• 농업과학연구
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• 제43권1호
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• pp.1-13
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• 2016

Climate changes are shifting the perception of C4 photosynthetic crops due to their superior adaptability to harsh conditions. The tribe Andropogoneae includes some economically important grasses, such as Zea mays, Sorghum bicolor, Miscanthus spp., and Saccharum spp., representing C4 photosynthetic grasses. Although the Andropogoneae grasses diverged fairly recently, their genomic structures are remarkably different from each other. As previously reported, the family Poaceae shares the pan-cereal duplication event occurring ca. 65 MYA. Since this event, Sorghum bicolor has never experienced any additional duplication event. However, some lineage-specific duplication events were reported in Z. mays and Saccharum spp., and, more recently, it was revealed that a shared allotetraploidization event occurred before the divergence between Miscanthus and Saccharum (but after the divergence from S. bicolor), which provided important clues to those two species having large genome sizes with complicated ploidy numbers. The complex genomic structures of sugarcane and Miscanthus (defined as the Saccharum complex along with some other taxa) have had a limiting effect on the use of their molecular information in breeding programs. For the last decade, genomics-associated technologies have become an important tool for molecular crop breeding (genomics-assisted breeding, GAB), but it has not been directly applied to sugarcane and Miscanthus due to their complicated genome structures. As genomics research advances, molecular breeding of those crops can take advantage of technical improvements at a reasonable cost through comparative genomic approaches. Active genomic research of non-model species using closely related model species will facilitate the improvement of those crops in the future.

• Journal of Applied Biological Chemistry
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• 제43권4호
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• pp.197-206
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• 2000

This paper summarizes recent developments in the field of molecular biology and its application to plant breeding, particularly in rice. Plant breeding in the past mostly depended on the time-consuming crossing of known genomes limited to certain traits. Plant breeding has now benefited from marker-assisted selection and genetic engineering to widen the gene pool, improve plant protection, and increase yield. Future plant breeding will expand based on functional and nutritional genomics, in which gene discovery and high-throughput transformation will accelerate crop design and benefits will accrue to human health, in the form of nutritional food for poor people to reduce malnutrition, or food enriched with antioxidants and with high food value for rich people. Agricultural biotechnology for food is no longer a dream but a reality that will dominate the 21st century for agriculture and human welfare.

• 한국작물학회:학술대회논문집
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• 한국작물학회 2017년도 9th Asian Crop Science Association conference
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• pp.13-13
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• 2017

By the progress of genome sequencing, infrastructures for marker-assisted breeding (MAB) of rice came to be established. Fine mapping and gene isolation have been conducted using the breeding materials derived from natural variations and artificial mutants. Such genetic analysis by the genome-wide dense markers provided us the knowledge about the many genes controlling important traits. We identified several genes or quantitative trait loci (QTL) for heading date, blast resistance, eating quality, high-temperature stress tolerance, and so on. NILs of each gene controlling heading date contribute to elongate the rice harvest period. Determination of precise gene location of blast resistance gene pi21, allowed us to overcome linkage drag, co-introduction of undesirable eating quality. We could also breed the first practical rice cultivar in Japan with a brown planthopper resistance gene bph11 in the genetic back-ground of an elite cultivar. Discovery of major and minor QTLs for good eating quality allowed us to fine-tune of eating quality according to the rice planting area or usage of rice grain. Many rice cultivars have bred efficiently by MAB for several traits, or by marker-assisted backcross breeding through chromosome segment substitution lines (CSSLs) using genetically diverse accessions. We are also systematically supporting the crop breeding of other sectors by MAB or by providing resources such as CSSLs. It is possible to pyramid many genes for important traits by using MAB, but is still difficult to improve the yielding ability. We are performing a Genomic Selection (GS) for improvement of rice biomass and grain yield. We are also trying to apply the genome editing technology for high yield rice breeding.

• Journal of Plant Biotechnology
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• 제39권1호
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• pp.23-32
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• 2012

Calcium is an essential nutrient for living organisms, with key structural and signaling roles. Its deficiency in plants can result in poor biotic and abiotic stress tolerance as well as reduced crop quality and yield. Calcium deficiency in humans causes various diseases such as osteoporosis and rickets. Biofortification of calcium in various food crops has been suggested as an economic and environmentally advantageous method to enhance human intake of calcium. Recent efforts to increase the levels of calcium in food crops have used calcium/proton antiporters ($CAXs$) and modified one to increase calcium transport into vacuoles through genetic engineering. It has been reported that overall calcium content of transgenic plants has been increased in their edible portions with some adverse effects. In conclusion, biofortification of calcium will add more value in crops as well as will be beneficial for animal and human. Therefore, more fundamental studies on the mechanisms of calcium ion storage and transporting are essential for more effective calcium biofortification.

