Effect of Atmospheric Mercury Deposition on Selenium Accumulation

Feb 17, 2015 - The total gaseous mercury (TGM) concentration in ambient air at the artisanal mining site was significantly greater than at the abandon...
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Effect of atmospheric mercury deposition on selenium accumulation in rice (Oryza sativa L.) at a mercury mining region in Southwestern China Chao Zhang, Guangle Qiu, Christopher William Noel Anderson, Hua Zhang, Bo Meng, Liang Liang, and Xinbin Feng Environ. Sci. Technol., Just Accepted Manuscript • DOI: 10.1021/es505827d • Publication Date (Web): 17 Feb 2015 Downloaded from http://pubs.acs.org on February 18, 2015

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Effect of atmospheric mercury deposition on selenium accumulation

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in rice (Oryza sativa L.) at a mercury mining region in Southwestern

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China

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Chao Zhang1, 2, Guangle Qiu1,*, Christopher W. N. Anderson3, Hua Zhang4, Bo Meng1, Liang Liang1, 2, Xinbin Feng1,* 1

State Key Laboratory of Environmental Geochemistry, Institute of Geochemistry, Chinese Academy of Sciences,

Guiyang 550002, P.R. China 2

Graduate University of Chinese Academy of Sciences, Beijing 100049, P.R. China

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Soil and Earth Sciences, Institute of Agriculture and Environment, Massey University, Palmerston North, New

Zealand 4

Contaminants in Aquatic Environments, Norwegian Institute for Water Research (NIVA), Gaustadalleen 21, Oslo

0349, Norway

*Corresponding Author: Xinbin Feng Phone: +86-851-5895728 Fax: +86-851-5891721 Email: [email protected]

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Abstract: Selenium (Se) is an important trace element for human nutrition, and has an interactive effect on mercury (Hg) uptake by plants and Hg toxicity in animals. Rice (Oryza sativa L) is the dominant source of dietary Se in China, however the effect of soil Hg contamination on the Se concentration in rice is unknown. We collected 29 whole rice plant samples and corresponding soils from across an active artisanal mercury mining area and an abandoned commercial mercury mining area. The soil Se concentration was similar across the two mining areas and greater than the background concentration for China. However, the Se concentration in rice grain was dramatically different (artisanal area 51±3 ng g-1; abandoned area 235±99 ng g-1). The total gaseous mercury (TGM) concentration in ambient air at the artisanal mining site was significantly greater than at the abandoned area (231 ng m-3 and 34 ng m-3 respectively) and we found a negative correlation between TGM and the Se concentration in grain for the artisanal area. Principal component analysis (PCA) indicated that the source of Se in rice was the atmosphere for the artisanal area (no contribution from soil), and both the atmosphere and soil for the abandoned area. We propose that TGM falls to soil and reacts with Se, inhibiting the translocation of Se to rice grain. Our data suggests that Se intake by the artisanal mining community is insufficient to meet Se dietary requirements, predisposing this community to greater risk from Hg poisoning.

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1. Introduction: Selenium (Se) is an essential trace element for mammalian physiology. However symptoms

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of deficiency or toxicity are apparent outside of the narrow concentration range that is considered

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adequate for physiological function.1 Selenium is recognized to have specific function in cellular

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defense against reactive oxygen species, to protect against carcinogenesis, and to maintain the

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activity of the thyroid hormone.2-3 Selenium is also thought to protect against infection with the

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HIV virus and to inhibit the progression of this virus to AIDS.1, 4

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Human exposure to Se occurs through the diet. Cereals, vegetables and meat have potential to

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deliver adequate levels of dietary intake, however this will depend on the Se concentration in food

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and the amount consumed.5-6 The concentration of Se in food is primarily dependent on the

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concentration and speciation of Se in soil, and the ability of plants to accumulate Se from the soil

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into edible tissues. 7 Consumption of foods that contain less than 0.1 µg g-1 Se will generally lead

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to Se-deficiency, while a concentration greater than 1.0 µg g-1 will result in toxicity.7 The

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recommended dietary allowance (RDA) of Se for humans in the USA and countries of the

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European Commission is 55 µg day-1 for both men and women, while an upper tolerable nutrient

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level (UL) for adults is 400 µg day-1.8-9 China has a maximum food standard limit of 300 ng g-1 Se

