MACROINVERTEBRATE PRODUCTION AND FOOD WEB ENERGETICS IN AN INDUSTRIALLY CONTAMINATED STREAM

This study examines secondary production and periphyton–invertebrate food web energetics at two sites in an industrially contaminated, nutrient‐enriched stream. Secondary production data and data from the literature were used to calculate potential amounts of mercury transferred from periphyton to chironomid larvae and into terrestrial food webs with emerging adults. The nutritional quality of periphyton was characterized using energy content, chlorophyll a , protein, ash‐free dry mass (AFDM), and percentage of organic matter. Chironomid larvae (Orthocladiinae: Cricotopus spp . ) comprised 96% of all macroinvertebrates collected from stones at the two sites. Cricotopus production was extremely high: production was 59.5 g AFDM·m −2 ·yr −1 at the site upstream of a 1‐ha settling basin and 32.4 g AFDM·m −2 ·yr −1 at the site below the basin. Apparent differences in annual secondary production were associated with reduced organic content (i.e., nutritional quality) of the periphyton matrix under different loading of total suspended solids. The periphyton matrix at both sites was contaminated with inorganic (Hg(II)) and methyl (MeHg) mercury. The amount of Hg(II) potentially ingested by Cricotopus was calculated to be 49 mg Hg(II)·m −2 ·yr −1 at the upstream site and 19 mg Hg(II)·m −2 ·yr −1 at the downstream site. Mercury ingestion by Cricotopus at the downstream site was calculated to be 2% of the estimated annual deposition of particulate‐bound Hg(II) to the stream bed. Emergence of adult Cricotopus was calculated to remove 563 μg Hg(II)·m −2 ·yr −1 from the stream at the upstream site and 117 μg Hg(II)·m −2 ·yr −1 at the downstream site, which amounted to 4.1 g Hg(II)/yr for the 2.1‐km reach of stream included in this study. The ratio of metal export in emergence production to surface area for the study stream was 10 to 10 3 times higher than ratios calculated for lakes using data from the literature. This study is the first well‐documented example of extremely high aquatic insect production in an industrially contaminated, nutrient‐enriched stream, and it highlights the application of production measurements to examine the role of aquatic insect production in the trophic transfer of energy and persistent contaminants in aquatic food webs and into terrestrial food webs.