2. Materials and methods2.1. Plant

2. Materials and methods
2.1. Plant material
Seeds of Kosteletzkya pentacarpos were issued from a field plantation in Jinhai Agricultural Experimental Farm of Yancheng (Jiangsu Province) and sown in trays filled with a perlite vermiculite mix (1:3 v/v) moistened regularly with a half-strength modified Hoagland nutrient solution. Seedlings were grown in a phytotron under a 12-h photoperiod (mean light intensity (PAR)=150molm−2 s−1 provided by Osram Sylvania (Dan-vers, MA) fluorescent tubes (F36W/133-T8/CW) with 27◦C/23◦C day/night temperature and 70%/50% atmospheric humidity). Young seedlings were adapted to a nutrient film technique (NFT) device consisting in an 8 m long and 0.25 m broad gully with a slop of 1.5%. The nutrient solution contained the following chemicals (in mM): 2.0 KNO3, 1.7 Ca(NO3)2, 1.0 KH2PO4, 0.5 NH4NO3, 0.5 MgSO4 and (in M) 17.8 Na2SO4, 11.3H3BO3, 1.6 MnSO4, 1 ZnSO4, 0.3 CuSO4, nevertheless rather expensive and require specific facilities. Any alternative aiming to reduce the initial level of water contamination may therefore help to reduce the cost of waste water treatment. Biosorption consists in the use of biological material for retention of heavy metals or organic pollutants. It appears as a cost-effective strategy to reduce water contamination by heavy metals (Pehlivan et al., 2009; Krishnani et al., 2008). Several types of biological material such as nutshell (Vaghetti et al., 2009), fungi (Sari and Tuzen, 2009; Vimala and Das, 2009), fern (Ponce et al., 2015), barks (Astier et al., 2010), straws (Pehlivan et al., 2009) and algae (Ibrahim, 2011) have been tested for this purpose and most of them show, to some extent, an ability to fix heavy metals.
Salt marshes are challenging environments for aquatic and semi-aquatic life. Plant species that are adapted to those environments are frequently exposed to high salinity and high concentrations of organic and inorganic pollutants (Cambrollé et al., 2012). The use of plant roots for biosorption is of special interest since it could help in the identification of a whole plant system that could be efficiently used for rhizofiltration purposes in constructed 0.03 (NH4)6Mo7O24 and 14.5 Fe-EDDHA. Minimum temperatures were 16–18◦C and daily maxima were 24–28◦C. Natural light was supplemented by PHILIPS lamps (Philips Lighting S.A., Brussels, Belgium) (HPLR 400 W) in order to maintain a light irradiance of 300molm−2 s−1 (PAR) at the top of the canopy. Seedlings were laterally adapted in specific orifices to the gully, with the root system inward. Gullies were then closed with a dark plastic sheet to avoid algae contamination and solution evaporation. Fifteen plants were placed at equal distances in the four gullies. A 50 L tank behind each gully was used to supply nutrient solution at a flow of 3Lmin−1 generated by an Eheim 1260 circulating pump. Nutrient solution was renewed each week but was daily controlled for pH stability. Gullies were distributed in a greenhouse under natural light, and temperature conditions as stated above. Humidity ranged between 48 and 70%. Environmental conditions were daily recorded by a Hobo® Onset Computer (Burne, MA, USA) and no significant difference was recorded between the gullies.
Plants were grown in the absence (0NaCl) or in the presence (+NaCl) of 50 mM NaCl, and these plants were not exposed to heavy metals during the 16 weeks growing period. At harvest, the whole root system from 8 plants per growing conditions were collected, thoroughly washed in sterile deionized water, air-dried for 48 h and pooled. Roots were then cut with scissor in small segments no longer than 3 cm and then dried again in an oven at 37◦C, to reach final water content lower than 8%. Tissues were ground with a blender (Waring Laboratory) and then in a mortar and a pestle in the presence of liquid nitrogen and a small amounts of washed and calcined silicon dioxide (Sigma-Aldrich). The obtained fine powder was then used for all subsequent biosorption experiments.
2.2. Characterization of the root powder
The swelling index of the powder was determined according to Ghanem et al. (2010) on a half gram of powdered material incubated in a 25 mL ground glass stoppered cylinder graduated over a height of 130 mm in 0.5 mL divisions. The powder was moistened with 1 mL of ethanol (96% v/v), distilled water was added up to 25 mL, and the cylinder was closed and shaken over 20 min at room temperature. It was then allowed to stand for 2 h. The volume occupied by the disintegrating agent including adhering mucilage was recorded. The crude mucilage was extracted from roots (5 g DW) with 500 mL water under stirring for 40 h at room temperature (Classen and Blaschek, 1998). The extract was centrifuged at 20,000g during 5 min at 4◦C. The aqueous supernatant was concentrated to 150 mL by evaporation and the mucilage solution was poured into 600 mL of a mixture