1.Clinical utility of live blood analysis.
June Hyek KANG ; Jae Yong SIM ; Hang Suk CHO ; Dong Hee KO ; Sun Hyen KIM ; Hye Ree LEE
Journal of the Korean Academy of Family Medicine 2001;22(1):70-77
BACKGROUND: Recently Live blood analysis was populated in korean society. so we evaluated clinical utility of Live blood analysis, as compared the Live blood analysis result of patients who have confirmed diagnosis of disease with that of controls who have no known health problems. METHODS: We carried out Live blood analysis to patients(n=30) who was entered to an admission in Yongdong severance hospital from February 2000 to March 2000 and to controls(n=30) who worked in that hospital at same time. We examined 3 abnormal finding; rouleau formation, spicule, protoplast, which were often observed in Live blood analysis. RESULTS: At comparison of patient group and control group, rouleau formation was observed in 27 patients except 3 patients and it was observed in all 30 controls. Spicule was observed 2in 9 patients except 1 patients and it was observed in all 30 controls. Protoplast was observed in 16 patients and 13 controls. There was no difference between patients and controls in observing 3 abnormal finding. CONCLUSION: We conclude that Live blood analysis may have no clinical significance.
Complementary Therapies
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Diagnosis
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Humans
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Protoplasts
2.Characteristics of Double Fungicide Resistant Strains of Venturia inaequalis.
P VIJAYA PALANI ; D LALITHAKUMARI
Mycobiology 2000;28(2):70-75
Penconazole-resistant and cabendazim-resistant mutants of Venturiu inaequalis were developed by chemical (MNNG) mutagenesis. Protoplasts of these mutants were isolated and fused using polyethylene glycol as the fusogen. Fusants were classified into parental, non-parental and recombinant types. The recombinants were resistant to penconazole and carbendazim. The double resistant strains were stable and exhibited pathogenicity on fungicide-sprayed and unsprayed apple twigs.
Humans
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Mutagenesis
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Parents
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Polyethylene Glycols
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Protoplasts
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Virulence
3.Protoplasts isolation, purification and plant regeneration of Pinellia cordata.
Xian YANG ; Dan-Dan MA ; Fu-Sheng JIANG ; Ni-Pi CHEN ; Bin DING ; Li-Xia JIN ; Chao-Dong QIAN ; Zhi-Shan DING
China Journal of Chinese Materia Medica 2014;39(21):4211-4215
The main factors which affected the isolation, purification and cultivation of Pinellia cordata protoplasts from leaves were studied. The results indicated that the optimum enzyme solution for P. cordata leaves was 13% CPW + 1.0% Cellulose +0.1% Pectolase, at pH 6.0, temperature (25-28 degrees C ) for 4 h. The sucrose density gradient centrifugation was adopted to purificate the protoplasts collected, when 25% sucrose was used as mediator, centrifugating at 500 rpm for 10 min. When the protoplasts were shallow liquid and liquid-solid double layer cultured on the medium of MS + 0.5 mg x L(-1) 6-BA + 0.25 mg x L(-1) NAA + 13% mannitol at the density of 2.5 x 104 protoplasts/mL, or fed and nursed cultured at the density of 100-500 protoplasts/mL, cell division could be observed for 3 days; granular calli appeared for 30 days. Calli was proliferated on the medium of MS + 0.5 mg x L(-1) 6-BA + 0.25 mg x L(-1) NAA solidified by 0.55% agar, and differentiated and regenerated after 5-6 months. Plant generation of P. cordata is successfully established.
Cell Separation
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methods
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Culture Media
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Pinellia
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physiology
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Protoplasts
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physiology
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Regeneration
4.Current Technologies and Related Issues for Mushroom Transformation.
Sinil KIM ; Byeong Suk HA ; Hyeon Su RO
Mycobiology 2015;43(1):1-8
Mushroom transformation requires a series of experimental steps, including generation of host strains with a desirable selective marker, design of vector DNA, removal of host cell wall, introduction of foreign DNA across the cell membrane, and integration into host genomic DNA or maintenance of an autonomous vector DNA inside the host cell. This review introduces limitations and obstacles related to transformation technologies along with possible solutions. Current methods for cell wall removal and cell membrane permeabilization are summarized together with details of two popular technologies, Agrobacterium tumefaciens-mediated transformation and restriction enzyme-mediated integration.
Agaricales*
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Agrobacterium
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Cell Membrane
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Cell Wall
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DNA
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Protoplasts
5.The Efficient Transformation of Pleurotus ostreatus using REMI Method.
Joong Ho JOH ; Beom Gi KIM ; Kyo Sun CHU ; Won Sik KONG ; Young Bok YOO ; Chang Soo LEE
Mycobiology 2003;31(1):32-35
Restriction enzyme-mediated integration (REMI) was used to transform uracil auxotrophs of Pleurotus ostreatus to prototrophy. When protoplasts of Pleurotus ostreatus were treated by the reaction mixture containing 10 units of BamHI, the frequency of REMI was about 64 transformants per 1 microg of DNA. This efficiency was increased by 14.2 times compared with that of the conventional PEG transformation. The optimal condition for REMI of P. ostreatus was achieved when 1 microg of linearized pTRura3-2 DNA was added into 1x10(7) protoplasts along with 10 units BamHI. Southern blot analysis revealed that about 50% of transformants examined were caused by REMI event and 30% carried single copy insertion at the genome. This suggested that the REMI method might be a useful tool for efficient transformation and tagging mutagenesis of P. ostreatus.