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in cereal grains such as rice, and the concentration of Se in rice is regularly assessed as this cereal

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is considered to the staple food for the majority of the Chinese population. Therefore, for much of

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China, daily Se intake is dependent on the Se concentration in rice.10

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Selenium is a rare element in our planet. The mean concentration of Se in igneous bedrock

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(50 ng g-1) is less than any other essential nutrient element.11The provenance of rocks that weather

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to form soil therefore leads to a varied distribution of the Se concentration in soil, and this, in turn,

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affects the concentration of Se in rice (See Supporting Information for details). The global 3

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background concentration of Se in soil is 200 ng g-1, while the background concentration of Se in

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rice is 95 ng g-1.12-13 However, the Se concentration in rice shows large variations across China,

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especially when known areas of seleniferous soil are compared to non-seleniferous areas (See

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Supporting Information for details).

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Plant uptake of Se is dependent on the speciation of Se in the soil. Two species of Se can be

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present under ambient environmental conditions; selenite which is strongly retained to soil

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colloids through the mechanism of specific adsorption, and selenate, which is weakly retained to

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soil colloids due to electrostatic repulsion.14 Selenate is therefore generally more available to

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plants than selenite and is the predominant form of Se in soil under alkaline or well-oxidized

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conditions. However, in highly anoxic and reduced soil, selenite can become the principle species

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of soil Se and this is poorly available to plants.15 Selenate competes with sulfate for uptake by

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plants because of the chemical similarity between selenate and sulfate, and it has been proposed

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that uptake of both species occurs by way of a sulfate transporter in the root plasma membrane.16

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The translocation of Se from root to stem is also highly dependent on the speciation of Se with

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selenate being much more easily transported than selenite or organic Se.17 Plants can also

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accumulate (absorb) Se from the atmosphere via leaf surfaces.16 In the Yangtze River Delta of

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China, a foliage spray of sodium selenite is regularly used to rectify the problem of low Se content

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of rice grains.18

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To protect against an excessive Se concentration in crop plants such as rice, maximum

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guidelines exist for Se in soil. In China the maximum allowable limit for Se in agricultural soil is

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290 ng g-1, a concentration that is coincidental with the soil Se background concentration for all of

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China.19 However, at contaminated locations, total soil Se concentrations can exceed this limit. 4

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The Wanshan Hg mining area of eastern Guizhou Province is one area that has been contaminated

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with Se. Mercury has been recovered from cinnabar ore in the Wanshan area since the Qin

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Dynasty (211 B.C.). Selenium is present at high concentration in the ore20 and has historically

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been released into the environment during ore processing. The background level of Se in soil

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across all of Guizhou Province is 390 ng g-1, 21 higher than the soil Se background value for all of

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China (290 ng g-1)22 and the world (200 ng g-1).23 Commercial-scale mining was closed in 2001,

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but some artisanal and small scale mercury mining is ongoing in the Wanshan mining area

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releasing mercury into the atmosphere today. However, the greatest legacy of mercury pollution is

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from historical and now abandoned large-scale smelting activities. Within the Wanshan area it is

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therefore possible to differentiate between lands that has been subject to historically high Se (and

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Hg) input, and land that is subject to current day Se (and Hg) flux from artisanal and small-scale

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mining. Paddy rice is the dominant crop species grown throughout the Wanshan region and

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monitoring the Se and Hg concentration in rice grains is important to protect public health.24-25

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Few studies have investigated the uptake and translocation of Se in cereal crop plants

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growing in mining areas with high flux of Hg and Se. These two elements are known to have an

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interactive effect on uptake and the subsequent concentration of these elements in cereal

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grains.25-26 In the current study we have investigated the influence of the nature of Se and Hg

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contamination (i.e. historic soil contamination or current day atmospheric contamination) on the

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concentration of Se in tissues of paddy rice (Oryza sativa L). Specifically, we have investigated

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the influence of Hg concentration and flux on the uptake and translocation of Se in rice. This work

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has been carried out in order to provide mechanistic insight into the process of Se uptake by paddy

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rice growing in Hg-contaminated soil. 5

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2. Materials & Methods

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2.1 Study area

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Formal Hg mining in the Wanshan area ceased at the end of 2001. However, illegal artisanal

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mining and smelting activities have continued to produce Hg to the current day. During the

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retorting of cinnabar ore (from both industrial and artisanal activity), mercury and other elements

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present within the ore, including Se (0.02 – 0.87% of the ore), 20 are released into the environment.

