plant Science.2025;[Epub]     CrossRef
  • Presence of disease resistance genes in tomato germplasm revealed by gene-based or gene-linked molecular markers
    Luyao Yang, Jie Ren, Huanhuan Yang, Tao Zhou, Wencai Yang
    Molecular Breeding.2025;[Epub]     CrossRef
  • Use of molecular markers associated with resistance to biotic and abiotic environmental factors in developing breeding material for tomato and pepper in Belarus
    O. G. Babak, E. V. Drozd, N. A. Nekrashevich, N. V. Anisimova, K. K. Yatsevich, P. V. Shesteren, I. Е. Bayeva, N. A. Nevestenko, I. G. Puhachova, M. M. Dobrodzkin, A. V. Kilchevsky
    Vegetable crops of Russia.2025; (1): 5.     CrossRef
  • DNA-free genome editing in tomato protoplasts using CRISPR/Cas9 ribonucleoprotein delivery
    Ga Hui Kang, Beum-Chang Kang, Jeung-Sul Han, Je Min Lee
    Horticulture, Environment, and Biotechnology.2024; 65(1): 131.     CrossRef
  • A search for tomato disease resistance genes using molecular markers to create new genotypes
    I. N. Shamshin, A. S. Ilyichev, M. G. Fomicheva, E. V. Grosheva
    Plant Biotechnology and Breeding.2024; 7(3): 19.     CrossRef
  • Molecular and genetic basis of tomato resistance to major fungal diseases
    M. V. Maslova, I. N. Shamshin, E. V. Grosheva, A. S. Ilyichev
    Vegetable crops of Russia.2023; (6): 28.     CrossRef
  • Seçilmiş Domatesler Arasında Genetik İlişkiler ve Bazı Patojenlere Karşı Dayanım Düzeylerinin Belirlenmesi
    Gülbanu KIYMACI, Ayşe Özgür UNCU, Önder TÜRKMEN
    Akademik Ziraat Dergisi.2023; 12(2): 177.     CrossRef
  • The New Green Challenge in Urban Planning: The Right Genetics in the Right Place
    Silvia Farinati, Angelo Betto, Fabio Palumbo, Francesco Scariolo, Alessandro Vannozzi, Gianni Barcaccia
    Horticulturae.2022; 8(9): 761.     CrossRef
  • Germplasm Screening Using DNA Markers and Genome-Wide Association Study for the Identification of Powdery Mildew Resistance Loci in Tomato
    Jiyeon Park, Siyoung Lee, Yunseo Choi, Girim Park, Seoyeon Park, Byoungil Je, Younghoon Park
    International Journal of Molecular Sciences.2022; 23(21): 13610.     CrossRef
  • QTL-Seq Analysis for Identification of Resistance Loci to Bacterial Canker in Tomato
    Alebel Mekuriaw Abebe, Chang-Sik Oh, Hyoung Tae Kim, Giwon Choi, Eunyoung Seo, Inhwa Yeam, Je Min Lee
    Frontiers in Plant Science.2022;[Epub]     CrossRef
  • Progress in Marker-Assisted Selection to Genomics-Assisted Breeding in Tomato
    Jagesh Kumar Tiwari, Suresh Reddy Yerasu, Nagendra Rai, Dhananjaya P. Singh, Achuit K. Singh, Suhas G. Karkute, Prabhakar M. Singh, Tusar K. Behera
    Critical Reviews in Plant Sciences.2022; 41(5): 321.     CrossRef
  • Screening of pepino (Solanum muricatum) and wild relatives against four major tomato diseases threatening its expansion in the Mediterranean region
    Juan Pacheco, Salvador Soler, Maria R. Figàs, Alberto San Bautista, Jaime Prohens, Pietro Gramazio
    Annals of Applied Biology.2021; 179(3): 288.     CrossRef
  • Evaluation of tomato (Solanum lycopersicum L.) lines and varieties to develop new breeding lines in Korea
    M.C. Cho, S.Y. Lee, E.Y. Yang, C.W. Nam, J.H. Moon, S.Y. Chae, J.H. Kim
    Acta Horticulturae.2021; (1316): 35.     CrossRef
  • Genetic Mapping of green-stripe in Tomato
    Woon Cho, Eun Sol Kang, Je Min Lee
    Horticultural Science and Technology.2021; 39(3): 402.     CrossRef
  • Development of codominant SCAR markers to detect the Pto, Tm22, I3 and Sw5 genes in tomato (Solanum lycopersicum)
    Jianbo Zhang, Dilip R. Panthee, Klaus Pillen
    Plant Breeding.2021; 140(2): 342.     CrossRef
  • Characterization of tomato accessions for morphological, agronomic, fruit quality, and virus resistance traits
    Stanislava Grozeva, Amol N. Nankar, Daniela Ganeva, Ivanka Tringovska, Gancho Pasev, Dimitrina Kostova, Brian Beres
    Canadian Journal of Plant Science.2021; 101(4): 476.     CrossRef
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