Blotting, Southern
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DNA
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Genome
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Mutagenesis
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Pleurotus*
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Protoplasts
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Uracil
6.Isolation and Characterization of Dikaryotic Mutants from Pleurotus ostreatus by UV Irradiation.
Joong Ho JOH ; Beom Gi KIM ; Won Sik KONG ; Young Bok YOO ; Kyo Sun CHU ; Nam Kuk KIM ; Hye Ran PARK ; Bong Gum CHO ; Chang Soo LEE
Mycobiology 2004;32(2):88-94
Protoplasts of the wild type strain of Pleurotus osteatus were mutagenized with UV light, and 3,000 colonies were examined for abnormal mycelial and fruiting phenotypes. Forty one strains displayed variant phenotypes in mycelia and fruiting processes. The variant phenotypes were classified into 6 groups: (1) auxotrophic strains, which are incapable of growing on minimal media and can only grow when provided with their specific requirements; (2) abnormal vegetative strains, which grow very slowly on minimal and complete media; (3) primordiumless strains, which fail to develop to the formation of primordia; (4) maturationless strains, which form primordia, but do not form mature fruiting bodies; (5) specifically colored strains, which have Specific bluish grey or bluish white pileus; (6) poorly spored strains, which fail to produce basidiospore or which produce few spores. These variant strains may be useful in genetic breeding programs and for the studies of fungal development and genetics.
Breeding
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Fruit
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Genetics
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Phenotype
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Pleurotus*
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Protoplasts
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Spores
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Ultraviolet Rays
7.Construction of protoplast genetic transformation system for Mycena--symbiont of Gastrodia elata.
Qing-Song YUAN ; Jiu-Chun AN ; Hui WANG ; Jiao XU ; Yan-Ping GAO ; Yang YANG ; Wei-Ke JANG ; Jin-Qiang ZHANG ; Liang-Yuan LI ; Tao ZHOU
China Journal of Chinese Materia Medica 2022;47(9):2304-2308
Mycena, a symbiont of Gastrodia elata, promotes seed germination of G. elata and plays a crucial role in the sexual reproduction of G. elata. However, the lack of genetic transformation system of Mycena blocks the research on the interaction mechanism of the two. In order to establish the protoplast transformation system of Mycena, this study analyzed the protoplast enzymatic hydrolysis system, screened the resistance markers and regeneration medium, and explored the transient transformation. After hydrolysis of Mycena hyphae with complexes enzymes for 8 h and centrifugation at 4 000 r·min~(-1), high-concentration and quality protoplast was obtained. The optimum regeneration medium for Mycena was RMV, and the optimum resistance marker was 50 mg·mL~(-1) hygromycin. The pLH-HygB-HuSHXG-GFP-HdSHXG was transformed into the protoplast of Mycena which then expressed GFP. The established protoplast transformation system of Mycena laid a foundation for analyzing the functional genes of Mycena and the molecular mechanism of the symbiosis of Mycena and G. elata.
Agaricales
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Gastrodia/genetics*
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Protoplasts
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Symbiosis/genetics*
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Transformation, Genetic
8.Improvement of Transformation System in Filamentous Fungus Aspergillus oryzae.
Jae Won LEE ; Chan Do YUN ; Young Tae HAHM
Korean Journal of Medical Mycology 2001;6(1):1-8
Aspergillus oryzae is a filamentous fungus classified in the group Aspergillaceae Ascomycetes. A. oryzae is an important microorganism for industrial production of enzymes and fermented food products. It secrets large quantities of proteins or enzymes into the culture medium which makes this organism appealing for the production of heterologous proteins. Recently Electric field-mediated transformation method, electroporation, has been applied to fungal transformation. It is fast, simple to handle, and avoids the use of some chemicals. The optimum conditions for A. oryzae were determined with pILJ-16 and ~0.2 x 105 protoplast cell at various field strength. The survived population of protoplasts in the electric field were ~80% of nonprotoplast cell population at 1.3 KV/cm to ~50% at 6.3 KV/cm. The electrotransformation efficiency, expressed as transformants/microgram of input DNA/population of protoplast cells, increased with the increment of the field strength up to 6.3 KV/cm. The highest value, 14.35%, was obtained at 6.3 KV/cm and 1540ohm. Some antibiotics for the dominant selectable makers were applied to A. oryzae and Tolypocladium inflatum. Whereas phleomycin was very effective on T. inflatum, hygromycin B and phleomycin were not effective on A. oryzae. Protoplasts were obtained with hemicellulase and celluclast, instead of novozyme234. More than 104 transformants/microgram of DNA with hemicellulase-treated protoplasts were obtained by using electroporation at the condition of 2,500 voltage, 1,540 ohm and 0.50 capacitance. Less than 102 transformants/microgram of DNA were obtained with Novozyme234- and celluclast-treated protoplasts.
