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Parsley is an herb/vegetable rich in nutritional compounds such as carbohydrates, vitamins, protein, crude fiber, minerals (especially potassium), phosphorus, magnesium, calcium, iron, and essential oils. Limited information is available in the literature on the quality of parsley roots depending on the cultivation technology used in the form of macronutrients and micronutrients, preparations to stimulate plant growth and development, as well as plant-protection products. A three-year study was undertaken to determine the effect of applying mineral fertilization with nitrogen, including magnesium on the nutritional value of parsley roots in terms of the content of ascorbic acid, total and reducing sugars, and minerals: (total N, K, Mg, Ca). The research material was the root of Petroselinum crispum ssp. tuberosum from an experiment where nitrogen was applied in soil at (0, 40, 80, 120 kg N ha−1) and magnesium at (0, 30 kg MgO ha−1). Nitrogen fertilization increased the nutritional value in terms of total and reducing sugars, as well as total N and Ca content. Applied magnesium fertilization caused a significant increase in the content of all tested nutrients. The most total sugars (127.7 g kg−1 f. m.), reducing sugars (16.8 g kg−1 f. m.), and total N (12.13 g kg−1 d. m.) were accumulated by roots from the object where nitrogen was applied at a maximum rate of 120 kg N ha−1, including magnesium. On the other hand, for the content of K (19.09 g kg−1 d. m.) in the roots, a dose of 80 N ha−1 was sufficient. For ascorbic acid (263.2 g kg−1 f. m.) and Ca (0.461 g kg−1 d. m.), a dose of 40 kg N ha−1 with a constant fertilization of 30 kg MgO ha−1 was sufficient. When applying high doses of nitrogen, lower doses of magnesium are recommended. This is sufficient due to the high nutritional value of parsley roots. Due to the worsening magnesium deficiency in soils in recent years, the use of this nutrient in the cultivation of root vegetables is as justified and timely as possible. Quality-assessment studies of root vegetables should be continued with higher amounts of magnesium fertilization. Different ways of applying magnesium in parsley cultivation should also be tested.
Parsley is an herb/vegetable rich in nutritional compounds such as carbohydrates, vitamins, protein, crude fiber, minerals (especially potassium), phosphorus, magnesium, calcium, iron, and essential oils. Limited information is available in the literature on the quality of parsley roots depending on the cultivation technology used in the form of macronutrients and micronutrients, preparations to stimulate plant growth and development, as well as plant-protection products. A three-year study was undertaken to determine the effect of applying mineral fertilization with nitrogen, including magnesium on the nutritional value of parsley roots in terms of the content of ascorbic acid, total and reducing sugars, and minerals: (total N, K, Mg, Ca). The research material was the root of Petroselinum crispum ssp. tuberosum from an experiment where nitrogen was applied in soil at (0, 40, 80, 120 kg N ha−1) and magnesium at (0, 30 kg MgO ha−1). Nitrogen fertilization increased the nutritional value in terms of total and reducing sugars, as well as total N and Ca content. Applied magnesium fertilization caused a significant increase in the content of all tested nutrients. The most total sugars (127.7 g kg−1 f. m.), reducing sugars (16.8 g kg−1 f. m.), and total N (12.13 g kg−1 d. m.) were accumulated by roots from the object where nitrogen was applied at a maximum rate of 120 kg N ha−1, including magnesium. On the other hand, for the content of K (19.09 g kg−1 d. m.) in the roots, a dose of 80 N ha−1 was sufficient. For ascorbic acid (263.2 g kg−1 f. m.) and Ca (0.461 g kg−1 d. m.), a dose of 40 kg N ha−1 with a constant fertilization of 30 kg MgO ha−1 was sufficient. When applying high doses of nitrogen, lower doses of magnesium are recommended. This is sufficient due to the high nutritional value of parsley roots. Due to the worsening magnesium deficiency in soils in recent years, the use of this nutrient in the cultivation of root vegetables is as justified and timely as possible. Quality-assessment studies of root vegetables should be continued with higher amounts of magnesium fertilization. Different ways of applying magnesium in parsley cultivation should also be tested.
The study aimed to determine the level of selected indicators of nitrogen metabolism in vegetables from organic (organic food store) and conventional (supermarket and local market) crops. Nitrates, total chlorophyll content, and the activity of the nitrate biosynthesis pathway enzymes—nitrate reductase (NR) and glutamine synthetase (GS)—were determined in the leaves of selected species from different plant families. The research material consisted of dill, carrot, celery, beet, onion, Chinese and white cabbage, and rocket. The nitrate content was within the permissible limits, except for vegetables bought at a local market. In most cases, no significant differences in the level of nitrates between organic and conventional farming were observed. The analyses revealed the highest nitrate content in dill [2.16 mg × g−1] and the lowest in onions [0.06 mg × g−1] from conventional crops. The enzyme activities were related to the level of nitrates. The analysed species differed in phenolic compounds, ascorbate levels, and total antioxidant capacity (TCA). Positive correlations were found between TCA and antioxidants.
Cucumber (Cucumis sativus L.) F1 hybrids are grown commercially in open-field or greenhouse conditions. Hybrids are well adapted to these settings due to directed breeding. In protected cultivation systems, a small rhizosphere volume and intensive, continuous fertigation predispose the roots to waterlogging (WL) conditions and potentially to hypoxia. However, high productivity is expected and achieved under these conditions. The aim of this study was to identify traits that play a role in this surprising behavior. Initial observations revealed the presence of a significantly higher number of adventitious roots (ARs) in three greenhouse (7–14) vs. three open-field cultivars (less than two) grown under normal conditions. Further on, two contrasting representative hybrids typically grown in open-field and in greenhouse conditions were subjected to WL stress. Declining oxygen levels in the media and increased alcohol dehydrogenase activity (ADH) in the roots were experienced during the WL treatment in both hybrids, with anaerobic metabolism triggered less intensively (~4-fold less ADH activity) in the greenhouse-type ‘Oitol’. The induction characteristics of cysteine oxidase (CysOx) genes, key components of the hypoxia sensing pathway, were used to confirm the hypoxic stress experienced by the roots. The lower extent of upregulation in CysOx genes expression agreed with the milder level of hypoxic stress in the roots of ‘Oitol’ than in ‘Joker’. The more efficient induction of AR formation with a ~50% increase upon waterlogging stress was found to be a prominent trait in ‘Oitol’, apparently helping root internal aeration and mitigating hypoxia. The shoot growth of neither hybrid was set back by hypoxic root conditions. ‘Joker’ plants maintained the same growth rate as that of the control, while the growth of ‘Oitol’ accelerated when its root system was flooded with nutrient solution. Acclimation processes to hypoxia were proposed to explain the lack of growth retardation in both varieties. This corresponded well with a general abundance of AR development in greenhouse-type (slicing) cucumbers that are typically cultivated in soilless systems.
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