• Weed & Turfgrass Science
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• v.5 no.2
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• pp.82-87
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• 2016

Herbicide options for weed control in sorghum is very limited, hence there is a need for exploring potential herbicides. Sorghum herbicide tolerance field trails were conducted at two locations, Yaechoun, Gyeongsangbuk-do, and Miryang, Gyeongsangnam-do, in 2013. Tolerance of sorghum was evaluated following the pre-emergence application of methabenzthiazuron 70% (WP), simazine 50% (WP), oxadiargyl 1.7% (EC), and dimethenamid-P 5% + pendimethalin 20% (EC) at the standard rate 157.5 g, 75 g, 5.1 g, and 75 g a.i. $10a^{-1}$, respectively. As well as double the standard rate. On a phytotoxicity scale of 0 to 9, methabenzthiazuron (WP) induced injury to sorghum up to level 1 at the standard rate and to 3 at double the rate, but did not significantly affect the yield any statistical difference from the untreated. Simazine (WP) induced phytotoxicity up to levels 2 and 4 at single and double rates, respectively. Simazine (WP) did not significantly affect yield: however, the values were numerically lower than those in the methabenzthiazuron (WP) treatment. Oxidiargyl (EC) and dimethenamid + pendimethalin (EC) induced no or slight phytotoxicity; however they failed to provide effective weed control at the standard rate (32 and 68% control, respectively). Out of the tested, methabenzthiazuron (WP) was found to have potential for use in sorghum whereas the other herbicides caused unacceptable levels of injury.

• Korean Journal of Weed Science
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• v.8 no.2
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• pp.182-186
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• 1988

This study was conducted to level up the tolerance of tobacco plant against bialaphos herbicide through tissue culture. The relatively good shoot regeneration from the subcultured calli treated with bialaphos at 0.5 ppm was observed in old the tobacco varieties tested such as NC 82, BY 4 and KA 101. However, at the treatment of bialaphos 1.0 ppm, shoot regeneration was only made in KA 101 variety, showing better regeneration than that of untreated one, When these shoots were transfered to the medium containing of bialaphos 10.0 ppm, the percentage of living shoots (i.e. tolerant plant) was very low, showing 2.43% in NC 82, 2.76% in KA 101 and 0.78% BY 4. Calli were induced and multiplied from leaf petiole of the above tolerant plants even under 2.5ppm of bialaphos, showing an average of 9% in NC 82 and 16% in KA 101 as compared with the untreated control. No calli were induced from tolerant plants as bialaphos concentration increased up to 5.0 ppm. Direct shooting from leaves of the above tolerant plants, that is selected at 10.0ppm of bialaphos treatment, was observed even under 10.0ppm of bialaphos treatment both in NC 82 and in KA 101 varieties, indicating that tolerance of tobacco plants against bialaphos can be greatly increased.

• Korean Journal of Weed Science
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• v.17 no.2
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• pp.176-184
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• 1997

The rice(Oryza saliva L.) tolerance to herbicide thiobencarb was determined. At the concentration of thiobencarb 3.0kg ai/ha, Yamabiko, M73 (23)F.A, and wx 139-3-64-220-3-1 were the most tolerant among 643 rice genotypes tested. Thiobencarb reduced plant height until 14 days after treatment by 10% and 13% in tolerant and susceptible genotypes, respectively, but increased plant height in 21 days after treatment for both the genotypes, though partial stunting or dwarfing was observed during the early period until 14 days after treatment. Number of tillers per plant was greater in the plants treated by thiobencarb than in the control, showing that the tolerant genotypes had 2 to 3 tillers which were more than the susceptible ones. Regardless of the genotypes, shoot dry weight was increased by 30 to 50% in 35 days after thiobencarb treatment. The root dry weight increased by 50 to 100% in 35 days after the treatment.

