Role of Settling Particles on Mercury Methylation in the Oxic Water Column of Freshwater Systems

Mercury (Hg) is a toxic trace element known to highly accumulate in aquatic biota and uptake by algae is the main entry‐point into the aquatic food chain. However, the effect of changes in solar irradiance and climatic conditions on Hg uptake by algae is largely unknown. We analyzed the link between sediment Hg accumulation, cyclic changes in total solar irradiance (TSI), and related changes in lake productivity as well as climate during the past 4.5 thousand years (kyr) in sediments of a small highly productive lake in Southern Patagonia (53°S). The analyses encompass proxies for TSI (based on 10Be), sediment geochemical composition, and lake productivity (FTIR spectra, and hydrogen‐index). The sediment record shows high concentrations of organic matter (median 70%) and strong variations in Hg accumulation rates (14–53 μg m2 yr−1) which correspond to changes in aquatic productivity and TSI. Accumulation of Hg was highest during dryer periods when irradiance and lake productivity was high. During these periods, accumulation was up to fourfold higher compared to those of lower TSI, lower productivity, and wetter climatic conditions. Higher amounts of algae biomass can increase Hg scavenging by organic particles and Hg export to the sediment. To obtain mass balance, we assume that the increase in sediment Hg accumulation rates during periods of lower Hg fluxes from the catchment (drier) caused a decrease in water phase Hg and in rates of Hg evasion from the lake.

Section: Resultsmentioning

confidence: 55%

mentioning

confidence: 99%

Solar irradiance and primary productivity controlled mercury accumulation in sediments of a remote lake in the Southern Hemisphere during the past 4000 years

Biester

Pérez-Rodríguez

Gilfedder

et al. 2017

“…Nonetheless, several studies revealed that Hg II ‐methylation can occur in oxygen deficient zones of water column (Eckley et al ; Malcolm et al ), sediments (Drott et al ; Hines et al ; Bouchet et al ; Jonsson et al ; Bravo et al ; Liem‐Nguyen et al ) flooded soils, e.g., wetlands (Louis et al ; Tjerngren et al ; Windham‐Myers et al ) and ponds (Lehnherr et al ; MacMillan et al ; Herrero Ortega et al ). In recent years, Hg II ‐methylation processes were in addition observed in microenvironments such as periphyton, growing on macrophytes (Cleckner et al ; Mauro et al ; Guimarães et al ; Achá et al ; Hamelin et al ; Bouchet et al ) and settling particles of oxic water columns, including pelagic ocean waters (Monperrus et al ; Cossa et al ; Sunderland et al ;Lehnherr et al ; Gascón Díez et al ). Initially, MMHg formation in oxic waters was considered negligible due to high redox and low concentrations of bacteria and nutrients, but studies demonstrated that about 20–40% of the MMHg measured below the surface mixed layer originates from the surface and enters deeper ocean waters (Blum et al ).…”

Section: Methylmercury Formation Is Widespread In the Environmentmentioning

confidence: 99%

“…Moreover, a recent study assessing 243 metagenomes from the Tara Oceans expedition reported high abundances of hgcAB genes in 77 samples across all oceans (Villar et al ). The progress in genetics (Gilmour et al ; Parks et al ; Podar et al ; Bravo et al , a ; Liu et al ; Jones et al ) combined with recent advances in the use of stable isotopes to determine Hg II methylation rate constants in sediments (Monperrus et al ; Jonsson et al ; Bravo et al , ), lakes (Eckley and Hintelmann ), water columns and oceans (Munson et al ) as well as in sinking particles of marine and lake waters (Lehnherr et al ; Gascón Díez et al ) have demonstrated that the potential for MMHg formation in the environment is widespread across ecosystems.…”

Section: Methylmercury Formation Is Widespread In the Environmentmentioning

confidence: 99%

Biotic formation of methylmercury: A bio–physico–chemical conundrum

Bravo

Cosio

2019

Self Cite

113

102

Mercury (Hg) is a natural and widespread trace metal, but is considered a priority pollutant, particularly its organic form methylmercury (MMHg), because of human's exposure to MMHg through fish consumption. Pioneering studies showed the methylation of divalent Hg (HgII) to MMHg to occur under oxygen‐limited conditions and to depend on the activity of anaerobic microorganisms. Recent studies identified the hgcAB gene cluster in microorganisms with the capacity to methylate HgII and unveiled a much wider range of species and environmental conditions producing MMHg than previously expected. Here, we review the recent knowledge and approaches used to understand HgII‐methylation, microbial biodiversity and activity involved in these processes, and we highlight the current limits for predicting MMHg concentrations in the environment. The available data unveil the fact that HgII methylation is a bio‐physico‐chemical conundrum in which the efficiency of biological HgII methylation appears to depend chiefly on HgII and nutrients availability, the abundance of electron acceptors such as sulfate or iron, the abundance and composition of organic matter as well as the activity and structure of the microbial community. An increased knowledge of the relationship between microbial community composition, physico‐chemical conditions, MMHg production, and demethylation is necessary to predict variability in MMHg concentrations across environments.

“…MeHg is produced in oxygen-limited sediments, soils, and stratified water columns (Pak and Bartha 1998;Eckley and Hintelmann 2006;Gascon Diez et al 2016). The content and composition of NOM and several additional environmental factors such as temperature, redox potential, pH, and sulfur chemistry modulate biological methylation rates of inorganic divalent mercury (Hg(II)) (Ullrich et al 2001;Drott et al 2007).…”

Section: Introductionmentioning

confidence: 99%

High methylmercury formation in ponds fueled by fresh humic and algal derived organic matter

Ortega

Catalán

Björn

et al. 2017

Self Cite

Neurotoxic methylmercury causes adverse effects to ecosystem viability and human health. Previous studies have revealed that ponding alters natural organic matter (NOM) composition and increase methylmercury concentrations in rivers, especially in the first years after flooding. Here, we investigate the influence of NOM composition (i.e., sources and degradation status) on mercury methylation rate constants in nine boreal beaver ponds of different ages across Sweden. We show that increased methylmercury concentrations in surface waters is a consequence of enhanced mercury methylation in the pond sediments. Moreover, our results reveal that during the first years after the initial flooding, mercury methylation rates are fueled by the amount of fresh humic substances released from the flooded soils and by an increased production of algal-derived NOM triggered by enhanced nutrient availability. Our findings indicate that impoundment-induced changes in NOM composition control mercury methylation processes, causing the raise in MeHg levels in ponds. Scientific Significance StatementPonds are the most abundant type of aquatic ecosystem at boreal, subarctic, and artic latitudes. Accelerated permafrost thawing caused by global warming and an increasing number of beaver populations now recovering from near extirpation are the main causes of ponding in the boreal region. Unfortunately, ponding is associated with increased concentrations of neurotoxic methylmercury, particularly during the first years after the initial flooding. An understanding of the processes controlling methylmercury formation is thus required to develop management strategies that aim to reduce mercury exposure. Our results show that ponding enhanced the released of fresh humic organic matter and nutrients triggered algae growth, both determining the final concentration of methylmercury in ponds.