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During the current study, rice and soil at a current-day artisanal mining area (sixteen sites), and a

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now-abandoned industrial-scale mining area (thirteen sites) were sampled. All sampling was

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conducted during the rice growing season of 2009. Small-scale smelting was ongoing throughout

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the sampling period, with the consequential released of mercury to the atmosphere. Mining at the

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industrial area ceased in 2001, however, historical large-scale Hg smelting released serious Hg

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contamination to the ambient air, water, soil, sediment, and biota. Wanshan has a subtropical

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monsoon humid climate with an average annual rainfall of 1200-1400 mm and the annual mean

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temperature of 17°C. The altitude of this area ranges from 205 to 1149 m above sea level.

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2.2 Sampling

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Twenty- nine samples of whole rice plant (Oryza sativa L) and corresponding soil samples (from

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10-20 cm depth) were collected by hand from across the study area (Figure 1). The whole rice

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plant samples were washed in the field with tap water to remove soil particles that had adhered to

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the plants’ surface. All rice and soil samples were then sealed in clean polyethylene bags and

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stored in a cooler before being carried to the laboratory.

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In the laboratory, the whole rice plant samples were carefully washed with deionized water 6

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three times, and divided into root, stem, leaf, and seed components with Teflon scissors, then

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freeze dried (EYELA FDU-1100, Tokyo Rikakikai Co. LTD, Japan). The mass of root, stem, leaf,

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and seed was recorded, and these components accounted for 3%, 31%, 10%, and 56% (average) of

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total plant biomass, respectively. The seed was separated into husk and brown rice using a huller.

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A rice milling machine was then used to separate the bran from the brown rice to yield white rice.

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Rice grain, white rice, bran, and husk accounted for 57%, 12% and 31%, respectively of seed

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biomass. All samples were ground to 150 mesh (IKA-A11 basic, IKA, Germany). The grinder and

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huller were thoroughly cleaned before/after processing each sample with ethanol to avoid

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cross-contamination during sample preparation. The powdered samples were kept in sealed

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polyethylene bags.

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Soil samples were freeze-dried (EYELA FDU-1100) and ground to pass through a 200 mesh sieve using an agate mortar and pestle.

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2.3 Analysis

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The experimental protocol employed for plant digestion and soil digestion, the analysis of Se

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concentration in rice plant tissues and soil, the analysis of the total Hg concentration in plants, and

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the analysis of total gaseous mercury (TGM) concentration are described in the Supporting

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Information.

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2.4 Quality assurance and quality control

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Quality assurance and quality control were validated by using duplicates, method blanks, matrix

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spikes, and certified reference materials (CRMs). Details of the protocols employed are presented 7

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in the Supporting Information.

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3. Results and discussion

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3.1 Se in the soil

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The mean concentration of total Se in soil was two-fold greater for the abandoned mining area

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(2,200 ng g-1) than for the current-day artisanal mining area (990 ng g-1)(Table 1). These

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concentrations are 2.6 and 5.6 fold greater than the soil background level of 390 ng g-1 Se for

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Guizhou province, 21 but lower than the soil Se concentration recorded for seleniferous areas such

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as Enshi in Hubei of China (See Supporting Information for details). The higher concentration of

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Se in soil for the abandoned mining area can be attributed to the extent of historical large-scale Hg

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smelting activities in this area. The cumulative release of elements to soil at the abandoned mining

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areas exceeds that at the current-day artisanal mining area.27

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3.2 Se in rice tissues

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The Se concentration varied between the tissues of rice plants collected from the two areas (Table

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2 and Figure 2). For plants collected from the artisanal area, the highest concentration of Se was

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found in roots (average 220 ng g-1), whereas the lowest concentration was found in the polished

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grain (40 ng g-1). In rice plants collected from the abandoned area the Se concentration in root

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ranged from 80 to 1700 ng g-1, with a mean of 520 ng g-1, whereas the concentration in grain

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ranged from 27 to 970 ng g-1 with a mean of 240 ng g-1. Figure 2 shows that the concentration of

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Se in rice tissues collected from both the artisanal and abandoned areas follows the trend root >

