Abstract
Selenium biofortification of lettuce plants was studied for two rates (5 and 10 mg kg−1 soil) of either selenate or selenite and for the effect of 5% w/w biochar addition. Lettuce seedlings were grown in pots containing 1 kg of a calcareous soil. Twelve weeks later, the plants were harvested and selenium (Se), phosphorus (P), and sulfur (S) concentrations were determined in heads and roots. Plant growth characteristics were measured and plant biometrics were assessed by NDVI, NDRE, and SPAD measurements. The highest Se concentration of 315.19 mg kg−1 D.W. and the highest amount of Se taken up by plants (950.5 μg/pot) were observed for the low selenate rate with biochar. The corresponding values for selenite treatments were an order of magnitude lower. Although in general, minor to severe toxicity symptoms occurred with selenium application in no biochar treatments (except selenite low rate), the addition of biochar secured plant growth and increased S and P concentrations in plants, regulating Se uptake by plants at high selenite rate and allowing maximum plant uptake at the low selenate rate. To propose an appropriate Se fertilization rate, the fate of excess selenates in the soil environment should be examined and experimentation under soil conditions is necessary.
Highlights
Selenium (Se), at low concentrations, is an essential element for the normal growth and development of living organisms due to its crucial contribution to many biochemical reactions [1]
The highest D.W. was observed for the treatments of 5 mg kg−1 soil and 10 mg kg−1 soil in the presence of biochar, while the lowest was with the addition of 10 mg kg−1 soil without biochar application
Biochar application increased D.W. of plants, while no significant differences in D.W. were found between the treatments where biochar was applied, regardless of the Se concentration
Summary
Selenium (Se), at low concentrations, is an essential element for the normal growth and development of living organisms due to its crucial contribution to many biochemical reactions [1]. It regulates many functions in humans and animals such as antioxidant activity [2], proper functioning of the thyroid gland [3], and prevention of carcinogenesis [4]. There is a positive effect of Se in plants as it enhances the tolerance to potentially toxic elements and pathogen stress and increases yield production [5,6,7], at proper concentrations.
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