Sesuvium portulacastrum-Mediated Removal of Nitrogen and Phosphorus Affected by Sulfadiazine in Aquaculture Wastewater

Plant-based removal of nitrogen (N) and phosphorus (P) from water bodies is an important method for remediation of aquaculture wastewater. In order to acquire knowledge as to how antibiotic residues in wastewater might affect the microbial community and plant uptake of N and P, this study investigated N and P removal by a coastal plant Sesuvium portulacastrum L. grown in aquaculture wastewater treated with 0, 1, 5, or 50 mg/L sulfonamide antibiotics (sulfadiazine, SD) for 28 days and compared the microbial community structure between the water and rhizosphere. Results showed that SD significantly decreased N removal rates from 87.5% to 22.1% and total P removal rates from 99.6% to 85.5%. Plant fresh weights, root numbers, and moisture contents as well as activities of some enzymes in leaves were also reduced. SD changed the microbial community structure in water, but the microbial community structure in the rhizosphere was less affected by SD. The microbial diversity in water was higher than that in the rhizosphere, indicating microbial community differences. Our results showed that the commonly used antibiotic, SD, in aquaculture can inhibit plant growth, change the structure of microbial community, and reduce the capacity of S. portulacastrum plants to remove N and P from wastewater, and also raised alarm about detrimental effects of antibiotic residues in phytoremediation of wastewater.

In Vitro Shoot Culture of Sesuvium portulacastrum: An Important Plant for Phytoremediation

Sesuvium portulacastrum L., a member of the family Aizoaceae, is an important coastal halophyte. Due to its adaptability to salinity and heavy metals, S. portulacastrum has now been widely used for the phytoremediation of saline soils and wastewater and the protection of the coast from erosion. The increasing use of this plant requires a large number of propagules. Stem cutting propagation and seed germination cannot meet this demand, and such propagations can initiate and spread diseases. A recent occurrence of Bipolaris sesuvii J.Z. Zhang and Gibbago trianthemae E.G. Simmons in S. portulacastrum resulted in the substantial loss of the plants during the remediation of aquaculture wastewater. Thus, there is an urgent need for establishing efficient methods of propagating disease-free starting materials. In the present study, we evaluated different growth regulators in the induction of axillary shoots from nodal explants cultured on Murashige and Skoog medium and identified that zeatin (ZT) and α-naphthaleneacetic acid (NAA) was an appropriate combination for inducing high numbers of axillary shoots. The nodal explants were then cultured on MS medium supplemented with different concentrations of ZT and NAA, and the combination of ZT at 1.0 mg L−1 and NAA at 0.3 mg L−1 induced more than 12 axillary shoots per explant. The axillary shoots were excised to produce microcuttings or microshoots, which were rooted on half-strength MS medium supplemented with different concentrations of indole-3-acetic acid (IAA) or indole-3-butyric acid (IBA). The results showed that IBA at 0.6 mg L−1 induced 91.7% of the microcuttings to root with root numbers of over 36 per cutting. The rooted plantlets were healthy and true-to-type and grew vigorously in plug trays or plastic containers with a 100% survey rate in a greenhouse. Thus, this established protocol could be used for the rapid propagation of genetically identical and disease-free plants of S. portulacastrum for phytoremediation and the protection of shoreline soils from erosion.

Total Phosphorus and Reactive Phosphate Removal from Aquaculture Wastewater using Calcined Eggshell

Phosphorus is the key nutrient in fish feed, and it has been one of the major soluble nutrients found in aquaculture wastewater (AW). This work aims to evaluate the removal of Total Phosphorus (TP) and Reactive Phosphate (PO4 3-) via adsorption in batch studies using thermally calcined eggshell as adsorbent. The effect of calcination temperature (700 – 1000°C), particle size and holding time were investigated. The screening phase showed that calcined eggshell at 800 °C for 30 minutes was the most suitable condition. Characterization of adsorbents revealed that crystalline structure and functional groups were responsible for the TP and PO4 3- removal using calcined eggshell from AW. Adsorption equilibrium was attained after 15 min with the dosage of 0.2 g of the optimized adsorbent, capable of removing more than 97 % of TP and PO4 3- from AW. This finding has proven the ability of calcined eggshell waste as a potential phosphorus adsorbent from liquid effluents.