Anti-Bacterial Agents
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Ascomycota
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Aspergillus oryzae*
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Aspergillus*
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DNA
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Electroporation
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Fungi*
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Hygromycin B
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Oryza
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Phleomycins
;
Protoplasts
9.Somatic hybridization between Brassica napus and Eruca sativa mill.
Chuanli ZHANG ; Zhixin YANG ; Xuemei GUI ; Yating LIU ; Xiaoqiang MAO ; Guoyin XIA ; Liangbin LIN
Chinese Journal of Biotechnology 2008;24(5):793-802
In order to expand gene resources and improve Brassica napus cultivars, protoplasts isolated from hypocotyls of Brassica napus cv. Huayou No. 3 and Eruca sativa were fused by PEG-high Ca2+-high pH. Fusion frequency was up to 18.2% when fusion system contained 5 x 10(5) protoplasts/mL, and when PEG concentration of fusion agents were 35% and when fusion time was 25 min. Then the fused protoplasts were cultured by the method of thin liquid layer at the density of 1 x 10(5) protoplasts/mL in improved KM8p medium supplemented with 1.0 mg/L 2,4-D, 0.5 mg/L NAA, 0.5 mg/L 6-BA, 200 mg/L inositol, 300 mg/L protein hydrolysate, and the combinations of 0.1 mol/L sucrose and 0.2 mol/L glucose and 0.2 mol/L mannitol for osmotic regulator, the frequency of callus regeneration was up to 6.8%. When the micro-calli transferred to the proliferation medium that contained B5 salts, 0.087 mol/L sucrose, 0.2 mg/L 2,4-D, 0.5 mg/L NAA, 0.2 mg/L 6-BA and 0.5% Agar, pH 5.8, have grown up to 3-5 mm of diameter, the calli were transferred to the differentiation medium that contained MS salts, 0.087 mol/L sucrose, 0.1 mg/L IAA, 0.8 mg/L 6-BA, 0.8% Agar, pH5.8, the shoots were regenerated in 4 weeks and its frequency was up to 32.8%. Then 2-3 cm shoots were transferred to 1/2 MS medium with 0.5 mg/L IBA+0.2mg/L 6-BA, plantlets were obtained in 14 days and the plantlet frequency was up to 88%. When the protoplasts of Eruca sativa were treated with UV radiation for 2 minutes calli and plantlets have been regenerated, treated for 4 min only calli have been regenerated, and treated for more than 5 min calli have not been regenerated. The callus regeneration and callus proliferation and plant regeneration from symmetric fusion were more than from asymmetric fusion. 16 hybrid plantlets have been regenerated on 21 piece of hybrid calli identified by cytology method.
Brassica
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genetics
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Brassicaceae
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genetics
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Cell Fusion
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Hybrid Cells
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Hybridization, Genetic
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Protoplasts
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Regeneration
;
Ultraviolet Rays
10.Acquiring homozygous tetraploid germplasm by PEG-mediated protoplast fusion of Rhodiola sachalinensis.
Jianfeng LIU ; Jianhua LIU ; Yunqing CHENG ; Xue ZHONG ; Zhiwen CHEN
China Journal of Chinese Materia Medica 2010;35(14):1783-1788
OBJECTIVETo acquire homozygous tetraploid germplasm of Rhodiola sachalinensis.
METHODPEG-mediated protoplast fusions were conducted using callus of Rh. sachalinensis as materials. Protoplast fusion products were embedded and cultured in low-density, low-melting-point agar and marked according to the protoplast size, and single-celled sister lines were established to acquire genetically homozygous tetraploid germplasm.
RESULTR(D) and R(M) of newborn daughter cells or protoplasm, metaphase cells or protoplasm were approximately in line with the formula R(D) = 0.793 7R(M). The change range in diameter of the diploid cells without fusion, two protoplasts fusion product were: 16.7 microm < or = R < 21.3 microm, 21.0 microm < or = R' < 26.8 microm respectively. There is an overlap between the two diameter ranges. The protoplast inoculation density of 1 x 10(4) cells x mL(-1) was appropriate when protoplasts were anchored by low-intensity, low-melting-point agar. Under the conditions of this density, plating efficiency was high and single cell origin of the sister lines microclones grew rapidly, and it was easy to mark the single cell microclones, and separate from each other to subculture. The chromosome counts results showed that chromosome numbers of diploid and tetraploid of single cell lines were 26 and 52, respectively. The result from flow cytometry assay showed that there is no presence of chimerism in single-cell regeneration plantlets.
CONCLUSIONThe results of this study provide a scientific basis for polyploid breeding of Rh. sachalinensis.
Cell Fusion ; methods ; Polyethylene Glycols ; pharmacology ; Polyploidy ; Protoplasts ; cytology ; drug effects ; Rhodiola ; cytology ; drug effects ; genetics