• Korean Journal of Plant Tissue Culture
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• v.21 no.3
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• pp.151-156
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• 1994

Acifluorfen-tolerant cell lines of S, ptycanthum were isolated by stepwise selection using suspension culture. Growth of unselected line was completely inhibited at $0.5\;\mu\textrm{M}$, while some selected lines grew at $8\;\mu\textrm{M}$ acifluorfen. After subculturing on acifluorfen-free medium for 4 passages, six of the eleven cell lines screened and maintained their tolerance to $2\;\mu\textrm{M}$ acifluorfen. The regeneration capacity of selected cell lines in Solanum ptycanthum differed depending on the tell line. The acifluorfen tolerance of the somarclones regenerated from acifluorfen-tolerant cell lines differed depending on the somarclone. When plants were heated with $16\;\mu\textrm{M}$ acifluorfen, unselected control plane had over 75% phytotoxicity Many selected cell lines had less phytotoxicity than the seed-grown control plants. Tolerance to acifluorfen was inherited to the self-pollinated progenies. The inheritance patterns differed depending on the clone. Acifluorfen tolerance was inherited as a semidominant trait. Other segregation patterns were also observed. acifluorfen tolerance was recessive and acifluorfen sensitivity was dominant.

• Journal of Plant Biotechnology
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• v.38 no.2
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• pp.117-124
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• 2011

Considering that the world population is expected to total 9 billion by 2050, it will clearly be necessary to sustain and even accelerate the rate of improvement in crop productivity. In the 21st century, we now face another, perhaps more devastating, environmental threat, namely climate change, which could cause irreversible damage to agricultural ecosystem and loss of production potential. Enhancing intrinsic yield, plant abiotic stress tolerance, and pest and pathogen resistance through agricultural biotechnology will be a critical part of feeding, clothing, and providing energy for the human population, and overcoming climate change. Development and commercialization of genetically engineered crops have significantly contributed to increase of crop yield and farmer's income, decrease of environmental impact associated with herbicide and insecticide, and to reduction of greenhouse gas emissions from this cropping area. Advances in plant genomics, proteomics and system biology have offered an unprecedented opportunities to identify genes, pathways and networks that control agricultural important traits. Because such advances will provide further details and complete understanding of interaction of plant systems and environmental variables, biotechnology is likely to be the most prominent part of the next generation of successful agricultural industry. In this article, we review the prospects for modification of agricultural target traits by genetic engineering, including enhancement of photosynthesis, abiotic stress tolerance, and pest and pathogen resistance associated with such opportunities and challenges under climate change.

• Korean Journal of Weed Science
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• v.17 no.4
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• pp.400-406
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• 1997

Greenhouse studies were conducted to evaluate the tolerance of 42 pepper cultivars to postemergence applications of bentazon [3-(1-methylethyl)-(1H)-2,1,3-benzothiadiazin-4(3H)-one 2,2-dioxide]. Cultivars, Jopoong, Singsing House, Sweet Green, Kwangbok, and Ilcheon showed relatively tolerant response to bentazon, while cultivars, Dahhong, Early Glory, Korea, Cheongyang, Nostalgia, and Daejanggyeong were susceptible ones to it. At rates over 2.40 kg ai/ha, the tolerant cultivars appeared to be clearly or more tolerant than the susceptible cultivars. For the determination of growth inhibition by bentazon, the concentration required to reduce growth by 50% (GR_(50)) was 2.00 to 2.40 kg ai/ha for susceptible cultivars, and 10.00 to 12.00 kg ai/ha for tolerant cultivars. Moreover, the herbicide rate required to inhibit growth by 50% $(I_{50})$ was 2.40 kg ai/ha for susceptible cultivars and 9.60 kg ai/ha for tolerant cultivars, respectively. On the $I_{50}$ and $GR_{50}$ estimates of growth, the tolerant cultivars were 5- to 6-fold more tolerant to bentazon than susceptible ones.

• Korean Journal of Plant Tissue Culture
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• v.24 no.4
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• pp.203-212
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• 1997

The impact of plant genetic engineering, a technology born in the early 1980's, is beginning to be felt across the world in the 1990's. The first wave of engineered plant produce are reaching consumers in the supermarket and many more are destined to follow Transformation technology now exists for most plant, including the four staple crops-maize, wheat, rice, and soybean. Early targets of genetic engineering include plane possessing insect resistance and herbicide tolerance, with future goals set on increasing harvestable yield, improving nutritional quality, and making specialty products. This review describes some of the milestones in plant biotechnology, the U.S. regulatory agencies, field trial numbers and deregulated plants, commercialization criteria, examples of commercialized plants, and future prospects of plant biotechnology.

