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"Sang-Choon Lee"

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"Sang-Choon Lee"

Research Articles
Characterization of Chloroplast Genomes, Nuclear Ribosomal DNAs, and Polymorphic SSR Markers Using Whole Genome Sequences of Two Euonymus hamiltonianus Phenotypes
Junki Lee, Shin-Jae Kang, Hyeonah Shim, Sang-Choon Lee, Nam-Hoon Kim, Woojong Jang, Jee Young Park, Jeong Hwa Kang, Wan Hee Lee, Taek Joo Lee, Gyoungju Nah, Tae-Jin Yang
Plant Breed. Biotech. 2019;7(1):50-61.   Published online March 1, 2019
DOI: https://doi.org/10.9787/PBB.2019.7.1.50

Although genomics provides useful tools for crops, most wild resource plants still lack molecular data. To retrieve useful genomic data and thus provide fundamental information for a resource plant, we established a multi-directional approach using two low coverage whole-genome shotgun sequence (WGS) data of Euonymus hamiltonianus, which is a wild resource plant with potential as a medicinal and ornamental plant. We assembled complete chloroplast genome and nuclear ribosomal DNA (nrDNA) sequences and analyzed polymorphic simple sequence repeats (pSSRs) in the nuclear genome based on the comparison of WGS data between two different phenotypes. We developed a bioinformatics pipeline to identify pSSR motifs by systematic comparison of two WGS datasets. The pipeline is composed of multiple steps including end-joining of paired reads, isolation of joined reads harboring SSR motifs derived from unique non-repetitive regions, identification of pSSR via in silico comparison with counterpart WGS reads, design of pSSR primer sets, and validation. The pipeline was applied to WGS data of E. hamiltonianus and identified 161 contigs with pSSR motifs between the two different phenotypes. Based on the pSSR motifs, 20 primer pairs were designed, of which seven were successfully validated as real pSSR markers. We expect this information to be applicable to genomic resources of E. hamiltonianus.

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  • A First Approach for the In Vitro Cultivation, Storage, and DNA Barcoding of the Endangered Endemic Species Euonymus koopmannii
    Balnur Kali, Sara Bekkuzhina, Dilnur Tussipkan, Shuga Manabayeva
    Plants.2024; 13(16): 2174.     CrossRef
  • High-throughput discovery of plastid genes causing albino phenotypes in ornamental chimeric plants
    Hyun-Seung Park, Jae-Hyeon Jeon, Woohyeon Cho, Yeonjeong Lee, Jee Young Park, Jiseok Kim, Young Sang Park, Hyun Jo Koo, Jung Hwa Kang, Taek Joo Lee, Sang Hoon Kim, Jin-Baek Kim, Hae-Yun Kwon, Suk-Hwan Kim, Nam-Chon Paek, Geupil Jang, Jeong-Yong Suh, Tae-J
    Horticulture Research.2023;[Epub]     CrossRef
  • Analysis of the complete plastomes and nuclear ribosomal DNAs from Euonymus hamiltonianus and its relatives sheds light on their diversity and evolution
    Young Sang Park, Jong-Soo Kang, Jee Young Park, Hyeonah Shim, Hyun Ok Yang, Jung Hwa Kang, Tae-Jin Yang, Sudhindra R. Gadagkar
    PLOS ONE.2022; 17(10): e0275590.     CrossRef
  • Comparative Analyses of Euonymus Chloroplast Genomes: Genetic Structure, Screening for Loci With Suitable Polymorphism, Positive Selection Genes, and Phylogenetic Relationships Within Celastrineae
    Yongtan Li, Yan Dong, Yichao Liu, Xiaoyue Yu, Minsheng Yang, Yinran Huang
    Frontiers in Plant Science.2021;[Epub]     CrossRef
  • De Novo Assembly and Species-Specific Marker Development as a Useful Tool for the Identification of Scutellaria L. Species
    Hakjoon Choi, Wan Seok Kang, Jin Seok Kim, Chang-Su Na, Sunoh Kim
    Current Issues in Molecular Biology.2021; 43(3): 2177.     CrossRef
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Genome-Wide Identification of the Dehydrin Genes in the Cucurbitaceae Species
Sang-Choon Lee, Won-Kyung Lee, Asjad Ali, Manu Kumar, Tae-Jin Yang, Kihwan Song
Plant Breed. Biotech. 2017;5(4):282-292.   Published online December 1, 2017
DOI: https://doi.org/10.9787/PBB.2017.5.4.282

