A Tropical Paradox - High Mercury Deposition, but Low Mercury Bioaccumulation in Northeastern Puerto Rico

At a "clean air" trade winds site in tropical northeastern Puerto Rico, atmospheric total mercury (THg) deposition averaged 28 µg m-2 yr-1, higher than any site in the USA Mercury Deposition Network, driven by efficient capture of upper tropospheric Hg by high rain-forming clouds. The elevated THg in deposition is reflected in high THg concentrations and flux in streams, but assimilation into the local food web was quite low. There are few mammalian or freshwater fish predators on the island, but 30 faunal samples including fly larvae, freshwater shrimp, spiders, tadpoles, coqui frogs, anole lizards, a scorpion, and a boa constrictor had a median THg concentration of 0.032 µg g-1 (dry weight basis), with the three highest values (near 0.14 µg g-1) from spiders. Avian blood THg concentrations (n=31, from 8 species in various foraging guilds) were also quite low, ranging widely from 0.0002 to 0.032 µg g-1 wet weight, with a median of 0.0043 µg g-1. THg levels in biota were severalfold to more than an order of magnitude lower than comparable values in the continental U.S. These results were surprising given the high Hg inputs and watershed features that would seem to favor methylmercury (MeHg) production (Hg(II)-methylation) - high soil moisture with anoxic zones, ample organic matter and sulfur, and year-round warm temperatures. However, organic soil (0-10 cm) along a hillslope to riparian transect averaged only 0.45 ng/g MeHg, with an average MeHg/THg of only 0.34%. Incubations (n=6) to assess methylation and demethylation indicated that rate constants for demethylation were 6-60 fold greater than those for Hg(II)-methylation, and calculated potential rates of demethylation were 3-9 fold greater than those for Hg(II)-methylation. Thus, the apparent paradox may be resolved by the difference between these rates, whereby MeHg degradation outpaces MeHg production in surface soil and sediment. The interplay of these microbial processes shields the island food web from adverse effects of high atmospheric mercury loading.