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leaf > stem >grain, an observation that is in agreement with the recent findings of Qin et al who 8

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investigated the distribution of Se in rice at Enshi in Hubei Province.28

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There are also differences in the concentration of Se in the various parts of the rice grain,

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with plants from the abandoned area exhibiting a higher concentration of Se in all parts of the

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cereal. The highest concentration of Se in the different components of rice grain was recorded for

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the bran at both areas. The Se concentration of the bran was 3.2- and 2.1-fold higher than the Se

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concentration in white rice and husk for the artisanal area, and 4.3- and 3.5-fold higher than the Se

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in white rice and husk for the abandoned area. Our results are in agreement with those of a

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previous investigation in the Wanshan area which showed that the Se concentration in whole rice

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grain ranged from 20 to 670 ng g-1 with an average of less than 100 ng g-1.26 When compared to

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the global average concentration of Se in white rice 95 ng g-1,13 rice from the abandoned areas

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exceeds the global average, but rice from the artisanal areas is lower (40 and 160 ng g-1 for the

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artisanal and abandoned areas respectively). However, the Se concentrations in the polished rice

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samples collected in this work were much lower than those recorded from the Enshi seleniferous

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region (range: 160 to 10200 ng g-1).28

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According to the mass proportion of root, stem, leaf, and grain in a whole rice plant, and the

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mass proportion of polished rice, bran, and husk in a whole grain, we calculated the relative mass

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distribution of Se throughout rice plants collected from the two areas (Figure 4). Selenium was

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predominantly accumulated in the above-ground parts of rice plants. For the artisanal area, 10% of

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accumulated Se was stored in roots, while 90% was stored in the aerial tissues. These values were

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5% and 95% for the abandoned area. For both areas, the greatest sink of plant Se was in the grain,

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with Se in the grain predominantly accumulated in the polished rice, followed by bran and husk.

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The relative distribution of Se between plant components was similar, despite the large difference 9

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in Se concentration for rice plants collected from the two areas. This indicates that the plant

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actively distributes accumulated Se throughout the various organs.

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The bioaccumulation factors (BAF) of Se in the various tissues of the rice plant are presented

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in Table 2. The BAF of Se in root for both areas was similar. However there was a significant

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difference in the BAF of Se in stem and grain for plants collected from the two areas. In particular,

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the BAF for Se in grain from the abandoned area was double that for the artisanal area (Table 2).

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For both areas the highest BAF was observed in root, followed by leaf, stem and grain, with the

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BAF in all the rice tissues greater at the abandoned area than at the artisanal area.

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3.3 Investigating the source of Se in rice plants

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Principal component analysis (PCA) is a multivariate statistical technique that reduces a large

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number of variables to a small number of factors (principal components or PCs) that can be used

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to explain the relationships and associations among objects and variables.29-31 For example, Shan

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et al.32 applied PCA to extract hidden subsets from a dataset in order to detect possible sources of

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heavy metals in agricultural soils (see Supporting Information). In order to identify the likely

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origin of Se in the plants sampled from the two mining areas, we analyzed the Se concentration of

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soil and the various tissues of rice plants collected from the two areas using PCA statistical

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software (SPSS 18.0).

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Principal Component Analysis of Se concentrations at the artisanal area defines three

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components (PC1, PC2 and PC3) which account for 84% of the variance in the data set (Table 3).

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PC1 expressed high positive loadings on leaf and grain and we interpret the inclusion of these two

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variables in one component to indicate a common origin of Se. Selenium can be accumulated as a 10

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function of stomata uptake of gas phase Se or foliar absorption from particulate material. 33-35 We

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therefore propose that PC1 can be used to infer that the source of Se in the aerial tissues of rice

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plants collected from artisanal area is the ambient air. There is precedent for this inference in

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previous studies that have investigated how atmospheric Se flux can affect plants. Component

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PC2 expressed a high positive loading for stem and a highly negative loading for soil. We interpret

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this to represent an internal phytophysiological transfer process for Se absorbed from the

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atmosphere. PC 3 expressed high positive loadings for all components: root, grain, stem and soil.

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As the stem is the transport channel connecting the root to the grain, we propose that PC3 for the

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artisanal area is an indicator for soil derived Se. The lower total variance described by PC3

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indicates that soil is a minor source for Se uptake by rice plants at the artisanal area.