Dehydrins (DHNs) are hydrophilic proteins with conserved lysine-rich K-segment, which belong to Group II of the late embryogenesis abundant (LEA) protein family. DHNs are considered as molecular chaperons playing important roles in abiotic stress tolerance. In this study, DHN genes were identified through genome-wide searches in five Cucurbitaceae species, including cucumber, wild cucumber, melon, watermelon, and bitter gourd. Three to five DHN genes were found in each of the five species, which were further divided into several protein architecture types based on the presence and order of the major conserved motifs such as K-, Y-, and S-segments. In silico expression profiling using RNA-Seq data revealed high expression of SK3-type DHN gene and low expression of other type DHN genes in cucumber and melon. In silico promoter analysis identified a number of cis-acting element-like sequences related to abiotic stress-response such as DRE and ABRE in 2-kb putative promoter sequences. DHN genes identified in this study will be valuable for understanding the stress response mechanism as well as assisting molecular breeding in Cucurbitaceae crops.

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  • Drought stress tolerance mechanisms and their potential common indicators to salinity, insights from the wild watermelon (Citrullus lanatus): A review
    Goitseone Malambane, Kelebogile Madumane, Lesego T. Sewelo, Utlwang Batlang
    Frontiers in Plant Science.2023;[Epub]     CrossRef
  • Genome-wide comprehensive characterization and expression analysis of TLP gene family revealed its responses to hormonal and abiotic stresses in watermelon (Citrullus lanatus)
    Chet Ram, Shagufta Danish, Mahipal Singh Kesawat, Bhupendra Singh Panwar, Manjusha Verma, Lalit Arya, Sheel Yadav, Vedprakash Sharma
    Gene.2022; 844: 146818.     CrossRef
  • Genome Assembly and Annotation of Soft-Shelled Adlay (Coix lacryma-jobi Variety ma-yuen), a Cereal and Medicinal Crop in the Poaceae Family
    Sang-Ho Kang, Byeollee Kim, Beom-Soon Choi, Hyun Oh Lee, Nam-Hoon Kim, Seung Jae Lee, Hye Sik Kim, Myung Ju Shin, Hyo-Won Kim, Kyunghyun Nam, Kyoung Dae Kang, Soo-Jin Kwon, Tae-Jin Oh, Sang-Choon Lee, Chang-Kug Kim
    Frontiers in Plant Science.2020;[Epub]     CrossRef
  • Knockdown of Gh_A05G1554 (GhDHN_03) and Gh_D05G1729 (GhDHN_04) Dehydrin genes, Reveals their potential role in enhancing osmotic and salt tolerance in cotton
    Joy Nyangasi Kirungu, Richard Odongo Magwanga, Lu Pu, Xiaoyan Cai, Yuanchao Xu, Yuqing Hou, Yun Zhou, Yingfan Cai, Fushun Hao, Zhongli Zhou, Kunbo Wang, Fang Liu
    Genomics.2020; 112(2): 1902.     CrossRef
  • Diverse responsiveness of dehydrin genes to abscisic acid and water stress treatments in cucumber F1 cultivar hybrids
    Anita Szegő, Eszter Badics, Dorottya Gubala, Réka Oszlányi, Bat-Erdene Oyuntogtokh, Noémi Kappel, István Papp, Erzsébet Kiss-Bába
    The Journal of Horticultural Science and Biotechnology.2019; 94(6): 726.     CrossRef
  • Comprehensive Transcriptome Profiling and Identification of Potential Genes Responsible for Salt Tolerance in Tall Fescue Leaves under Salinity Stress
    Erick Amombo, Xiaoning Li, Guangyang Wang, Shao An, Wei Wang, Jinmin Fu
    Genes.2018; 9(10): 466.     CrossRef
  • Crosstalk between Brassinosteroids and Ethylene during Plant Growth and under Abiotic Stress Conditions
    Petra Jiroutova, Jana Oklestkova, Miroslav Strnad
    International Journal of Molecular Sciences.2018; 19(10): 3283.     CrossRef
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The Complete Chloroplast Genome Sequence and Intra-Species Diversity of Rhus chinensis
Inseo Kim, Jee Young Park, Yun Sun Lee, Ho Jun Joh, Shin Jae Kang, Jayakodi Murukarthick, Hyun Oh Lee, Young-Jin Hur, Yong Kim, Kyung Hoon Kim, Sang-Choon Lee, Tae-Jin Yang
Plant Breed. Biotech. 2017;5(3):243-251.   Published online September 1, 2017
DOI: https://doi.org/10.9787/PBB.2017.5.3.243

