칠성초에 역병 저항성을 도입한 칠복1호에 베트남 도입 풋마름병 저항성 계통을 교배하여 육성한 및 에서부터 및 까지 역병-풋마름병 복합 저항성 선발을 2009년도와 2010년도에 걸쳐 수행하였다. 매 세대 역병을 접종하여 저항성을 평가하여 선발하고 선발개체에 풋마름병을 접종하여 감염되는 개체는 도태하였다. 역병에 대한 저항성은 선발과 함께 현저히 향상되었으며, 선발계통들은 역병 저항성으로 판매되고 있는 교배종 '무한질주'와 비슷한 수준의 저항성을 나타내었다. 선발개체를 칠복CMS-A라인에 교배를 하여 의 임성을 보고 화분친의 CMS-Rf유전자형을 검정하였다. 대부분Nrfrf로 고정되고, 칠복 KC995, 칠복 KC1009 조합의 일부 개체가 이형(heterozygote) 상태인 것으로 확인되었다.

본 연구는 토마토 수경재배에서 풋마름 병원균의 분포와 침입 및 전파경로를 구명하여 풋마름병 방제의 기초 자료를 얻고자 수행하였다. 배양액 재배시스템에서 토마토 풋미름병의 발생정도별로 배양액탱크, 배지, 폐액에서 병원균의 밀도를 검정한 결과 20% 정도 발병된 포장의 폐액에서는 19,000cfu/mL의 밀도로 검출되었으며 연작연수가 많을수록 병 발생이 심하였다. 토마토 펄라이트 수경재배시스템에서 토마토 풋마름병의 발생전파 과정은 최초 발생지점으로부터 좌우로 급속히 전파되었다. 토마토 풋마름병 발생포쟁에서 병원균의 유입경로를 추적한 결과 육묘 중에 감염되는 경우와 웹스 주변의 이병된 토양에서 감염되는 경우로 크게 두 가지 방법으로 유입되는 것으로 생각된다. 또한 시판용 토마토 종자에서는 풋마름병원균이 검출되지 않았다.

This study aimed to evaluate 105 tomato accessions conserved in National Agrobiodiversity Center regarding their resistance to Ralstonia solanacearum, a soil-borne vascular bacterium that causes lethal wilt diseases of a wide range of crops worldwide. All the accessions are Solanum lycopericum var. lycopersicum including cultivar or breeding lines. At the four leaf stage, the seedlings were inoculated by drenching the soil with the bacterial suspension concentrated of 108 CFU/ml. Plant roots were wounded before inoculation by cutting with the knife. Seven accessions including IT 32899 were rated as resistant, while other 98 accessions were rated as susceptible. IT 32899 scored 0.1 of disease rate and 0.7 of disease index. The selected accessions will be used as a material to reveal the mechanism of wilt tolerance and to identify the host gene involved in defense response.

For the field application of dielectric barrier discharge plasma reactor in nutrient solution culture, a filtration-DBD (dielectric barrier discharge) plasma reactor was investigated for the Ralstonia solanacearum which causes bacterial wilt in aquiculture. The filtration-DBD plasma reactor system of this study was consisted of filter, plasma reactor, reservoir. The DBD plasma reactor consisted of a quartz dielectric tube, discharge electrode (inner) and ground electrode (outer). The experimental results showed that the inactivation of R. solanacearum with filter media type in filter reactor ranked in the following order: anthracite > fiber ball > sand > ceramic ball > quartz ceramic. In filtration + plasma process, disinfection effect with the voltage was found to small. In disinfection time of 120 minutes, residual R. solanacearum concentration was 1.17 log (15 CFU/mL). When the continuous disinfection time was 120 minute, disinfection effect was thought to keep the four days. In sporadic operation mode of 30 minutes disinfection - 24 hours break, residual R. solanacearum concentration after five days was 0.3 log (2 CFU/ mL). It is considered that most of R. solanacearum has been inactivated substantially.

Effect of improvement of the dielectric barrier discharge (DBD) plasma system on the inactivation performance of bacteria were investigated. The improvement of plasma reactor was performed by combination with the basic plasma reactor and UV process or combination with the basic plasma reactor and circulation system which was equipped with gas-liquid mixer. Experimental results showed that tailing effect was appeared after the exponential decrease in basic plasma reactor. There was no enhancement effect on the Ralstonia Solanacearum inactivation with combination of basic plasma process and UV process. The application of gas-liquid mixing device on the basic plasma reactor reduced inactivation time and led to complete sterilization. The effect existence of gas-liquid mixing device, voltage, air flow rate (1 ～ 5 L/min), water circulation rate (2.8 ～ 9.4 L/min) in gas—liquid mixing plasma, plasma voltage and UV power of gas—liquid mixing plasma+UV process were evaluated. The optimum air flow rate, water circulation rate, voltage of gas-liquid mixing system were 3 L/min, 3.5 L/min and 60 V, respectively. There was no enhancement effect on the Ralstonia Solanacearum inactivation with combination of gas-liquid mixing plasma and UV process.

A dielectric barrier discharge (DBD) plasma reactor was investigated for the inactivation of Ralstonia Solanacearum which causes bacterial wilt in aquiculture. The DBD plasma reactor of this study was divided into power supply unit, gas supply unit and plasma reactor. The plasma reactor consisted of a quartz dielectric tube, discharge electrode (inner) and ground electrode (outer). The experimental results showed that the optimum 1st voltage, 2nd voltage, air flow rate and pH were for 100 V (1st voltage), 15 kV (2nd voltage), 4 L/min, and pH 3, respectively. At a low 1st voltage, shoulder and tailing off phenomena was observed. The shoulder phenomenon was decreased as the increase of 1st voltage. R. Solanacearum disinfection in the lower air flow rate was showed shoulder and tailing off phenomenon because the active species generated less. Under optimum condition, shoulder and tailing off phenomenon was reduced. When the 2nd voltage was less than 7.5 kV, tailing off phenomenon was observed and this was not vanishes even though the increase of the disinfection time. The inactivation efficiency increased as the increase of air flow rate, however, the efficiency decreased when the air flow rate was above 4 L/min. R. Solanacearum disinfection at pH 3 showed somewhat higher than in pH 11. The pH effect of R. Solanacearum deactivation is less than the impact on other factor.