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Principle Component Analysis of the Se concentrations for the abandoned area defined two

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components which together accounted for 98% of total variance in the data set (PC1 58% and PC2

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40%) (Table 4). Due to high loadings on grain, stem and leaf, but relatively low loading on root,

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we infer that PC1 again describes ambient air as the source of Se. However, the positive loading

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on soil for PC1 indicates that soil has an influence on PC1 for the abandoned area. We propose

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that this influence may be Se volatilized from soil that is subsequently adsorbed by the aerial plant

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tissues; however, the validity of this assumption must be further tested. PC2 has a high loading on

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soil, root and leaf. As these are the two plant components with the highest BAF (Table 2) we infer

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that soil is again the source of Se for PC2. PCA of Se for the abandoned area suggests that there is

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no clear distinction between soil and air as the primary source of this element in rice and describes

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an apparent interaction between these two sources that is not observed for the artisanal area.

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Artisanal smelting of cinnabar ore was ongoing during the rice growing season in 2009 and 11

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therefore there was release of Hg into the atmosphere throughout this period. Monitoring of the

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total gaseous mercury (TGM) concentration in air recorded a mean concentration of 231 ng m-3

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which was significantly higher than the mean concentration recorded for the abandoned area (34

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ng m-3). During smelting other volatile components of the ore will also have been released into the

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atmosphere, including Se. The elevated TGM concentration for the artisanal area relative to the

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abandoned area therefore suggests a differential concentration of Se in the atmosphere between the

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two areas and supports the PCA modeled differential primary origin of Se in rice between the two

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areas. Further research is needed to substantiate this interpretation of the PCA data. Measurement

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of the total gaseous selenium concentration at the two areas and isotopic fingerprinting would

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achieve this aim.

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3.4 Wanshan daily dietary Se intake via rice consumption

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Dumont et al.7 indicated that if the concentration of Se in food is less than 100 ng g-1, symptoms

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of deficiency can be expected in human populations. Across the sampling sites in this study, the Se

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concentration of polished rice exceeded 100 ng g-1 for only 17% of the 29 locations. The potential

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magnitude of this problem can be further considered through analysis of rice consumption habits.

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According to the National Bureau of Statistics of China, the daily per capita consumption of

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rice in 2010 in China was 200 g dry weight per day for adults with an average weight of 60 kg.

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Assuming that 100% of the ingested Se is absorbed in the body, we can approximately calculate

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the adult daily intake of Se via rice consumption in each of the two study areas. For an adult,

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consuming 200 g rice per day containing an average Se concentration of 40 and 160 ng g-1 for the

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artisanal and abandoned mining areas respectively, total daily Se intake will be 8 and 32 µg 12

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respectively (intake will be lower if absorption is not 100%; these values are therefore

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conservative). Based on these calculations, Se intake from rice in the abandoned mining area will

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exceed the WHO/FAO/IAEA guideline level of 30 µg day-1 for women and is close the guideline

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level for men (40 µg day-1).4 However, Se intake from rice in the artisanal mining area is

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considerably lower than the guideline level for both men and women.

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The soil Se concentration at both areas exceeded the Chinese guideline concentration for Se

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in soil. Therefore, the low concentration of Se in rice at the artisanal site cannot be attributed to a

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low soil Se concentration. Instead, we believe the high concentration of Hg in the atmosphere is

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inhibiting Se uptake from soil. Zhang et al.24 , proposed a new criterion for Se and Hg exposure

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assessment, based on their understanding of the interaction between Se and Hg; the physiology

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and toxicology of Se; and the toxicology of Hg. According to Zhang et al., daily dietary Se intake

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can have an important mitigating impact on the toxicity of Hg exposure. However, assessment of

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Se intake alone without considering the potential for interactions with Hg may inadequately reflect

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the Se status of individuals. Applying Zhang et al.’s criterion, the low Se intake predicted for the

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artisanal mining area may lead to both a deficiency of Se and increased risk of Hg toxicity in the

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population.

