Evaluation of Grafted Tomatoes with Different Levels of Resistance of Rootstocks to TYLCV by Analyzing the Growth Characteristics,  Leaf-macronutrient Content,  and Chlorophyll Fluorescence

Hyewon Lee; Hyo Bong Jeong; Jun Gu Lee; Indeok Hwang; Deok Ho Kwon; Yul Kyun Ahn

doi:10.7235/HORT.20230049

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2023 Vol.41, Issue 5 Preview Page Next Page

Research Article

Evaluation of Grafted Tomatoes with Different Levels of Resistance of Rootstocks to TYLCV by Analyzing the Growth Characteristics, Leaf-macronutrient Content, and Chlorophyll Fluorescence 접목 토마토의 생육 특성, 엽 내 양분 함량 및 엽록소형광 분석을 통한 황화잎말림바이러스(TYLCV)에 대한 대목 성능 검정

31 October 2023. pp. 571-583

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Abstract

The grafting technique has widely been used with fruits and vegetables in an effort to increase productivity for long-term cultivation. For long-term cultivation, the result is increased vigor provided by the rootstock, which allows the scion to grow longer, even in the presence of a virus. This study was conducted to evaluate the performance of rootstocks having different TYLCV- resistance levels by comparatively analyzing the growth, yield, nutrient concentration in the petiole sap, and chlorophyll fluorescence in tomatoes grown via a hydroponics system. The domestic cultivars ‘HSF4’ and ‘BWM’ were used as the TYLCV-susceptible rootstocks, and ‘21LM’ and ‘21A701’ were used as the TYLCV-resistant rootstocks. The tomato variety ‘Red250’ was used as the TYLCV-resistant scion and the non-grafted control plants. The tomato plants were infected overall with TYLCV at ten weeks after transplanting. Grafted tomatoes on the TYLCV- resistant rootstocks ‘21A701’ and ‘21LM’ were vigorous, and the yields were 7,999g and 7,754g respectively, correspondingly higher by 25% and 22% than those using the TYLCV-susceptible rootstock ‘BWM’. Moreover, the growth strength of ‘21A701’ was highest compared to the others. The NO₃-N concentration of ‘21A701’ was highest at 1,211mg·L^-1, and that of ‘BWM’ was lowest at 835mg·L^-1at 36 weeks after transplanting. The K⁺ concentration of ‘21A701’ was highest at 4,050mg·L^-1, and the non-grafted case was lowest at 3,350mg·L^-1. The maximum quantum yield of the primary PSⅡ photochemistry (F_V/F_M) and the performance index based on the absorption (PI_ABS) of ‘21LM’ were highest at 0.803 and 2.990, respectively. The non-grafted samples were lowest at 0.739 and 1.422, respectively. The grafted plants on the TYLCV-resistant rootstocks had high vigor of the root system and greater mineral and water uptake levels, leading to an increased yield, likely due to the high concentrations of nutrients reaching the leaves and the high photosynthetic efficiency. The use of TYLCV-resistant rootstocks was required to improve the yields up to the late harvest stage. We concluded that tomato grafting onto TYLCV-resistant rootstocks can increase the uptake of mineral nutrition and the photosynthetic efficiency, thereby affecting plant growth and the fruit yield.

Keywords

growth strength

nutrient uptake

photosynthetic efficiency

plant vigor

Solanum lycopersicum L.

토마토 접목묘는 재배기술이 향상됨에 따라 장기재배를 위해 많이 사용되고 있을 뿐 아니라 토마토 바이러스에 대한 저항성을 가진 대목의 경우 바이러스에 감염되어도 접수 생육을 유지시켜 작기 후반까지 재배 가능하도록 돕는다. 본 연구는 수경재배 시 토마토 대목 종류에 따른 생육과 수량 차이, 엽병 분석 및 광합성 효율을 측정하여 국내 개발 대목의 성능과 TYLCV 저항성 수준을 검정하고자 수행하였다. 실험재료는 국내 개발 대목 중 TYLCV 감수성 계통으로 ‘HSF4’와 ‘BWM’을, TYLCV 저항성 계통으로 ‘21LM’과 ‘21A701’을 사용하여 접목한 처리구 4개와 TY 내병계 품종 ‘Red250’을 사용하여 접수와 비접목 처리구로 사용하였다. 모든 처리구는 정식 후 10주에 TYLCV 감염을 진단받고 정식 후 18주부터 수확이 시작되었다. TYLCV 저항성 대목을 사용한 ‘21A701’와 ‘21LM’ 처리구는 주당 총 수량이 7,999g과 7,754g으로 TYLCV 감수성 대목을 사용한 ‘BWM’보다 각각 25%와 22% 높았고 생장강도는 ‘21A701’이 처리구 중 가장 높았다. 정식 후 36주의 엽병 즙액 내 NO₃-N 농도는 ‘21A701’이 1,211mg·L^-1로 가장 높았고 ‘BWM’이 835mg·L^-1로 가장 낮았으며, K⁺ 농도는 ‘21A701’이 4,050mg·L^-1로 가장 높았고 비접목 처리구가 3,350mg·L^-1로 가장 낮았다. 정식 후 36주에 ‘21LM’의 F_V/F_M과 PI_ABS는 각각 0.803과 2.990으로 높았고 비접목 처리구는 각각 0.739와 1.422로 낮았다. TYLCV 저항성 대목을 사용한 접목 처리구는 바이러스에 감염되었음에도 뿌리 활력이 강해 생육 후기까지 양분 흡수와 광합성 효율이 높아 접수의 생육을 유지해 총 수량이 많은 것으로 판단된다. 처리 간 생육과 수량의 정도가 엽병 즙액 내 양분 함량과 엽록소형광 수치와 비례하여 체 내 영양진단과 광합성 효율 측정을 통해 대목의 성능을 검정할 수 있는 것으로 판단된다.

키워드

광합성 효율

생장강도

양분 흡수

작물 세력

Solanum lycopersicum L.

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Information

Publisher :KOREAN SOCIETY FOR HORTICULTURAL SCIENCE
Publisher(Ko) :원예과학기술지
Journal Title :Horticultural Science and Technology
Journal Title(Ko) :원예과학기술지
Volume : 41
No :5
Pages :571-583
Received Date : 2022-12-30
Revised Date : 2023-04-18
Accepted Date : 2023-05-05
DOI :https://doi.org/10.7235/HORT.20230049

Horticultural Science and Technology 원예과학기술지 ISSN:1226-8763(Print) 2465-8588(Online)

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