Background : This study was conducted to develop sustainable and safe ginseng cultivation facilities to cope with climate change and to save labor due to the decrease of labor force in rural areas. Methods and Results : In 2017, we designed the wide-shading facility which was unmanned and labor saving to cope with climate warming and decreasing labor force in farming area for stable and sustainable production of ginseng. The developed model is called model Ⅰ(Slope-shading facility, Gyeongsangbuk-do ARES), model Ⅱ (Slope-shading facility, Gyeonggi-do ARES) and Model Ⅲ (Roof-type shading facility, RDA, NIHHS, Department of Herbal Crop Research). The tested varieties were stem-violet variant, and the transplanting was done by using the 2-years-old seedlings on April 3, 2017 and the planting density was 90 plant/1.62㎡. A thermometer, a light meter, and a rain gauge were installed in the center of the facility on April 13, 2017 to measure the micro-weather in the facility. Micro-weather observations were made from April 14 to October 10, measuring temperature, humidity, light intensity, soil moisture content, water leakage, and wind speed. Surveys were carried out on June 20 and September 29, respectively. The maximum temperature in the facility was 2 to 3℃ lower than the outside, but the relative humidity was 2 - 3% higher in the facility than in the outside. Soil moisture did not show a clear trend among the models. The light transmittance was 5 - 10% and it was the highest in model I, where the height of the shading facility was the highest. Rain leakage was 10 - 36%, the most in model Ⅱ. The amount of leaks increased with the amount of precipitation per hour. In all models, ginseng stem and leaf were damaged due to excessive water leakage. On July 10, stem and leaf were grown well only in wide-shading facility where leakage was adequately blocked with double-sided film. The average wind speed was less than 1.6 m/s during the survey period. The maximum wind speed was 8.8 m/s or less, which did not affect the deformation of the wide-shading facility. In all models, there was no difference in growth of aboveground part and root. Conclusion : As a result, in order to grow ginseng continuously and stably using wide-shading facilities, it is considered that the amount of leakage should be minimized by using material that can prevent leakage in cope with rainfall or heavy rain rather than wind-resistance.

Background : This study examined EC in soil depending on leaking water rate of sun shading facilities and conducted experiments to establish the proper leaking water rate for ginseng depending on rainfall. Methods and Results : For leakage examination, rainfall flowing into a ridge. As sun shading facilities of ginseng to examine leakage, four kinds such as Blue-Pe-sheet, Pe4 (four–layered polyethylene net) + Pe2 (two–layered polyethylene net), Pe4, Pe2 were installed. As for leakage, a plastic box (23 × 30 × 30 ㎝) was installed on the ridge of ginseng field and outside, rainfall into the box during precipitation was examined, and the leakage quantity was calculated as the ratio of the quantity into the ginseng field regarding rainfall outside. The leakage quantity was examined a total of six times on July 2, July 3, August 24, August 30, August 31, and September 4. Regarding EC in soil, WT–1000n (www.rfsenser.co) which is a EC measuring instrument was used, and the average was calculated through 3 repeated examinations. There are little differences in the leakage quantity depending on the sun shading with 0.1% of the Blue-Pe-sheet, 2.3% of Pe4 + Pe2, 4.3% of Pe4, and 30.7% of Pe2. At the leakage rate of 0.1%, EC decreased from 1.52 ds/m on July 3 to 1.04 ds/m on August 8, and increased again to 1.54 ds/m on September 3 At the leakage rate of 2.4%, EC changes were lower than that of the leakage quantity of 0.1%, and similar results depending on periods were found. At the leakage rate of 4.3%, salt concentration was measured at 0.92 ds/m on July 3, decreased since then, increased to 0.90 ds/m on September 3, and overall concentration was less than 1.0 ds/m. At the leakage rate of 30.7%, EC was the lowest at 0.46 ds/m and similar results were found since then. Conclusion : The differences in leakage quantity depending on sun shading facilities of ginsengs affected EC in soil, and EC became lower with more leakage quantity. As for the leakage quantity to maintain the EC in soil proper for ginseng growth and development lower than 1.0 ds/m, it was found to be effective to control the leakage quantity at 30% in May - June, and September - October when there are less rainfall, and at 2 - 5% in July - August when there are heavy rainfall.