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3.5 Conceptual model to explain the effect of atmospheric Hg on Se uptake by rice

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According to the Principle Component Analysis, the source of Se in rice across the artisanal

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area is the atmosphere, with little to no accumulation of Se from soil, despite the presence of a

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significant concentration of soil Se. However, across the abandoned area, PCA indicates that rice

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accumulates Se from both the atmosphere and the soil. We believe that the factor controlling the

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uptake of Se from soil is the total gaseous mercury (TGM) concentration in ambient air. Where the 13

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TGM concentration in ambient air is low, rice plants are able to accumulate Se from the soil and to

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translocate this to grain. However, where the TGM concentration in ambient air is high, uptake of

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Se from soil and translocation is restricted. Supporting this hypothesis is a negative correlation

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(R2=0.242, P=0.074) between TGM concentration in ambient air and the concentration of Se in

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grain for the artisanal area only (Figure 3). No similar correlation was found for the abandoned

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area. The rationale for using the correlation between TGM concentration in ambient air and Se

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concentration in grain to qualify the effect of TGM concentration in ambient air is further

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explained in the supporting information.

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Previous work has shown that a high TGM concentration in ambient air due to artisanal and

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small-scale mining will lead to a high flux of mercury to soil through both particulate mercury

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deposition and the presence of dissolved Hg in precipitation.36 Meng et al.36 described how freshly

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deposited inorganic mercury from artisanal and small-scale mining is more chemically reactive

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than Hg that has been in soil for an extended period of time and is readily methylated in soil. This

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MeHg is then accumulated by rice plants, and concentrates in rice grain. Zhang et al.24 showed

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that chemically reactive Hg in soil will readily precipitate Se as a stable and insoluble Hg-Se

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complex in the rhizopshere or on the root surface of rice plants. We therefore propose that the lack

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of Se uptake by rice plants from soil at the artisanal area is due to the removal of bioavailable Se

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from soil solution by chemically reactive Hg that was being released to the atmosphere and falling

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to the ground through the rice sampling period of our study. This mechanism was unique to the

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artisanal area, as there was no active Hg mining across the abandoned area at the time of sampling.

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The abandoned area was characterized by a relatively low TGM concentration in ambient air and

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therefore limited deposition flux of fresh (and chemically reactive) Hg to soil. 14

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3.6 Implications of this model for Wanshan public health

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The two mining areas described in this paper are typical mining areas across the Wanshan region

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of Guizhou, China. The Se concentration in soil varies across Wanshan, but is much higher than

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the global soil Se background level (200 ng g-1).12 Despite the elevated Se concentration in soil,

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the Se concentration in rice is not always high. We have shown that the Se concentration in rice

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grain across the artisanal area is low and may lead to Se deficiency in the human population.

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Foods that contain less than 100 ng g-1 Se will generally lead to Se-deficiency.7 Using this

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criterion value, rice across the artisanal mining area was Se deficient (average concentration 51 ng

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g-1), whereas rice collected from the abandoned areas was sufficient (average concentration 235 ng

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g-1). We do not believe that the explanation for this difference in Se concentration in rice is the Se

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concentration in the soil as soil Se should not be a limiting factor for uptake. Instead we propose

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that the limiting factor for Se concentration in rice is the current-day concentration of Hg in the

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atmosphere, and subsequently, the deposition flux of Hg to the soil. This same deposition flux of

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mercury to soil is now recorded as the source of significant Hg (as MeHg) exposure to inland

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communities of China who consume rice.

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Ralston et al.37 suggested the ratio of Hg to Se may be the critical factor in determining the

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toxicity of Hg. Based on rodent data, Hg exposure that might otherwise produce toxic effects can

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be counteracted by Se, particularly when Se/Hg molar ratios approach or exceed 1:1. At this ratio

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there is adequate Se to prevent Hg toxicity.38 The scenario where artisanal and small scale mining

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leads to a high deposition flux of inorganic mercury to soil may therefore lead to both excessive

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exposure of the local population to Hg (as MeHg), and deficiency of the local population in Se. 15

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We therefore propose that in the context of rice production in artisanal mining areas, Hg

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contamination of the air is a significant threat to the Se nutrition of the mining communities. The

338

combined effect of elevated Hg and Hg-induced Se deficiency in rice may be leading to more

339

excessive exposure of the artisanal mining communities to Hg toxicity than is currently

340

recognized. The interactive effect of these two elements, especially the profound effect of Hg on

341

Se uptake into rice grain, should be assessed more fully in the context of public health. Studies on

342

the effect of Hg on the uptake and accumulation of Se in plants and the underlying mechanisms of

343

this effect, especially phytophysiological processes, should be considered in the future.