• Asian-Australasian Journal of Animal Sciences
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• 제28권3호
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• pp.328-333
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• 2015

A genome wide association study was conducted using estimated breeding value (EBV) for milk production traits from 1st to 4th lactation. Significant single nucleotide polymorphism (SNP) markers were selected for each trait and the differences were compared by lactation. DNA samples were taken from 456 animals with EBV which are Holstein proven bulls whose semen is being sold or the daughters of old proven bulls whose semen is no longer being sold in Korea. High density genome wide SNP genotype was investigated and the significance of markers associated with traits was tested using the breeding value estimated by a multiple lactation model as a dependent variant. As the result of significance comparisons by lactations, several differences were found between the first lactation and subsequent lactations (from second to 4th lactation). A similar trend was noted in mean deviation and correlation of the estimated effects by lactation. Since there was a difference in the genes associated with EBV for each trait between first and subsequent lactations, a multi-lactation model in which lactation is considered as a different trait is genetically useful. Also, significant markers in all lactations and common markers for different traits were detected, which can be used as markers for quantitative trait loci exploration and marker assisted selection in milk production traits.

• 생명과학회지
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• 제25권9호
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• pp.1059-1071
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• 2015

수박과 멜론은 경제적 중요성을 지니는 대표적인 박과 작물이다. 최근 유전자 지도 작성 및 차세대 유전체 염기서열 분석에 기반한 분자마커 개발과 염기서열변이 탐색은 마커 이용 선발 및 여교잡 등 분자육종을 통한 품종육성에 필수적 기술이다. 본 연구에서는 이들 작물에 대한 국내외 유전체 분석 과 분자마커 개발 현황에 대해 분석ㆍ정리함으로서 향후 분자육종에 활용할 수 있는 정보를 제공하고자 하였다. 수박과 멜론은 참조유전체의 염기서열이 밝혀졌으며 다수의 유전자 지도가 작성되어 수량, 과특성, 내병성과 같은 주요 형질과 연관된 마커의 개발과 관련 유전자의 탐색이 꾸준히 진행되고 있다. 현재까지 해외에서 보고된 유전자지도는 수박 멜론 각 각 16종 이상이며, 40개 이상의 주요형질에 대한 유전자좌와 연관 마커들이 존재한다. 더욱이 고밀도 유전자 지도와 유전자지도 기반 클로닝을 통해 이러한 형질을 조절하는 기능 유전자에 정보가 밝혀지고 있다. 또한 참조게놈정보를 기반으로 한 다양한 유전자원의 전장유전체염기서열 재분석이 꾸준히 이루어지고 있다. 새로운 분자마커의 자체적 개발과 더불어 이와 같이 현재 활용 가능한 공개된 마커들의 정보를 통해 유전체학 이용 육종과정을 크게 앞당길 수 있을 것이다.

• Plant Biotechnology Reports
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• 제3권4호
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• pp.309-315
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• 2009

Molecular markers developed from the flanking sequences of two cytoplasmic male sterility (CMS)-associated genes, orf456 and ${\Psi}atp6-2$, have been used for marker-assisted selection of CMS in pepper. However, in practice, the presence of orf456 and ${\Psi}atp6-2$ at substoichiometric levels even in maintainer lines hampers reliable selection of plants containing the CMS gene. In this study, we developed a novel CMS-specific molecular marker, accD-U, for reliable determination of CMS lines in pepper, and used the newly and previously developed markers to determine the cytoplasm types of pepper breeding lines and germplasms. This marker was developed from a deletion in a chloroplast-derived sequence in the mitochondrial genome of a CMS pepper line. CMS pepper lines could be unambiguously determined by presence or absence of the accD-U marker band. Application of orf456, ${\Psi}atp6-2$and accD-U to various pepper breeding lines and germplasms revealed that accD-U is the most reliable CMS selection marker. A wide distribution of orf456, but not ${\Psi}atp6-2$, in germplasms suggests that the pepper cytoplasm containing both orf456 and ${\Psi}atp6-2$ has been selected as CMS cytoplasm from cytoplasm containing only orf456. Furthermore, factors other than orf456 may be required for the regulation of male sterility in pepper.