Rhus chinensis is a shrub widely distributed in Asia. It has been used for traditional medicine and ecological restoration. Here, we report the complete chloroplast genome sequence of two R. chinensis genotypes collected from China and Korea. The assembled chloroplast genome of Chinese R. chinensis is 149,094 bp long, consisting of a large single copy (97,246 bp), a small single copy (18,644 bp) and a pair of inverted repeats (16,602 bp). Gene annotation revealed 77 protein coding genes, 30 tRNA genes, and 4 rRNA genes. A phylogenomic analysis of the chloroplast genomes with 11 known complete chloroplast genomes clarified the relationship of R. chinensis with the other plant species in the Sapindales order. A comparative chloroplast genome analysis identified 170 SNPs and 85 InDels at intra-species level of R. chinensis between Chinese and Korean collections. Based on the sequence diversity between Korea and Chinese R. chinensis plants, we developed three DNA markers useful for genetic diversity and authentication system. The chloroplast genome information obtained in this study will contribute to enriching genetic resources and conservation of endemic Rhus species.

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  • Complete plastid and 45S rDNA sequences allow authentication of Liriope platyphylla and Ophiopogon japonicus
    Yeonjeong Lee, Hyun-Seung Park, Jae-Hyeon Jeon, Jee Young Park, Seung Hyun Kim, Jungmoo Huh, Sunmin Woo, Do-Won Jeong, Tae-Jin Yang
    Current Plant Biology.2022; 30: 100244.     CrossRef
  • Variation among the Complete Chloroplast Genomes of the Sumac Species Rhus chinensis: Reannotation and Comparative Analysis
    Yujie Xu, Jun Wen, Xu Su, Zhumei Ren
    Genes.2022; 13(11): 1936.     CrossRef
  • Phytochemical, Antioxidant, Anti-Microbial, and Pharmaceutical Properties of Sumac (Rhus coriaria L.) and Its Genetic Diversity
    Anna Perrone, Sanaz Yousefi, Boris Basile, Giandomenico Corrado, Antonio Giovino, Seyed Alireza Salami, Alessio Papini, Federico Martinelli
    Horticulturae.2022; 8(12): 1168.     CrossRef
  • Authentication of Rubus coreanus and Related Species via DNA Barcoding and HPLC Approaches
    Young Sang Park, Young Jun Kim, Tae Jin Yang, Ji Yeon Kim
    Korean Journal of Medicinal Crop Science.2021; 29(6): 425.     CrossRef
  • Plastid genomes of the North American Rhus integrifolia-ovata complex and phylogenomic implications of inverted repeat structural evolution in Rhus L.
    Craig F. Barrett
    PeerJ.2020; 8: e9315.     CrossRef
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High-Throughput Development of Polymorphic Simple Sequence Repeat Markers Using Two Whole Genome Sequence Data in Peucedanum japonicum
Junki Lee, Ho Jun Joh, Nam-Hoon Kim, Sang-Choon Lee, Woojong Jang, Beom Soon Choi, Yeisoo Yu, Tae-Jin Yang
Plant Breed. Biotech. 2017;5(2):134-142.   Published online June 1, 2017
DOI: https://doi.org/10.9787/PBB.2017.5.2.134

Resource plants are important and have strong potential for a variety of utilities as crops or pharmaceutical materials. However, most resource plants remain wild and thus their utility for breeding and biotechnology is limited. Molecular markers are useful to initiate genetic study and molecular breeding for these understudied resource plants. We collected various wild collections of Peucedanum japonicum which is indigenous resource plants utilized as oriental medicine and leafy vegetables in Korea. In this study, we produced two independent whole genome sequences (WGSs) from two collections and identified large scale polymorphic simple sequence repeat (pSSR) based on our pipeline to develop SSR markers based on comparison of two WGSs. We identified a total of 452 candidate pSSR contigs. To confirm the accuracy and utility of pSSR, we designed ten SSR primer pairs and successfully applied those to seven collections of P. japonicum. The WGS and pSSR candidates identified in this study will be useful resource for genetic research and breeding purpose for the valuable resource plant, P. japonicum.

