Attenuation of mercury phytotoxicity with a high nutritional level of nitrate in alfalfa plants grown hydroponically
Sandra Carrasco-Gil,
Cristina Ortega-Villasante,
Juan Sobrino-Plata,
Ángel Barón-Sola,
Rocío Millán,
Luis E. Hernández
Affiliations
Sandra Carrasco-Gil
Laboratory of Plant Physiology-Department of Biology/Research Centre for Biodiversity and Global Change, Universidad Autónoma Madrid, Darwin 2, Madrid ES28049, Spain; Centro de Investigaciones Energéticas, Medioambientales y Tecnológicas, Avd. Complutense, 22, Madrid 28040, Spain
Cristina Ortega-Villasante
Laboratory of Plant Physiology-Department of Biology/Research Centre for Biodiversity and Global Change, Universidad Autónoma Madrid, Darwin 2, Madrid ES28049, Spain
Juan Sobrino-Plata
Laboratory of Plant Physiology-Department of Biology/Research Centre for Biodiversity and Global Change, Universidad Autónoma Madrid, Darwin 2, Madrid ES28049, Spain
Ángel Barón-Sola
Laboratory of Plant Physiology-Department of Biology/Research Centre for Biodiversity and Global Change, Universidad Autónoma Madrid, Darwin 2, Madrid ES28049, Spain
Rocío Millán
Centro de Investigaciones Energéticas, Medioambientales y Tecnológicas, Avd. Complutense, 22, Madrid 28040, Spain
Luis E. Hernández
Laboratory of Plant Physiology-Department of Biology/Research Centre for Biodiversity and Global Change, Universidad Autónoma Madrid, Darwin 2, Madrid ES28049, Spain; Corresponding author.
Mercury (Hg) is one of the most dangerous pollutant heavy metals to the environment, which causes several toxic effects in plants upon accumulation, such as induction of oxidative stress. Nitrate (NO3) is the prevalent form to incorporate nitrogen (N) in higher plants, through its reduction to nitrite (NO2) by the enzyme nitrate reductase (NR). We studied the physiological alterations caused by Hg (0, 6 and 30 µM) in alfalfa plants grown at two different levels of NO3: low, (2 mM; LN), and high (12 mM; HN) for one week using a semi-hydroponic culture system. Several parameters of oxidative stress such as lipid peroxidation, chlorophyll content, biothiol concentration, and ascorbate peroxidase (APX) and glutathione reductase (GR) activities showed that HN plants were less affected by Hg. Nitrate reductase activity and NO3 concentration were also altered under Hg stress, with lower impact in plants nourished with high NO3. Our results highlight the importance of the NO3 nutritional status to improve tolerance to toxic metals like Hg.