• Journal of Plant Biotechnology
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• 제43권3호
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• pp.272-280
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• 2016

국화는 관상용, 약용으로 활용되는 주요한 화훼 작물중의 하나이다. 국화의 육종 프로그램은 다양한 품종의 개발에 기여하였으나, 다른 주요한 식량, 채소작물에서 보여졌듯이 전통적인 표현형 기반의 품종선발에서 분자표지를 활용한 선발로 진일보할 필요가 있다. 이러한 분자육종은 유전학, 분자생물학, 최근에는 유전체 연구로 규명된 형질연관 분자표지에 의존한다. 그러나 자가불화합성, 자식약세, 이질육배체, 이형접합성, 거대한 유전체와 같은 국화의 생식적, 유전적, 유전체의 특성으로 인하여 이러한 연구는 심각하게 지연되고 있다. 그럼에도 불구하고 유전연구를 통하여 국화의 유전자지도가 구축되었고 꽃, 잎, 식물구조와 같은 국화의 주요한 형질과 연관된 분자표지가 규명되었다. 염기서열 분석기술이 발달됨에 따라 국화의 전사체가 해독되어 국화의 표준유전자 목록이 구축되고 발달단계에 따라 혹은 생물적 비생물적 환경에서 특이적으로 발현되는 유전자도 규명되었다. 또한 2배체인 야생의 국화속 식물의 유전체 해독 프로젝트가 시작되었다. 이러한 대량의 염기서열 정보는 국화의 분자육종을 위한 근원적인 자원으로 활용될 수 있을 것이다. 이 총설에서는 국화의 분자유전학, 유전체 연구의 현황을 요약하고 향후 전망을 논의한다.

• 한국양식학회지
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• 제18권2호
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• pp.130-132
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• 2005

Genomics research has two ultimate applied goals: to Isolate and clone genes of economic importance for bio-technology and gene-assisted selection (GAS), and to locate and use markers for marker-assisted selection (MAS) in selective breeding programs. To this end, we have identified linked markers for feed conversion efficiency growth rate, and disease resistance to enteric septicemia of catfish (ESC). Three microsatellite markers Ip266, Ip384, and Ip607 were identified to be linked to feed conversion efficiency. Similarly one marker each was identified to be linked to growth rate (Ip607) and disease resistance to ESC (Ip477). Ip607 marker linked to both growth rate and feed conversion efficiency, indicating that the QTL for both growth rate and feed conversion efficiency may either be the same or located in the same chromosomal region in the catfish genome. On phenotypic evaluation, certain traits such as growth rate can be accurately evaluated by body weight evaluation while other traits such as disease resistance can be quite complex. The linked DNA markers will be highly useful for MAS programs and for directing further efforts of genomic mapping for important quantitative traits.

• Molecules and Cells
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• 제37권1호
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• pp.36-42
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• 2014

The tomato (Solanum lycopersicum L.) is a model plant for genome research in Solanaceae, as well as for studying crop breeding. Genome-wide single nucleotide polymorphisms (SNPs) are a valuable resource in genetic research and breeding. However, to do discovery of genome-wide SNPs, most methods require expensive high-depth sequencing. Here, we describe a method for SNP calling using a modified version of SAMtools that improved its sensitivity. We analyzed 90 Gb of raw sequence data from next-generation sequencing of two resequencing and seven transcriptome data sets from several tomato accessions. Our study identified 4,812,432 non-redundant SNPs. Moreover, the workflow of SNP calling was improved by aligning the reference genome with its own raw data. Using this approach, 131,785 SNPs were discovered from transcriptome data of seven accessions. In addition, 4,680,647 SNPs were identified from the genome of S. pimpinellifolium, which are 60 times more than 71,637 of the PI212816 transcriptome. SNP distribution was compared between the whole genome and transcriptome of S. pimpinellifolium. Moreover, we surveyed the location of SNPs within genic and intergenic regions. Our results indicated that the sufficient genome-wide SNP markers and very sensitive SNP calling method allow for application of marker assisted breeding and genome-wide association studies.