Pilot-scale duckweed-CO wastewater bioremediation system: a synergistic approach for nutrient removal, carbon capture, and biomass production.

This study presents a pilot-scale duckweed-based wastewater treatment system enhanced with CO fertilization to improve nutrient removal, CO capture, and biomass productivity. Three strains of Landoltia punctata were cultivated continuously for five months. In spring, CO supplementation significantly increased the biomass yield and starch and protein productivity (by more than 12.2, 2.4 and 3.5 g/m/d, respectively), representing increases of 189-259 %, 1,108-2,330 % and 143-166 %, respectively, compared with those of the control group. The removal rates of total nitrogen (TN) and total phosphorus (TP) increased by 28-71 % and 120-148 %, respectively, whereas CO capture improved by 196-264 %. Enhanced nutrient recovery was also observed, with N recovery increasing from 0.20-0.25 to 0.54-0.61 g/m/d and P from approximately 0.05 to 0.11 g/m/d. Enzyme activity and transcriptome analyses of strain 0202, which presented the highest starch content, revealed that CO fertilization upregulated key starch biosynthesis genes (ADP-glucose pyrophosphorylase (AGPase), Granule-bound starch synthase (GBSS), and Soluble Starch Synthase (SSS)), contributing to increased starch accumulation. It also promoted glutamine synthetase expression, increasing nitrogen assimilation and shifting nitrogen removal from microbial nitrification to duckweed uptake. As a result, microbial nitrification decreased significantly, and the proportion of NH-N removed via plant assimilation increased to over 69 %. These findings demonstrate that coupling CO fertilization with duckweed cultivation is an effective and scalable approach for wastewater treatment, carbon fixation, and renewable bioresource production.