Citations

Citations to this article as recorded by  
  • Complete plastid and 45S rDNA sequences allow authentication of Liriope platyphylla and Ophiopogon japonicus
    Yeonjeong Lee, Hyun-Seung Park, Jae-Hyeon Jeon, Jee Young Park, Seung Hyun Kim, Jungmoo Huh, Sunmin Woo, Do-Won Jeong, Tae-Jin Yang
    Current Plant Biology.2022; 30: 100244.     CrossRef
  • De Novo Assembly and Species-Specific Marker Development as a Useful Tool for the Identification of Scutellaria L. Species
    Hakjoon Choi, Wan Seok Kang, Jin Seok Kim, Chang-Su Na, Sunoh Kim
    Current Issues in Molecular Biology.2021; 43(3): 2177.     CrossRef
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Genome-Wide Identification and Classification of the AP2/EREBP Gene Family in the Cucurbitaceae Species
Sang-Choon Lee, Won-Kyung Lee, Asjad Ali, Manu Kumar, Tae-Jin Yang, Kihwan Song
Plant Breed. Biotech. 2017;5(2):123-133.   Published online June 1, 2017
DOI: https://doi.org/10.9787/PBB.2017.5.2.123

AP2/EREBP gene family consists of transcription factor genes with a conserved AP2 DNA-binding domain and is involved in various biological processes. AP2/EREBP gene families were identified through genome-wide searches in five Cucurbitaceae species including cucumber, wild cucumber, melon, watermelon, and bitter gourd, which consisted of more than 100 genes in each of the five species. The gene families were further divided into five groups including four subfamilies (ERF, DREB, AP2 and RAV) and a soloist group. Among the subfamilies, DREB subfamily which is known to be related to abiotic stress response was more analyzed and a total of 25 genes were identified as Cucurbitaceae homologues of Arabidopsis CBF/DREB1 genes which are important for abiotic stress-response and tolerance. In silico expression profiling using RNA-Seq data revealed diverse expression patterns of cucumber AP2/EREBP genes. AP2/EREBP gene families identified in this study will be valuable for understanding the stress response mechanism as well as facilitating molecular breeding in Cucurbitaceae crops.

Citations

Citations to this article as recorded by  
  • BnAP2-12 overexpression delays ramie flowering: evidence from AP2/ERF gene expression
    Xiaoyang Zhang, Wenxian Peng, Hao Chen, Hucheng Xing
    Frontiers in Plant Science.2024;[Epub]     CrossRef
  • Genome Assembly and Structural Variation Analysis of Luffa acutangula Provide Insights on Flowering Time and Ridge Development
    Aizheng Huang, Shuo Feng, Zhuole Ye, Ting Zhang, Shenglong Chen, Changming Chen, Shijun Chen
    Plants.2024; 13(13): 1828.     CrossRef
  • Genome-Wide Identification of APETALA2/ETHYLENE RESPONSIVE FACTOR Transcription Factors in Cucurbita moschata and Their Involvement in Ethylene Response
    Qingfei Li, Li Zhang, Peiwen Chen, Chunhui Wu, Huaixia Zhang, Jingping Yuan, Junguo Zhou, Xinzheng Li
    Frontiers in Plant Science.2022;[Epub]     CrossRef
  • Breeding strategies for enhancing nutrient content and quality in Cucurbitaceae: a review
    Wan Nur Suzani Sazleen Wan Shafiin, Nurfatin Liyana Ablah, Hasan Nudin Nur Fatihah, Md. Amirul Alam, Rohayu Ma’arup, Md Sarwar Jahan, Kamarul Ain Mustafa, Nadiawati Alias
    International Journal of Vegetable Science.2021; 27(5): 415.     CrossRef
  • Systematic analysis of the Capsicum ERF transcription factor family: identification of regulatory factors involved in the regulation of species-specific metabolites
    Jiali Song, Changming Chen, Shuanglin Zhang, Juntao Wang, Zhubing Huang, Muxi Chen, Bihao Cao, Zhangsheng Zhu, Jianjun Lei
    BMC Genomics.2020;[Epub]     CrossRef
  • Knockdown of Gh_A05G1554 (GhDHN_03) and Gh_D05G1729 (GhDHN_04) Dehydrin genes, Reveals their potential role in enhancing osmotic and salt tolerance in cotton
    Joy Nyangasi Kirungu, Richard Odongo Magwanga, Lu Pu, Xiaoyan Cai, Yuanchao Xu, Yuqing Hou, Yun Zhou, Yingfan Cai, Fushun Hao, Zhongli Zhou, Kunbo Wang, Fang Liu
    Genomics.2020; 112(2): 1902.     CrossRef
  • Crosstalk between Brassinosteroids and Ethylene during Plant Growth and under Abiotic Stress Conditions
    Petra Jiroutova, Jana Oklestkova, Miroslav Strnad
    International Journal of Molecular Sciences.2018; 19(10): 3283.     CrossRef
  • Comprehensive Transcriptome Profiling and Identification of Potential Genes Responsible for Salt Tolerance in Tall Fescue Leaves under Salinity Stress
    Erick Amombo, Xiaoning Li, Guangyang Wang, Shao An, Wei Wang, Jinmin Fu
    Genes.2018; 9(10): 466.     CrossRef
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A Glimpse of Panax ginseng Genome Structure Revealed from Ten BAC Clone Sequences Obtained by SMRT Sequencing Platform
Woojong Jang, Nam-Hoon Kim, Junki Lee, Nomar Espinosa Waminal, Sang-Choon Lee, Murukarthick Jayakodi, Hong-Il Choi, Jee Young Park, Jong-Eun Lee, Tae-Jin Yang
Plant Breed. Biotech. 2017;5(1):25-35.   Published online March 1, 2017
DOI: https://doi.org/10.9787/PBB.2017.5.1.25