344 345

Acknowledgments

346

This research was financed by National Key Basic Research Program of China (973 Program

347

2013CB430004), Natural Science Foundation of China (41073098, 41203091, 41073062,

348

41173126, and 11105172), and also financed by the 135 project of IGCAS.

349 350 351

Supporting Information Available

352

Detailed information of sample analysis; detailed information of QA/AC; literature precedent for

353

applying PCA to extract hidden subsets from a dataset in order to detect possible sources;

354

explanation of the correlation between TGM and Se concentration in grain; one tables. This

355

information is available free of charge via the Internet athttp://pubs.acs.org/

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References

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Morris, J. S. How Might Selenium Moderate the Toxic Effects of Mercury in Stream Fish of the Western US? Environ. Sci. Technol. 2009, 43 (10), 3919-3925.

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Table 1 Concentration of total Se in tissues of rice plant as a function of the two sampling areas

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(ng g-1)

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Table 2 Bioaccumulation factors (BAF) of Se in tissues of the rice plant as a function of sampling

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area. BAF is calculated as the Se concentration in the tissues of rice plant/Se concentration in soil.

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Table 3 Rotated factor loadings and percent variance for the two principal components (PC) of Se

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in rice tissues and soil for the artisanal area

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Table 4 Rotated factor loadings and percent variance for the two principal components (PC) of Se

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in rice tissues and soil for the abandon area

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Table 1 Tissues, ng g-1

Artisanal area

Abandoned area

Mean±Std.E

Range

Mean±Std.E

Range

Polished

40±6

17-130

160±64

13-650

Bran

99±10

42-180

680±290

52-2900

Husk

52±4

26-82

200±75

36-820

Grain

51±3

23-76

235±99

27-970

Root

220±19

70-340

520±160

80-1700

Stem

66±7

27-120

330±140

35-1600

Leaf

150±15

67-280

440±150

63-1500

Soil

990±92

370-1900

2200±660

540-8900

457 458

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Table 2 Tissues Grain Root Stem Leaf

Artisanal area

Abandoned area

0.05 0.22 0.07 0.15

0.11 0.24 0.15 0.2

460

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Se

PC 1

PC 2

PC 3

Grain Stem Leaf Root Soil % of variance explained cumulative % of total variance

0.657 -0.410 0.922 0.127 -0.371 29

0.383 0.812 0.048 0.041 -0.791 29

0.442 0.390 0.036 0.936 0.262 26 84

Extraction method: principal component analysis. Rotation method: Varimax with Kaiser Normalization.

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Table 4 Se

PC 1

PC 2

Grain Stem Leaf Root Soil % of variance explained cumulative % of total variance

0.921 0.940 0.747 0.722 0.325 58

0.375 0.339 0.655 0.664 0.943 40 98

Extraction method: principal component analysis. Rotation method: Varimax with Kaiser Normalization.

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Figure 1. The study area and location of the sampling sites (Area A is the artisanal area, Area B is

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the abandoned area)

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Figure 2. Total Se concentration in different tissues of rice plant collected from the two areas

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(with Std. Error) (Area A is the artisanal area, Area B is the abandoned area)

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Figure 3. Concentration of Se in the grain as a function of TGM for the two areas (Area A is the

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artisanal area, Area B is the abandoned area)

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Figure 4. The relative distribution of Se in the tissues of rice plants from the artisanal area (Area

478

A) and abandoned area (Area B)

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Figure 1.

481 482

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Figure 2.

1000

1000

800

800

600

700

200

-1

Total Se concerntation (ng g )

700

100

600

-1

900

900

Total Se concerntation (ng g )

483

Area A Area B

0

500

Polished

Bran

Husk

Tissues of grain

400 300 200 100 0 Grain

Stem

Leaf

Root

Tissues of rice plant

484 485

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Figure 3. Concentrations of Se in grain (ng/g)

486

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A

80

B

1000

R2=0.242, P=0.074

70

2

R =3E-05, P=0.921

800

60 600 50 400

40

200

30

0

20 0

100

200

300

400

500

600

700

20

TGM (ng/m3)

30

40

50

60

TGM (ng/m3)

487 488

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Figure 4.

490 491

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