1. Urea accounts for similar to 50% of global nitrogen (N)-based fertiliser; however, little is known of the factors regulating its distribution and abundance in freshwaters. Improved understanding of urea biogeochemistry is essential because its use as fertiliser is expected to double by 2050 and because pollution with urea can promote outbreaks of toxic cyanobacteria in phosphorus (P)-rich lakes in regions with intensive agricultural or urban development. 2. Biweekly measurements of urea concentration and diverse limnological variables (water chemistry, hydrology, algae, zooplankton) were taken during two summers (2008, 2009) in a chain of seven productive lakes within a 52 000-km2 catchment in central Canada to quantify environmental and anthropogenic correlates of temporal and spatial patterns of urea occurrence. 3. Mean (+/-SD) urea concentrations varied between 29 +/- 14 and 132 +/- 65 mu g N L-1, generally increased from headwater to downstream sites and represented 1050% of bioavailable N (as sum of , and urea). Principal components analysis demonstrated that urea concentrations were elevated in agriculturally impacted lakes with abundant dissolved organic and inorganic nutrients (N, P, C) and low O2 concentrations, but were not correlated consistently with plankton abundance or community composition. Urea concentrations were more than twofold greater in lakes receiving N from cities than in agriculturally affected basins, despite low summer concentrations of urea in tertiary-treated urban effluent (c. 50% of lake values). Multiple regression models evaluated using Akaike Information Criterion showed that mean water-column O2 concentration was the single best predictor of in situ urea concentrations (r2 = 0.91, P = 0.002), but that urea concentrations were also correlated significantly with changes in longitudinal position and Secchi depth and with concentrations of , non-urea dissolved organic N (DON) and dissolved inorganic carbon. 4. Additional seasonal surveys of up to 69 closed-basin lakes within a 100 000-km2 region during 2004 and 2008 revealed that urea was abundant in 100% of measured sites and exhibited concentrations (81 +/- 48 mu g N L-1) similar to those observed in lakes with surface drainage (58 +/- 38 mu g N L-1). Further, non-urea DON accounted for 5099% of the total dissolved N pool in both open- and closed-basin lakes. 5. When combined with an extensive literature review and previous mass-budget analyses of the study lakes, these findings allowed the development of a first-generation model of the mechanisms regulating urea content of P-rich lakes of central North America. In this model, water-column concentrations of urea are predicted to be regulated mainly by algal decomposition in anoxic environments (sediments, hypolimnion), followed by redistribution into surface waters. Consequently, anthropogenic activities can increase the urea content of lakes by stimulating primary production, sedimentation and deepwater anoxia and by increasing influx of undegraded urea from agricultural and urban sources.

• 出版日期2012-6