Korean ginseng (Panax ginseng) is a well-known valuable medicinal plant with excellent therapeutic effects, however its complex genome structure has not been elucidated yet. To understand its genome structure, we obtained ten ginseng bacterial artificial chromosome (BAC) clone sequences by single-molecule real-time (SMRT) sequencing platform using a pooled DNA of the BAC clones. Out of the ten BAC clones, nine were completely assembled without any gap and one remained a single gap. The total length of BAC clone sequences was 1,163,364 bp. Sophisticated sequence analysis revealed that the 89.7% of the sequences are high copy repeat regions and the remaining 10.3% are non-repeat regions. Eleven protein-coding genes were identified in the non-repeat regions. Most of the repeat regions show more than 1,000 copies and complex structure of various repetitive elements. Ty3/Gypsy family long terminal repeat retrotransposons (LTR-RTs) are predominant repeats occupying 46.9% of the 1,163-kbp sequence. We identified six novel LTR-RTs and their insertion time. Fluorescence in situ hybridization (FISH) analysis demonstrated that PgDel2 and PgDel5 elements had a subgenome-biased distribution. Collectively, our analysis reveals that ginseng genome has very complex genome structure with abundant repetitive elements and rare gene frequency.

Citations

Citations to this article as recorded by  
  • High-resolution genetic map and SNP chip for molecular breeding in Panax ginseng, a tetraploid medicinal plant
    Woohyeon Cho, Woojong Jang, Hyeonah Shim, Jiseok Kim, Youngju Oh, Jee Young Park, Young Chang Kim, Jung-Woo Lee, Ick-Hyun Jo, Misun Lee, Jinsu Gil, Martin Mascher, Murukarthick Jayakodi, Xuejiao Liao, Jiang Xu, Deqiang Dou, Yi Lee, Tae-Jin Yang
    Horticulture Research.2024;[Epub]     CrossRef
  • Beyond genome: Advanced omics progress of Panax ginseng
    Wenjing Yu, Siyuan Cai, Jiali Zhao, Shuhan Hu, Chen Zang, Jiang Xu, Lianghai Hu
    Plant Science.2024; 341: 112022.     CrossRef
  • Cytokinin signaling promotes root secondary growth and bud formation in Panax ginseng
    Kyoung Rok Geem, Yookyung Lim, Jeongeui Hong, Wonsil Bae, Jinsu Lee, Soeun Han, Jinsu Gil, Hyunwoo Cho, Hojin Ryu
    Journal of Ginseng Research.2024; 48(2): 220.     CrossRef
  • Construction of a Single File Reference Transcriptome Database for Deodeok (Codonopsis lanceolata) and Sseumbagwi (Ixeridium dentata)
    Tae-Ho Lee, Yun-Ho Oh, Ji-Nam Kang, Si-Myung Lee
    Korean Journal of Breeding Science.2023; 55(4): 321.     CrossRef
  • Salinity responses and tolerance mechanisms in underground vegetable crops: an integrative review