Background : Among registered fungicides for controlling ginseng disease, the disease occurrence rate from the mixed use of a single ingredient, mancozeb WP, and copper sulfate basic WP was examined, and experiments were conducted to establish safe disease control system. Methods and Results : As for the medicines used for the experiments, besides registered Pyraclostrobin WG as a single ingredient for ginseng disease control, 14 kinds were used for experiments. The fungicide was sprayed 5 times on June 21, July 4, July 16, August 2 and August 24. The examination was conducted 5 days, 10 days, 15 days, and 20 days after the final fungicide treatment. Anthracnose occurrence rate 5 days after the final fungicide treatment was 0.0 - 61.3% which was different depending on fungicides, and in a single treatment, the occurrence rate was less than 1% in 6 fungicides. In the single treatment, the occurrence rate was more than 1%, but 9 kinds of fungicides which had less than 1% occurrence rate in the case of mixed use with mancozeb, and one kind in the case of mixed use with copper sulfate basic 10 days later, the occurrence rate was 0.0 - 100% and there were lots of differences in the disease occurrence rate depending on fungicides. 10 kinds of fungicides showed the disease occurrence rate of more than 10.0% in the case of a single treatment. Among them, 9 fungicides showed the disease occurrence rate of less than 1.0% in the case of mixed use with mancozeb, indicating the effect of lowering disease occurrence rate in the case of mixed use. 15 days later, 9 fungicides showed disease occurrence rate of more than 2%, 1 kind of fungicide had the disease occurrence rate of less than 1%, and the overall disease occurrence rate increased. Among them, 7 kinds of fungicides showed the disease occurrence rate of less than 1% from the mixed use. 20 days later, 12 kinds of fungicides showed the disease occurrence rate of more than 50%, and only 1 kind of fungicide showed the disease occurrence rate of less than 1%. In the case of mixed use with mancozeb, 2 kinds had the disease occurrence rate of less than 10% and 1 kind of fungicide had the disease occurrence rate of less than 1%. Conclusion : For prevention of anthracnose disease of ginsengs during a rainy season, the disease occurrence rate from a single or mixed use was examined, and the examination found that rather than a single use, mixed use decreased the disease occurrence rate. In particular, the mixed use with mancozeb showed low disease occurrence rate and prevented the disease occurrence rate for a long time.

Background : Ginseng sometimes develops physiological disorders as EC of soil accumulates in sun shading facilities with no leaking water. In addition, it is difficult to make moisture content of soil and EC stably suitable for ginseng growth and development in the same sun shading facility. Accordingly, this study examined EC in soil depending on leaking water rate of sun shading facilities and conducted experiments to establish the proper leaking water rate for ginseng depending on rainfall. Methods and Results : For leakage examination, rainfall flowing into a ridge. As sun shading facilities of ginseng to examine leakage, four kinds such as Blue-Pe-sheet, Pe4 (four–layered polyethylene net) + Pe2 (two–layered polyethylene net), Pe4 , Pe2 were installed. As for leakage, a plastic box (23 × 30 × 30 ㎝) was installed on the ridge of ginseng field and outside, rainfall into the box during precipitation was examined, and the leakage quantity was calculated as the ratio of the quantity into the ginseng field regarding rainfall outside. The leakage quantity was examined a total of six times on July 2, July 3, August 24, August 30, August 31, and September 4. Regarding EC in soil, WT-1000n which is a EC measuring instrument was used, and the average was calculated through 3 repeated examinations. There are little differences in the leakage quantity depending on the sun shading with 0.1% of the Blue-Pe-sheet, 2.3% of Pe4 + Pe2, 4.3% of Pe4, and 30.7% of Pe2. At the leakage rate of 0.1%, EC decreased from 1.52 ds/m on July 3 to 1.04 ds/m on August 8, and increased again to 1.54 ds/m on September 3 At the leakage rate of 2.4%, EC changes were lower than that of the leakage quantity of 0.1%, and similar results depending on periods were found. At the leakage rate of 4.3%, salt concentration was measured at 0.92 ds/m on July 3, decreased since then, increased to 0.90 ds/m on September 3, and overall concentration was less than 1.0 ds/m. At the leakage rate of 30.7%, EC was the lowest at 0.46 ds/m and similar results were found since then. Conclusion : Differences in leakage quantity depending on sun shading facilities of ginseng affected EC in soil, and EC became lower with more leakage quantity. For the leakage quantity to maintain the EC in soil proper for ginseng growth and development lower than 1.0 ds/m, it was found to be effective to control the leakage quantity at 30% in May - June, and September - October when there are less rainfall, and at 2 - 5% in July - August when there are heavy rainfall.