• Proceedings of the Korean Society of Toxicology Conference
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• 2006.11a
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• pp.87-94
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• 2006

Genetically modified (CM) crops with agricultural traits including herbicide resistance and insect tolerance have been commercialized. The safety testing strategies conducted for food and feed ingredients from GM crops differ from those applied to food ingredients in that they are conducted to demonstrate similarity between the CM food and the appropriate non-CM comparator rather than for quantitative risk assessment. However, there are similarities in the design and conduct of the safety assessment studies between these types of studies that should be readily recognized by toxicologists. The current presentation reviews some of the basic principles of safety assessment of typical dietary ingredients and compares and contrasts them with the testing strategies applied to CM foods and products obtained from them.

• The Korean Journal of Pesticide Science
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• v.4 no.3
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• pp.89-92
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• 2000

A series of 5-(2-metllyl-2-alkylindallyl)cyclohexane-1,3-diones were synthesized and evaluated for herbicidal activities in a green house. Under submerged paddy conditions, those compounds showed high herbicidal activity against barnyardgrass with good tolerance on rice.

• Korean Journal of Weed Science
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• v.6 no.2
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• pp.174-190
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• 1986

A series of laboratory and greenhouse experiments were conducted to find out the possibility of tissue culture and cell culture methods as a tool to study herbicidal behaviour and herbicide tolerance screening from 1985 to 1986 at the Yeongnam Crop Experiment Station. For dehulled-rice culture, pure agar medium was the most appropriate in rice growth campared to other media used for plant tissue culture method. All the media but the pure agar medium resulted in growth retardance by approximately 50% and this effect was more pronounced to root growth than shoot growth. Herbicidal phytotoxicity was enhanced under light condition for butachlor, 2.4-D, and propanil while this effect was reversed for DPX F-5384 and CGA 142464, respectively. And also, herbicides of butachlor, chlornitrofen, oxadiazon, and BAS-514 resulted in more phytotoxic effect when shoot and root of rice were exposed to herbicide than root exposure only while other used herbicides exhibited no significant difference between two exposure regimes. Similar response was obtained from Echinochloa crusgalli even though the degree of growth retardance was much greater. Particularly, butachlor, 2.4-D, chlornitrofen, oxadiaxon, pyrazolate and BAS-514 totally inhibited chlorophyll biosynthesis even at the single contact of root. Apparent cultivar differences to herbicide were observed at the young seedling culture method and dehulled rice cultivars were more tolerant in DPX F-5384, NC-311, pyrazolate and pyrazoxyfen, respectively. For derant than other types or rice cultivar in butachlor, pretilachlor, perfluidone and oxadiazon while Tongil-type rice cultivars were more tolerant in DPXF-5384, NC-311, Pyrazolate and Pyrazoxyfen, respectively. For dehulled rice culture, on the other hand, Japonica-type rice cultivar was less tolerant to herbicides of butachlor, propanil, chlornitrofen and oxadiazon that was reversed trend to young seedling culture test. Cultivar differences were also exhibited within same cultivar type. In general, relatively higher tolerant cultivars were Milyang 42, Cheongcheongbyeo, Samgangbyeo, Chilseoungbyeo for Tongil-type, Somjinbyeo for Japonica-type and IR50 for Indica-type, respectively. The response of callus growth showed similar to dehulled rice culture method in all herbicides regardless of property variables. However, concentration response was much sensitive in callus response. The concentration ranges of $10^{-9}M-10^(-8)M$ were appropriate to distinguish the difference between herbicides for E. crusgalli callus growth. Among used herbicides, BAS-514 was the most effective to E. crusgalli callus growth. Based on the above results, tissue culture method could be successfully used as a tool for studying herbicidal behaviour and tolerance screening to herbicide.