%0 Generic %A Watanabe, Toshihiro %A Maejima, Eriko %A Yoshimura, Tomoko %A Urayama, Masaru %A Yamauchi, Aiko %A Owadano, Masako %A Okada, Ryosuke %A Osaki, Mitsuru %A Kanayama, Yoshinori %A Shinano, Takuro %D 2016 %T The Ionomic Study of Vegetable Crops %U https://plos.figshare.com/articles/dataset/The_Ionomic_Study_of_Vegetable_Crops/3509138 %R 10.1371/journal.pone.0160273 %2 https://ndownloader.figshare.com/files/5574740 %2 https://ndownloader.figshare.com/files/5574746 %2 https://ndownloader.figshare.com/files/5574758 %K Solanum lycopersicum %K field conditions %K nonedible parts %K Vegetable Crops Soil %K ionomic profile %K ionomic techniques %K xylem transfer %K calcium accumulation %K calcium concentration %K plant ionomics %K mineral accumulation %K ionomic profiles %K vegetable crop species %K eggplant fruit %K Ionomic Study %X

Soil contains various essential and nonessential elements, all of which can be absorbed by plants. Plant ionomics is the study of the accumulation of these elements (the ionome) in plants. The ionomic profile of a plant is affected by various factors, including species, variety, organ, and environment. In this study, we cultivated various vegetable crop species and cultivars under the same field conditions and analyzed the level of accumulation of each element in the edible and nonedible parts using ionomic techniques. The concentration of each element in the edible parts differed between species, which could be partly explained by differences in the types of edible organs (root, leaf, seed, and fruit). For example, the calcium concentration was lower in seeds and fruit than in other organs because of the higher dependency of calcium accumulation on xylem transfer. The concentration of several essential microelements and nonessential elements in the edible parts also varied greatly between cultivars of the same species, knowledge of which will help in the breeding of vegetables that are biofortified or contain lower concentrations of toxic elements. Comparison of the ionomes of the fruit and leaves of tomato (Solanum lycopersicum) and eggplant (S. melongena) indicated that cadmium and boron had higher levels of accumulation in eggplant fruit, likely because of their effective transport in the phloem. We also found that homologous elements that have been reported to share the same uptake/transport system often showed significant correlation only in a few families and that the slopes of these relationships differed between families. Therefore, these differences in the characteristics of mineral accumulation are likely to affect the ionomic profiles of different families.

%I PLOS ONE