Background : Development of new real-time PCR diagnosis method for simultaneous diagnosis of Cylindrocarpon destructans and Fusarium solani, causative fungi of ginseng root rot disease. C. destructans and F. solani are known to be the major pathogens of ginseng root rot disease. Root rot caused by these pathogens is a disease that is difficult to control because the disease progresses slowly and it is difficult to diagnose early and even when symptoms of plant seeding are present, the disease is already spread in the roots. Diagnostic methods to detect the presence or absence of ginseng roots rot fungi in soil before ginseng cultivation are currently being used as a method for controlling. However, commercialized soil extraction kits and PCR diagnostics have cost, diagnostic time, and single diagnostic problems, and need to develop new diagnostic methods. Methods and Results : Primers and probes in the beta-tubulin 2 gene were designed for species-specific detection. In silico analysis, the detection rate of C. destructans was 100% and the detection rate of F. solani was 95%. The multiplex real time PCR optimization conditions including the internal control were established. The analytical sensitivity using positive samples was 10 copies/㎕ for C. destructans and 10 copies/㎕ for F. solani. As a result of performance comparison test with conventional PCR diagnosis methods, it was confirmed that the developed multiplex real time PCR method has the same or better performance in terms of sensitivity. In the developed soil extraction kit, the extraction time was reduced and the extracted DNA quality was improved, compared to the used soil extraction kit. Conclusion : From the above results, we expect that the developed C. destructans / F. solani multiplex real time PCR diagnosis method and soil extraction kit will be useful for real-time monitoring of ginseng root rot pathogenic fungi in the soil of ginseng cultivation area and diagnosis of suitability of ginseng cultivation area.

Background : Root rot is a major factors of replanting failure in ginseng cultivation. Some of the phenolics detected in the soil could inhibit the seed germination and seedling growth of ginseng. Methods and Results : Water of 2 ℓ was irrigated per pot (20 ℓ) into the soil infected with ginseng root rot pathogens for one month every day. After the irrigation treatment, the powder of ginseng fine root of 20 g per pot was mixed with the irrigated soil. NO3 -, electric conductivity (EC), exchangeable Na (Ex. Na) and K (Ex. K) were decreased in descending order by irrigation. NO3 -, EC, Ex. K, and available P2O5 were increased in descending order by incorporation of ginseng powder into soil. Trichoderma crassum was decreased by irrigation, but it was increased again by incorporation of powder. Haematonectria haematococca was increased by irrigation, but it was decreased by incorporation of powder. Cylindrocarpon spp. and Fusarium spp. causing ginseng root rot were increased by incorporation of powder. Arthrobacter oryzae and Streptomyces lavendulae were increased by irrigation. Streptomyces lavendulae was decreased, and Arthrobacter spp. was increased by incorporation of powder. Aerial growth of ginseng was promoted by irrigation, and ginseng root rot was increased by incorporation of powder. Conclusion : The residues of ginseng root in the soil affected soil nutrients and microorganisms, and promoted ginseng root rot, but did not affect the aerial growth of ginseng.