    Kumar Nishant Chourasia, Sanket Jijabrao More, Ashok Kumar, Dharmendra Kumar, Brajesh Singh, Vinay Bhardwaj, Awadhesh Kumar, Sourav Kumar Das, Rajesh Kumar Singh, Gaurav Zinta, Rahul Kumar Tiwari, Milan Kumar Lal
    Planta.2022;[Epub]     CrossRef
  • Dynamic evolution of Panax species
    Hyeonah Shim, Nomar Espinosa Waminal, Hyun Hee Kim, Tae-Jin Yang
    Genes & Genomics.2021; 43(3): 209.     CrossRef
  • Gibberellin Signaling Promotes the Secondary Growth of Storage Roots in Panax ginseng
    Chang Pyo Hong, Jinsoo Kim, Jinsu Lee, Seung-il Yoo, Wonsil Bae, Kyoung Rok Geem, Jin Yu, Inbae Jang, Ick Hyun Jo, Hyunwoo Cho, Donghwan Shim, Hojin Ryu
    International Journal of Molecular Sciences.2021; 22(16): 8694.     CrossRef
  • Genetic diversity among cultivated and wild Panax ginseng populations revealed by high-resolution microsatellite markers
    Woojong Jang, Yeeun Jang, Nam-Hoon Kim, Nomar Espinosa Waminal, Young Chang Kim, Jung Woo Lee, Tae-Jin Yang
    Journal of Ginseng Research.2020; 44(4): 637.     CrossRef
  • Till 2018: a survey of biomolecular sequences in genus Panax
    Vinothini Boopathi, Sathiyamoorthy Subramaniyam, Ramya Mathiyalagan, Deok-Chun Yang
    Journal of Ginseng Research.2020; 44(1): 33.     CrossRef
  • Five-color fluorescence in situ hybridization system for karyotyping of Panax ginseng
    Nomar Espinosa Waminal, Tae-Jin Yang, Jun-Gyo In, Hyun Hee Kim
    Horticulture, Environment, and Biotechnology.2020; 61(5): 869.     CrossRef
  • Complete Mitochondrial Genome and a Set of 10 Novel Kompetitive Allele-Specific PCR Markers in Ginseng (Panax ginseng C. A. Mey.)
    Woojong Jang, Hyun Oh Lee, Jang-Uk Kim, Jung-Woo Lee, Chi-Eun Hong, Kyong-Hwan Bang, Jong-Wook Chung, Ick-Hyun Jo
    Agronomy.2020; 10(12): 1868.     CrossRef
  • Molecular Genetic Diversity and Population Structure of Ginseng Germplasm in RDA-Genebank: Implications for Breeding and Conservation
    Kyung Jun Lee, Jung-Ro Lee, Raveendar Sebastin, Gyu-Taek Cho, Do Yoon Hyun
    Agronomy.2020; 10(1): 68.     CrossRef
  • Genome and evolution of the shade‐requiring medicinal herb Panax ginseng
    Nam‐Hoon Kim, Murukarthick Jayakodi, Sang‐Choon Lee, Beom‐Soon Choi, Woojong Jang, Junki Lee, Hyun Hee Kim, Nomar E. Waminal, Meiyappan Lakshmanan, Binh van Nguyen, Yun Sun Lee, Hyun‐Seung Park, Hyun Jo Koo, Jee Young Park, Sampath Perumal, Ho Jun Joh, Ha
    Plant Biotechnology Journal.2018; 16(11): 1904.     CrossRef
  • Isoform Sequencing Provides a More Comprehensive View of the Panax ginseng Transcriptome
    Ick-Hyun Jo, Jinsu Lee, Chi Hong, Dong Lee, Wonsil Bae, Sin-Gi Park, Yong Ahn, Young Kim, Jang Kim, Jung Lee, Dong Hyun, Sung-Keun Rhee, Chang Hong, Kyong Bang, Hojin Ryu
    Genes.2017; 8(9): 228.     CrossRef
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