Background : Ginseng (Panax ginseng C. A. meyer) is a medicinal herb which has been used for prevention and treatment of diseases in Korea, China and Japan for a long time. Ginseng is well known to have effects such as immunity enhancement, anticancer, antioxidative effect and blood circulation improvement. These pharmacological effects of ginseng have been reported to be due to various ginsenoside components. Recently, many studies have been actively conducted to identify the major components and functionalities of ginseng berry. Ginsenoside, a representative active ingredient of ginseng, is distributed in various parts of ginseng. However, contents of certain ingredient such as ginsenoside Re which have antidiabetic effect is higher in ginseng berry. This study was conducted to compare ginsenoside content and UV blocking effect according to the color of ginseng berry. Methods and Results : The ginseng berry extracts for the component analysis and UV-blocking effect test were obtained by harvesting the ginseng berry by color in 4-years-old ginseng cultivated, and then removing the seeds and extracting only the flesh of the ginseng berry and the peel with methanol. Ginsenosides analysis was carried out by dissolving 100 ㎎ of the extract in 2 ㎖ of methanol, filtering it with a 0.50 ㎛ filter and using it as a sample for HPLC analysis. Analysis of ginsenoside content showed that the total ginsenoside and ginsenoside Rb2 content of yellow ginseng berry were 23.9 and 2.9 ㎎/g, while those of red berry was 19.6 and 2.3 ㎎/g, respectively. The UV blocking effect of yellow ginseng berry was 17.4%, which was higher than that of red berry. Conclusion : The ginsenoside content and UV blocking effect of yellow ginseng berry were superior to those of red berry. These results suggested that yellow berry is more useful as cosmetic material for UV protection.

Background : The major active components of ginseng are ginsenosides and their pharmacological effects include anticanser, anti-stress, anti-fatigue, antioxidant and aging inhibitory effects. These ginsenosides components is higher in leaves than roots. Therefore, consumers are increasingly interested in using ginseng sprouts. Methods and Results : Ginseng sprouts were cultivated during 60 days from June to late July in greenhouse. After 60 days of cultivation, the stem was hardened, and the cultivation was done until 60th because of the tendency that the value of ginseng sprouts was lowered. The content of the three indicator components were analysed by high performance liquid chromatography. Total ginsenoside content increased 1.07 times in leaves and decreased 0.67 times in roots according to cultivated period. The contents of ginsenoside Rg1, Re, Rb1, Rc F3 and F4 of leaves were increased and ginsenoside Rg1, Re, Rb1, Rb2 and Rf of roots were decreased on cultivated 60 days, especially. Total free sugar content increased 1.29 times in leaves and decreased 0.68 times in roots according to cultivated period. The total phenolic acid contents of leaves decreased slightly until 40 days and then increased. The major components of ginsenoside, free sugar and phenolic acid in leaves were Re, sucrose and sinapic acid, respectively. Conclusion : From the above results, ginseng sprouts cultivated for 60 days is more effective ingredient than roots, so it can be said that it is good for consumers to use.

Background : Panax ginseng the king of Oriental medicines, has enormous potential against many of the disease symptoms and ailments. Panax quinquefolius is an another important member of Panax family which has similar benefits and medicinal properties. Both the species contains ginsenosides a pharmacologically active component abundant in their roots. In an effort to establish the new ginseng cultivars with improved agronomical characters such as root shape, stress tolerant and higher ginsenoside contents, the reciprocal interspecific hybrids were generated Methods and Results : Four elite cultivars and two new lines of ginseng were chosen to produce interspecies reciprocal hybrids with P. quinquefolius, by pollen dusting on the emasculated flowers. Among the F1 populations, the reciprocal hybrids generated by using new line 0837 both as maternal and paternal parent showed better properties and hybrid vigor. They showed strong root phenotypes with many lateral and fine roots thus having 10% to 20% higher ginsenoside contents compared to the parental populations. Among the major ginsenosides, the pharmacologically active ginsenosides such as Re, Rb1, Rb2 and F1 were enriched and accounted for the 70% of the PPD ginsenosides in 0837/Pq and Pq/0837 crosses, displaying strong dominance. Conclusion : Thus, based on our result we could conclude that P. ginseng line 0837 is the superior variety compared to the already existing lines for performing the interspecific hybrids with promising outcome in their root quality and ginsenoside content.

Background : Korean ginseng require 3 - 4 years to produce mature seeds from their mother plants. Therfore, it takes over 20 years to genetic fixation by artificial crossing of 8 generation. Anther culture is a useful method for obtaining homozygotes in only one generation. However, there is not much research on ginseng yet. In this study, we investigated the callus induction of anther depending on the type and concentration of the plant growth regulators in Panax ginseng C. A. Meyer. Methods and Results : Flower buds of P. ginseng were cold pretreated at 2 days before the anthers were plated on the induction medium. The flower buds were immersed in 70% ethanol for 30 sec min, washed two times with sterile distilled water, surface-sterilized in 2% sodium hypochlorite solution for 20 min, then rinsed five times with sterile distilled water. The anthers were placed on Petri dishes containting fifteen different concentrations and combinations of 2,4-D, NAA, BAP and KT. Callus induction was significantly influenced by the type and combination of plant growth regulators. The highest callus induction rate was observed in GR5 medium at 79.2%. The 2,4-D mediums had significantly higher callus induction than the NAA medium, and 2,4-D 1 ㎎/ℓ have a higher callus induction rate than the other concentrations. The increase of callus induction rate was not observed by the addition of cytokinin, but the callus induction rate was gradually decreased as the BAP concentration was increased. There was no difference in callus induction rate between BAP and KT. Conclusion : The important factor for inducing callus of ginseng anther was the addition of 2,4-D, and no effect of cytokinin addition could be found.

Background : Mutagenesis is one of the most powerful method for genetic variation, however there is little research history in P. ginseng. The seeds and vegetative tissues are materials commonly used for mutagenesis, but there is a problem that chimeras known as sectoral differences can occur and unintentional poor selection can occur owing to the influence of the growth environment. The combination of in vitro culture and mutagenesis can eliminate the effects of the environmental factors. Methods and Results : Gamma irradiation was carried out using a 60Co irradiator (3000Ci, Nordion Inc., Ottawa, Canada) of the Korea Atomic Energy Research Institute, Jeongeup, Korea. The explants containing the somatic embryos were treated with 20, 40, 60, 80, and 100 Gy. Gamma-rays affected the somatic embryos produced in vitro depending on the dose. The survival rate of somatic embryo was significantly influenced by gamma irradiation. Also, the development of the embryo was changed by gamma irradiation depending on each dose. When somatic embryos were transferred to the medium supplemented with GA3, they started to germinate but were affected significantly by gamma irradiation dose. When germinated shoots were transferred to 1/2 SH medium to induce rooting, as the concentration of gamma ray treatment increased, the rooting gradually decreased. Conclusion : Considering the overall survival rate, germination rate, embryo development, and rooting rate, the optimal dose of gamma rays to be used with somatic embryo is estimated to be between 60 Gy and 80 Gy.

Background : Panax ginseng C. A. Meyer is an important medicinal herb and their major pharmacologically active components are ginsenosides. Many studies have reported that various ginsenosides are effective in the treatment of human diseases such as cancer, cardiovascular and alzheimer’s disease. However, it is difficult to create new desirable variation such as increased ginsenosides. Since the frequency of spontaneous mutations is rare naturally and difficult to apply to plant breeding, artificial mutation inductions are necessary to obtain noble genetic resources having desirable traits. Methods and Results : Gamma irradiation was carried out using a 60Co irradiator (3000Ci, Nordion Inc., Ottawa, Canada) of the Korea Atomic Energy Research Institute, Jeongeup, Korea. One-year-old ginsengs were treated at 20, 40, 60, 80, and 100 Gy. The emergence rate was significantly decreased with increasing gamma doses. When irradiated at more than 80 Gy, it did not emerge at all. Survival rate was also significantly influenced by gamma-ray dose. The maximum survival rate were recorded in control. The survival rate of 20 Gy was 22.0% and only 1.0% survived when 40 Gy dose was treated. There was no survival when irradiated at more than 60 Gy. Gamma irradiation also affected the phenotype of emerged plants. The growth of plants derived from irradiated one-year-old ginsengs was decreased and the leaves became variegated or curled. Also, rusty roots resulting from physiological disorders were observed and the rhizomes, which is a kind of dormant bud, were destroyed completely. Conclusion : Based on these results, we estimated the optimal dose for mutation induction by gamma-ray treatment of one-year-old ginseng is to be less than 20 Gy.

Background : The conventional ginseng breeding is time-consuming and labor-intensive. Furthermore, it is difficult to create new desirable variation such as resistant to various stresses and increased ginsenosides. Therefore, creating variants remains a serious challenge of ginseng breeding. Methods and Results : Gamma irradiation was carried out using a 60Co irradiator (3000Ci, Nordion Inc., Ottawa, Canada) of the Korea Atomic Energy Research Institute, Jeongeup, Korea. The dehiscent seeds were treated 20, 40, 60, 80, 100, 120, 150, 200 and 400 Gy. The seed germination was greatly influenced by gamma-ray treatment. It was found that the germination rate decreased significantly when treated at 60 Gy or more. The maximum survival rate was achieved at 20 Gy but there was no significant difference from control. Following exposure to 40 Gy or more, survival rate was declined compared to the control. Gamma irradiation affected not only the germination and survival rate but also the growth of plants germinated from seeds. As gamma irradiation dose increased, the size of the plant decreased sharply and it also had a negative effect on root development. Conclusion : Considering the extent of reduction in the germination and survival rates, as well as growth reduction, the optimal dose of gamma-ray for inducing mutation in ginseng dehiscent seeds was estimated at approximately 40 Gy, because the germination rate observed at 40 Gy was similar to that of the observed in the control, while the survival rate was 50% of the control.

Background : Recently, the shortage of first planted ginseng field has increased direct seeding cultivation in paddy. Therefore, the demand for the development of ginseng varieties suitable for direct seeding cultivation in paddy has increased. So the aim of this study was selection ginseng varieties and germplasms suitable for direct seeding cultivation in paddy. Methods and Results : We used 13 varieties and 191 lines of Korean ginseng (Panax ginseng C. A. Meyer) in this study. Ginseng Seeds were harvested at the end of July 2013, sown in mid-November, and were grown for four years in paddy. In 2017, the survey was conducted on 27 items of growth characteristics in accordance with the standards for survey of ginseng variety, and the degree of diseases and physiological disorders. Among ginseng varieties, the growth of Gopoong, Sunwon and Gwumjin were excellent. However, the incidence of physiological disorder was low in Gumpoong and Geumsun. Among the genetic sources, the growth of 7 ginseng lines, such as G04092, G04098, M05015, G07053, G10069 and G10093, were excellent. However, the incidence of physiological disorder was low in 10 lines of ginseng, such as G04020, G04061, G04081, G04092, G05054, G07052, G07053, G10069 and G10093. Conclusion : This result suggests that 5 varieties and 10 lines of ginseng showed outstanding growths in paddy. In the future, we will review the characteristics of root and the content of ginsenosides of ginseng variety and elite lines.

Background : One generation of ginseng is four years, so it takes a long time to breed. So far, a total of 18 ginseng varieties have been developed under pure line selection. However the pure line selection can reach the limit, because ginseng’s gene pool is very small. A solution to this is the need for cross breeding. Therefore, this study carries out cross breeding for the introduction of excellent character and expansion of variation and check the F1 generation. Methods and Results : As plant materials, Chunpoong, Yunpoong, Gumpoong, Chungsun and Cheonryang were used in this study. In order to cultivate the F1 of ginseng, we cross-bred ginseng varieties from mid-May to late May 2013 and harvested seeds from late July. Ginseng seeds were sown on November 15 and cultivated in 2014 for one year in the field and then transplanted into the main field in 2015. In 2017, the survey was conducted on 27 items of growth characteristics in accordance with the standards for survey of ginseng variety, such as length of leaf, length of stem and width leaf, and the degree of diseases and physiological disorders. In a combination of cross-breeding in domestic ginseng varieties, the germination time and growth characteristics of F1 were not much different from the parent plants, but the incidence of disease was reduced. Conclusion : According to this study, there was a tendency for expressing dominant figures in the crossbreeding between ginseng varieties. In the future, we will review the characteristics of root and the content of ginsenosides of F1.

Background : Recently, there is an urgent demand for development of new varieties with enhanced resistance to various biotic/abiotic stresses. One generation of ginseng is four years, so it takes a long time to breed. To increase the efficiency of the ginseng breeding and save time and effort, it is necessary to build a ginseng core collection. This study examined the major growth characteristics of genetic sources for the establishment of core collection. Methods and Results : As plant materials, 187 ginseng lines collected in 2003 were used in this study. Ginseng Seeds were harvested at the end of July 2014, sown in mid-November, and cultivated in 2015 for one year in the field and then transplanted into the main field in 2016. All phenotypes including agronomic characteristics, seed yield, and physiological response to biotic/abiotic stresses were investigated according to the ginseng GAP and UPOV guidelines. The stem colors of the collected ginseng germplasm were classified as the five classes; light green, green, light purple, purple and dark purple, but most of them were purple or dark purple. The locations of distribution of anthocyanin coloration in stem were classified into the four classes; proximal end, proximal end and petiole part, the entire stem and the stem with purple not revealed, but most of them were petiole part or the entire stem. The shapes of leaflet were classified the four classes; the long elliptic, elliptic, slender type, and spatulate type. Most of surveyed lines were elliptic type. When the leaflet of ginseng was laterally cut, the shape was classified into the three types; concave type, plane type and convex type. Most of surveyed lines were red berry color. Conclusion : The genetic pool of ginseng is known to be narrow. The results of this study showed similar characteristics among the ginseng fields collected. In the future, we will carry out the survey about quantitative characteristics and correlations of ginseng genetic resources for establishment of Korean ginseng core collection.

Background : This study examines the main growth characteristics, physiological stress, or diseases damage for 3 and 4-years-old ginseng in the new lines cultivated in Gyeonggi for development of new lines of Ginseng. Methods and Results : Eumseong 13, 14 and 15, which are two-years-old seedling in the new line ginseng were transplanted in 7 lines × 9 rows (70 plants)/1.62㎡ in 2015 along with Gumpoong and Yeonpoong as the control lines while Eumseong 16 and 17 as well as Chunpoong as the control line were transplanted in the same way in 2016. The ginseng shading was installed with the front post of 170 ㎝ high and the rear post of 100 ㎝ high using the rear line while as the sun blocking material, the aluminum shade plate was used. As for the new growth lines of 3 and 4-years ginseng in the new growth line, the aerial parts of the ginseng and underground part of ginseng were examined. In addition, the physiological stress such as the leaf discoloration, rusty root and root rot as well as the resistance against the disease were examined. It was found out that as for the aerial parts of 3-years-old ginseng in test line, Eumseong 16 and 17 were better in the growth than the control lines were while in 4 years old ginseng, Eumseong 13 and 14 were better in the growth than Gumpoong as the control line was. As for the root weight of the 4-years-old ginseng for the underground part, there was no significant difference compared with control line while in 3-years-old ginseng, Eumseong 16 and 17 were heavier. The leaf discoloration did not happen to both 3 and 4-years-old ginseng. As for the root rot, 3-years-old Eumseong 16 and 17 suffered less root rot in the same way as for the control line. 4-years-old Eumseong 14 and 15 had less root rot in the same way as for the control line. 3-years-old Eumseong 16 and 17 have less rusty root in the same way as the control line while as for 4-years-old ginseng, Eumseong 13, 14 and 15 showed a lot of rusty roots in the same way as the control line. Conclusion : Finally, considering the growth characteristics, physiological stress and root rusty of the aerial parts and underground parts of the ginseng, we selected Eumseong 16 and 17 as the excellent lines for 3-years-old ginseng.

Background : Ginseng is an important agriculture plant in Korea. However, plant yield is reduced by pathogens. Cylindrocarpon destructans and Fusarium solani are responsible for root-rot and replant failure of ginseng in Korea. Because of root rot pathogen, the productivity decreased and repeated cultivation is difficult. Methods and Results : The number of Cylindrocarpon destructans and Fusarium solani in soils can be measured by real-time PCR. This methode makes it possible to select of land for caltivation of ginseng. The specific primers of C. destructans and F. solani were synthesized from β-tubulin region. The equation of the standard curve between the colony forming unit(cfu) and the Ct value in the C. destructans was y (Ct value) = -1.608X (cfu) + 39.325. The equation of the standard curve between the colony forming unit (cfu) and the Ct value in the Fusarium solani was y (Ct value) = -1.608X (cfu) + 39.077. This method makes possible to rapidly exactly measure the number of pathogens in soil. C. destructans, a ginseng root rot fungus, was detected in soil samples of 32 (16%) in soil samples. 35.5% of paddy field, 34.3% of paddy field, 64.1% of field, and 65.6% of paddy field were found in perennial plant. Conclusion : As a result, the major causative agent of ginseng root rot was Cylindrocarpon and the onset density was 102 cfu/g in soil. There was no significant difference in density between fusarium and disease.

Background : This study was conducted to investigate the effect of soluble silicate and germanium on the characteristics of soil and growth in ginseng (Panax ginseng C. A. Meyer) cultivated in blue-white plastic houses. Methods and Results : Seedlings (n = 63 per 3.3 ㎡) of Korean ginseng cultivar were planted on April 10, 2015. Shading material of plastic house [8 m (W) × 3.5 m (H) × 50 m (L)] was blue-white vinyl. From May to September of each year, 1,000 times diluted sol. of germanium and silicate and these mixed solutions were drenched once a month. The chemical properties of the soil are as follows : pH, EC, organic content, and P2O5 of the soil were within the proper range, and the Mg content of the Ex-cations was lower than the standard value in 3 treatments except treatment of germanium 1,000 times. The total nitrogen content was 0.13 - 0.14%, which was higher than the optimum value. The number of soil microorganisms (Actinomycetes etc.) was higher in the treatment than in the non-treatment of inorganic components. The photosynthetic rate of ginseng leaves was 2.25 μmole CO2/㎡/s in the non-treatment and 2.91 to 3.17 μmole CO2/㎡/s in the inorganic treated. The growth characteristics of the aerial parts (leaf and stem) of the ginseng plants were generally better than that of non-treatment. Especially, in the treatment with silicate 1,000 times showed better growth, leaf area and leaf width growth. The growth of the underground part (root weight etc.) were also better than non-treatment. Specially, at 1,000 ppm treatment with soluble silicate, the root length and diameter were longer and the weight was was 72.2 g per plant. The ginsenoside content of each treatment is under analysis. The disease incidence (Alternaria panax etc.) rate was 20.1% in the untreated and 6.4% to 10.0% in the inorganic components treatment. Conclusion : By soil drench of inorganic compononts such as soluble silicate in ginseng blue-white plastic house cultivation, the growth of the aerial and root parts in ginseng were more improved than non-treatment. There are a lot of soil microorganism and less disease.

Background : The cultivation method of ginseng (Panax ginseng C. A. Meyer) has been introduced not only in the existing shading facilities but also in the cultivation method using the rain shelter house. In addition, direct seedling cultivation of ginseng is increasing in order to save labor. Ginseng cultivation area in the northern area is increasing with the disappearance of first planted field. Proper shading method in the northern ares is needed to grow direct grown ginseng using rain forest house. Methods and Results : Shading method using rain shelter house was Polyethylene film with layered polyethylene net 75%, blue-white duplicated PE film 85%, blue-white duplicated PE film 90%. Plant materials is 5-years-old Ginseng using direct seedling cultivation. In order to select proper shading materials of the rain shelter house in northern area, we investigated photosynthetic properties and growth of 5-years-old ginseng in rain shelter house. The temperature and humidity were slightly different between the traditional conventional shade facility and the rain shelter house, but the light intensity of the shading facility tended to decrease with the passage of time. The difference in shading method in rain shelter house was the highest at polyethylene film with layered polyethylene net 75%. As a result of the growth characteristics of the top part, 90% of blue-green double-sided film showed the greatest growth with 89.8 ± 1.5. The difference in top part between rain shelter house and shading facility is about 23 ㎝. Conclusion : Although the above growth characteristics of the ginseng shows this tendency, the root growth characteristics of the ginseng must be further observed.